HandWiki Test - User contributions [en]

Template:Mainpage rotating external quantum article

2026-05-25T09:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
In Quantum Sensing, What Beats Beating Noise? Meeting Noise Halfway.
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-09-10
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
A team including scientists at NIST may have found a new way of dealing with noise at<br>
the microscopic scales where quantum physics reigns.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-09-10.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/09/quantum-sensing-what-beats-beating-noise-meeting-noise-halfway Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-09-10
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T08:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
A simple twist unlocks never-before-seen quantum behavior
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors; Engineering and Construction; Materials Science
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Scientists have discovered a revolutionary new method for creating quantum states by<br>
twisting materials at the M-point, revealing exotic phenomena previously out of reach.<br>
This new direction dramatically expands the moiré toolkit and may soon lead to the<br>
experimental realization of long-sought quantum spin liquids.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors;<br>
Engineering and Construction; Materials Science.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/07/250710113201.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T07:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Researchers establish new basis for quantum sensing and communication
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers have established a new basis for quantum sensing and communication. Their<br>
theoretical approach for generating quantum states could be crucial for many areas,<br>
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical<br>
research.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,<br>
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,<br>
quantum information, non-Gaussian quantum states.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/researchers-establish-new-basis-quantum-sensing-communication-0313 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T06:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Sharper than lightning: Oxford’s one-in-6.7-million quantum breakthrough
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Computers and Internet; Computer Modeling; Computer Science; Hacking; Quantum Computers; Distributed Computing; Communications; Math Puzzles
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists at the University of Oxford have set a new global benchmark for the<br>
accuracy of controlling a single quantum bit, achieving the lowest-ever error rate for<br>
a quantum logic operation--just 0.000015%, or one error in 6.7 million operations.<br>
This record-breaking result represents nearly an order of magnitude improvement over<br>
the previous benchmark, set by the same research group a decade ago.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Computers and Internet; Computer Modeling; Computer Science; Hacking;<br>
Quantum Computers; Distributed Computing; Communications; Math Puzzles.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250610074301.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T05:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
MIT engineers advance toward a fault-tolerant quantum computer
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum readout, Quarton coupler, Nonlinear light-matter coupling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers demonstrated extremely strong nonlinear light-matter coupling in a<br>
quantum circuit. Stronger coupling enables faster quantum readout and operations,<br>
ultimately improving the accuracy of quantum operations.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum<br>
readout, Quarton coupler, Nonlinear light-matter coupling.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/mit-engineers-advance-toward-fault-tolerant-quantum-computer-0430 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T04:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Novel ‘Quantum Refrigerator’ Is Great at Erasing Quantum Computer’s Chalkboard
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-01-09
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum computers need a "clean" workspace, and a team including scientists at NIST<br>
has found a way to make one.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-01-09.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/01/novel-quantum-refrigerator-great-erasing-quantum-computers-chalkboard Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-01-09
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T03:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Scientists just found a hidden quantum geometry that warps electrons
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics Research; Computers and Internet; Hacking; Computer Modeling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
A hidden quantum geometry that distorts electron paths has finally been observed in<br>
real materials. This “quantum metric,” once thought purely theoretical, may<br>
revolutionize electronics, superconductivity, and ultrafast devices.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics<br>
Research; Computers and Internet; Hacking; Computer Modeling.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/09/250905112310.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T02:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Anything-goes “anyons” may be at the root of surprising quantum experiments
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions, superconductivity, Magnetism, quantum computing, stable qubits
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT theoretical physicists may have an explanation for the surprising observation that<br>
superconductivity and magnetism can co-exist in some materials. They propose that<br>
under certain conditions, a magnetic material’s electrons could splinter into<br>
quasiparticles known as “anyons,” some of which could flow together without friction —<br>
an entirely new form of superconductivity.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron<br>
fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions,<br>
superconductivity, Magnetism, quantum computing, stable qubits.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/anything-goes-anyons-may-be-root-surprising-quantum-experiments-1222 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T01:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Multiplexing entanglement in a quantum network
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics Research; Computers and Internet; Communications; Internet
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers use rare-earth ions to achieve the first-ever demonstration of<br>
entanglement multiplexing between individual memory qubits in a quantum network.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics<br>
Research; Computers and Internet; Communications; Internet.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/02/250226125136.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-25T00:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
NIST Physicists Bring Unruly Molecules to the Quantum Party
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-12-18
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Molecules can serve as versatile building blocks for quantum technologies, but they<br>
are much harder to control than atoms.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-12-18.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/12/nist-physicists-bring-unruly-molecules-quantum-party Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-12-18
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T23:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Photons collide in the void: Quantum simulation creates light out of nothing
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Energy and Resources; Optics; Physics; Telecommunications; Civil Engineering; Virtual Environment; Quantum Physics; Electricity
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists have managed to simulate a strange quantum phenomenon where light appears<br>
to arise from empty space a concept that until now has only existed in theory. Using<br>
cutting-edge simulations, researchers modeled how powerful lasers interact with the<br>
so-called quantum vacuum, revealing how photons could bounce off each other and even<br>
generate new beams of light. These breakthroughs come just as new ultra-powerful laser<br>
facilities are preparing to test these mind-bending effects in reality, potentially<br>
opening a gateway to uncovering new physics and even dark matter particles.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Energy and Resources; Optics; Physics; Telecommunications; Civil<br>
Engineering; Virtual Environment; Quantum Physics; Electricity.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250608072527.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T22:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Why some quantum materials stall while others scale
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Mingda Li, Quantum materials
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers developed a way to evaluate the scale-up potential of quantum<br>
materials, combining a material’s quantum behavior with its cost, supply chain<br>
resilience, and environmental footprint. The approach could help researchers identify<br>
materials for next-generation microelectronics, energy harvesting applications, and<br>
medical diagnostics.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Mingda Li, Quantum materials.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/why-some-quantum-materials-stall-while-others-scale-1015 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T21:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Physicists Take the Imaginary Numbers Out of Quantum Mechanics | Quanta Magazine
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
Quanta Magazine · Quantum science · 2025-11-07
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum mechanics has at last been formulated exclusively with real numbers, bringing<br>
a mathematical puzzle at the heart of the theory into a new era of inquiry.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-11-07.<br>
The selected source is Quanta Magazine; the full article link appears below this<br>
preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.quantamagazine.org/physicists-take-the-imaginary-numbers-out-of-quantum-mechanics-20251107/ Read the full article at Quanta Magazine ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: Quanta Magazine. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: Quanta Magazine · 2025-11-07
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T20:10:08Z

Maintenance script: Update rotating external quantum article

Template:Mainpage rotating external quantum article

2026-05-24T19:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
A simple twist unlocks never-before-seen quantum behavior
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors; Engineering and Construction; Materials Science
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Scientists have discovered a revolutionary new method for creating quantum states by<br>
twisting materials at the M-point, revealing exotic phenomena previously out of reach.<br>
This new direction dramatically expands the moiré toolkit and may soon lead to the<br>
experimental realization of long-sought quantum spin liquids.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors;<br>
Engineering and Construction; Materials Science.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/07/250710113201.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T18:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Researchers establish new basis for quantum sensing and communication
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers have established a new basis for quantum sensing and communication. Their<br>
theoretical approach for generating quantum states could be crucial for many areas,<br>
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical<br>
research.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,<br>
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,<br>
quantum information, non-Gaussian quantum states.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/researchers-establish-new-basis-quantum-sensing-communication-0313 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T17:10:12Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Sharper than lightning: Oxford’s one-in-6.7-million quantum breakthrough
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Computers and Internet; Computer Modeling; Computer Science; Hacking; Quantum Computers; Distributed Computing; Communications; Math Puzzles
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists at the University of Oxford have set a new global benchmark for the<br>
accuracy of controlling a single quantum bit, achieving the lowest-ever error rate for<br>
a quantum logic operation--just 0.000015%, or one error in 6.7 million operations.<br>
This record-breaking result represents nearly an order of magnitude improvement over<br>
the previous benchmark, set by the same research group a decade ago.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Computers and Internet; Computer Modeling; Computer Science; Hacking;<br>
Quantum Computers; Distributed Computing; Communications; Math Puzzles.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250610074301.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T16:10:11Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
MIT engineers advance toward a fault-tolerant quantum computer
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum readout, Quarton coupler, Nonlinear light-matter coupling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers demonstrated extremely strong nonlinear light-matter coupling in a<br>
quantum circuit. Stronger coupling enables faster quantum readout and operations,<br>
ultimately improving the accuracy of quantum operations.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum<br>
readout, Quarton coupler, Nonlinear light-matter coupling.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/mit-engineers-advance-toward-fault-tolerant-quantum-computer-0430 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T15:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Novel ‘Quantum Refrigerator’ Is Great at Erasing Quantum Computer’s Chalkboard
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-01-09
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum computers need a "clean" workspace, and a team including scientists at NIST<br>
has found a way to make one.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-01-09.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/01/novel-quantum-refrigerator-great-erasing-quantum-computers-chalkboard Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-01-09
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T14:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Scientists just found a hidden quantum geometry that warps electrons
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics Research; Computers and Internet; Hacking; Computer Modeling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
A hidden quantum geometry that distorts electron paths has finally been observed in<br>
real materials. This “quantum metric,” once thought purely theoretical, may<br>
revolutionize electronics, superconductivity, and ultrafast devices.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics<br>
Research; Computers and Internet; Hacking; Computer Modeling.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/09/250905112310.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T13:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Anything-goes “anyons” may be at the root of surprising quantum experiments
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions, superconductivity, Magnetism, quantum computing, stable qubits
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT theoretical physicists may have an explanation for the surprising observation that<br>
superconductivity and magnetism can co-exist in some materials. They propose that<br>
under certain conditions, a magnetic material’s electrons could splinter into<br>
quasiparticles known as “anyons,” some of which could flow together without friction —<br>
an entirely new form of superconductivity.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron<br>
fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions,<br>
superconductivity, Magnetism, quantum computing, stable qubits.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/anything-goes-anyons-may-be-root-surprising-quantum-experiments-1222 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T12:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Multiplexing entanglement in a quantum network
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics Research; Computers and Internet; Communications; Internet
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers use rare-earth ions to achieve the first-ever demonstration of<br>
entanglement multiplexing between individual memory qubits in a quantum network.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics<br>
Research; Computers and Internet; Communications; Internet.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/02/250226125136.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T11:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
NIST Physicists Bring Unruly Molecules to the Quantum Party
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-12-18
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Molecules can serve as versatile building blocks for quantum technologies, but they<br>
are much harder to control than atoms.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-12-18.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/12/nist-physicists-bring-unruly-molecules-quantum-party Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-12-18
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T10:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Photons collide in the void: Quantum simulation creates light out of nothing
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Energy and Resources; Optics; Physics; Telecommunications; Civil Engineering; Virtual Environment; Quantum Physics; Electricity
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists have managed to simulate a strange quantum phenomenon where light appears<br>
to arise from empty space a concept that until now has only existed in theory. Using<br>
cutting-edge simulations, researchers modeled how powerful lasers interact with the<br>
so-called quantum vacuum, revealing how photons could bounce off each other and even<br>
generate new beams of light. These breakthroughs come just as new ultra-powerful laser<br>
facilities are preparing to test these mind-bending effects in reality, potentially<br>
opening a gateway to uncovering new physics and even dark matter particles.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Energy and Resources; Optics; Physics; Telecommunications; Civil<br>
Engineering; Virtual Environment; Quantum Physics; Electricity.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250608072527.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T09:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Why some quantum materials stall while others scale
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Mingda Li, Quantum materials
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers developed a way to evaluate the scale-up potential of quantum<br>
materials, combining a material’s quantum behavior with its cost, supply chain<br>
resilience, and environmental footprint. The approach could help researchers identify<br>
materials for next-generation microelectronics, energy harvesting applications, and<br>
medical diagnostics.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Mingda Li, Quantum materials.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/why-some-quantum-materials-stall-while-others-scale-1015 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T08:10:11Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Physicists Take the Imaginary Numbers Out of Quantum Mechanics | Quanta Magazine
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
Quanta Magazine · Quantum science · 2025-11-07
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum mechanics has at last been formulated exclusively with real numbers, bringing<br>
a mathematical puzzle at the heart of the theory into a new era of inquiry.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-11-07.<br>
The selected source is Quanta Magazine; the full article link appears below this<br>
preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.quantamagazine.org/physicists-take-the-imaginary-numbers-out-of-quantum-mechanics-20251107/ Read the full article at Quanta Magazine ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: Quanta Magazine. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: Quanta Magazine · 2025-11-07
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T07:10:09Z

Maintenance script: Update rotating external quantum article

Template:Mainpage rotating external quantum article

2026-05-24T06:10:12Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
A simple twist unlocks never-before-seen quantum behavior
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors; Engineering and Construction; Materials Science
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Scientists have discovered a revolutionary new method for creating quantum states by<br>
twisting materials at the M-point, revealing exotic phenomena previously out of reach.<br>
This new direction dramatically expands the moiré toolkit and may soon lead to the<br>
experimental realization of long-sought quantum spin liquids.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors;<br>
Engineering and Construction; Materials Science.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/07/250710113201.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T05:10:13Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Researchers establish new basis for quantum sensing and communication
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers have established a new basis for quantum sensing and communication. Their<br>
theoretical approach for generating quantum states could be crucial for many areas,<br>
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical<br>
research.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,<br>
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,<br>
quantum information, non-Gaussian quantum states.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/researchers-establish-new-basis-quantum-sensing-communication-0313 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T04:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Sharper than lightning: Oxford’s one-in-6.7-million quantum breakthrough
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Computers and Internet; Computer Modeling; Computer Science; Hacking; Quantum Computers; Distributed Computing; Communications; Math Puzzles
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists at the University of Oxford have set a new global benchmark for the<br>
accuracy of controlling a single quantum bit, achieving the lowest-ever error rate for<br>
a quantum logic operation--just 0.000015%, or one error in 6.7 million operations.<br>
This record-breaking result represents nearly an order of magnitude improvement over<br>
the previous benchmark, set by the same research group a decade ago.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Computers and Internet; Computer Modeling; Computer Science; Hacking;<br>
Quantum Computers; Distributed Computing; Communications; Math Puzzles.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250610074301.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T03:10:12Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
MIT engineers advance toward a fault-tolerant quantum computer
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum readout, Quarton coupler, Nonlinear light-matter coupling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers demonstrated extremely strong nonlinear light-matter coupling in a<br>
quantum circuit. Stronger coupling enables faster quantum readout and operations,<br>
ultimately improving the accuracy of quantum operations.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Yufeng Ye, Bright Ye, Kevin P. O’Brien, quantum computing, Quantum<br>
readout, Quarton coupler, Nonlinear light-matter coupling.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/mit-engineers-advance-toward-fault-tolerant-quantum-computer-0430 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T02:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Novel ‘Quantum Refrigerator’ Is Great at Erasing Quantum Computer’s Chalkboard
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-01-09
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum computers need a "clean" workspace, and a team including scientists at NIST<br>
has found a way to make one.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-01-09.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/01/novel-quantum-refrigerator-great-erasing-quantum-computers-chalkboard Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-01-09
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T01:10:12Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Scientists just found a hidden quantum geometry that warps electrons
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics Research; Computers and Internet; Hacking; Computer Modeling
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
A hidden quantum geometry that distorts electron paths has finally been observed in<br>
real materials. This “quantum metric,” once thought purely theoretical, may<br>
revolutionize electronics, superconductivity, and ultrafast devices.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Albert Einstein; Consumer Electronics; Spintronics<br>
Research; Computers and Internet; Hacking; Computer Modeling.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/09/250905112310.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-24T00:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Anything-goes “anyons” may be at the root of surprising quantum experiments
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions, superconductivity, Magnetism, quantum computing, stable qubits
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT theoretical physicists may have an explanation for the surprising observation that<br>
superconductivity and magnetism can co-exist in some materials. They propose that<br>
under certain conditions, a magnetic material’s electrons could splinter into<br>
quasiparticles known as “anyons,” some of which could flow together without friction —<br>
an entirely new form of superconductivity.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: MIT physics, Research Laboratory of Electronics, Senthil Todadri, electron<br>
fractions, fractional quantum anomalous Hall effect, anyons, bosons, Fermions,<br>
superconductivity, Magnetism, quantum computing, stable qubits.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/anything-goes-anyons-may-be-root-surprising-quantum-experiments-1222 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T23:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Multiplexing entanglement in a quantum network
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics Research; Computers and Internet; Communications; Internet
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers use rare-earth ions to achieve the first-ever demonstration of<br>
entanglement multiplexing between individual memory qubits in a quantum network.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Physics; Nanotechnology; Telecommunications; Spintronics<br>
Research; Computers and Internet; Communications; Internet.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/02/250226125136.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T22:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
NIST Physicists Bring Unruly Molecules to the Quantum Party
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
NIST · Quantum science · 2025-12-18
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Molecules can serve as versatile building blocks for quantum technologies, but they<br>
are much harder to control than atoms.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-12-18.<br>
The selected source is NIST; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.<br>
Readers can follow the source link for the complete article, credits and surrounding<br>
context.
</div>

<div style="margin-top:8px;">
[https://www.nist.gov/news-events/news/2025/12/nist-physicists-bring-unruly-molecules-quantum-party Read the full article at NIST ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: NIST. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: NIST · 2025-12-18
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T21:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Photons collide in the void: Quantum simulation creates light out of nothing
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Energy and Resources; Optics; Physics; Telecommunications; Civil Engineering; Virtual Environment; Quantum Physics; Electricity
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists have managed to simulate a strange quantum phenomenon where light appears<br>
to arise from empty space a concept that until now has only existed in theory. Using<br>
cutting-edge simulations, researchers modeled how powerful lasers interact with the<br>
so-called quantum vacuum, revealing how photons could bounce off each other and even<br>
generate new beams of light. These breakthroughs come just as new ultra-powerful laser<br>
facilities are preparing to test these mind-bending effects in reality, potentially<br>
opening a gateway to uncovering new physics and even dark matter particles.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Energy and Resources; Optics; Physics; Telecommunications; Civil<br>
Engineering; Virtual Environment; Quantum Physics; Electricity.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250608072527.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T20:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Why some quantum materials stall while others scale
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Mingda Li, Quantum materials
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
MIT researchers developed a way to evaluate the scale-up potential of quantum<br>
materials, combining a material’s quantum behavior with its cost, supply chain<br>
resilience, and environmental footprint. The approach could help researchers identify<br>
materials for next-generation microelectronics, energy harvesting applications, and<br>
medical diagnostics.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Mingda Li, Quantum materials.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/why-some-quantum-materials-stall-while-others-scale-1015 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T19:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Physicists Take the Imaginary Numbers Out of Quantum Mechanics | Quanta Magazine
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
Quanta Magazine · Quantum science · 2025-11-07
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Quantum mechanics has at last been formulated exclusively with real numbers, bringing<br>
a mathematical puzzle at the heart of the theory into a new era of inquiry.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Quantum science.<br>
Publication or update date: 2025-11-07.<br>
The selected source is Quanta Magazine; the full article link appears below this<br>
preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.quantamagazine.org/physicists-take-the-imaginary-numbers-out-of-quantum-mechanics-20251107/ Read the full article at Quanta Magazine ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: Quanta Magazine. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: Quanta Magazine · 2025-11-07
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T18:10:12Z

Maintenance script: Update rotating external quantum article

Template:Mainpage rotating external quantum article

2026-05-23T17:10:10Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
A simple twist unlocks never-before-seen quantum behavior
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors; Engineering and Construction; Materials Science
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Scientists have discovered a revolutionary new method for creating quantum states by<br>
twisting materials at the M-point, revealing exotic phenomena previously out of reach.<br>
This new direction dramatically expands the moiré toolkit and may soon lead to the<br>
experimental realization of long-sought quantum spin liquids.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Spintronics; Chemistry; Graphene; Inorganic Chemistry; Physics; Detectors;<br>
Engineering and Construction; Materials Science.<br>
The selected source is ScienceDaily; the full article link appears below this preview.<br>
The right-side image is selected from the same article URL when a usable article image<br>
is available.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/07/250710113201.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T16:10:09Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Researchers establish new basis for quantum sensing and communication
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
MIT News | Massachusetts Institute of Technology · Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory, quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications, quantum information, non-Gaussian quantum states
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Researchers have established a new basis for quantum sensing and communication. Their<br>
theoretical approach for generating quantum states could be crucial for many areas,<br>
ranging from fingerprinting the magnetic field of the Earth to enhancing astrophysical<br>
research.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Moe Win, MIT AeroAstro, MIT LIDS, MIT IDSS, Quantum neXus Laboratory,<br>
quantum sensing, photon-varied Gaussian states (PVGSs), quantum communications,<br>
quantum information, non-Gaussian quantum states.<br>
The selected source is MIT News | Massachusetts Institute of Technology; the full<br>
article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://news.mit.edu/2025/researchers-establish-new-basis-quantum-sensing-communication-0313 Read the full article at MIT News | Massachusetts Institute of Technology ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: MIT News | Massachusetts Institute of Technology. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: MIT News | Massachusetts Institute of Technology
</div>

</div>

Template:Mainpage rotating external quantum article

2026-05-23T15:10:08Z

Maintenance script: Update rotating external quantum article

<div style="border:1px solid #d8e8d8; background:#fff8cc; padding:12px 14px; margin:12px 0; line-height:1.45; border-radius:4px; overflow:auto;">

<div class="mainpage-external-quantum-image-box">
<div class="mainpage-external-quantum-image"></div>
<div class="mainpage-external-quantum-image-click">
[https://scholarlywiki.org/mainpage/external_quantum_article.png Open image full size]
</div>
<div style="margin-top:5px; color:#555;">
Image from or related to the featured external quantum article.
</div>
</div>

<div style="font-weight:bold; color:#006b45; font-size:120%; margin-bottom:6px;">
Featured external quantum article
</div>

<div style="font-size:120%; font-weight:bold; margin-bottom:4px;">
Sharper than lightning: Oxford’s one-in-6.7-million quantum breakthrough
</div>

<div style="font-size:90%; color:#555; margin-bottom:8px;">
ScienceDaily · Computers and Internet; Computer Modeling; Computer Science; Hacking; Quantum Computers; Distributed Computing; Communications; Math Puzzles
</div>

<div style="margin-top:8px;">
'''Article preview.'''<br>
Physicists at the University of Oxford have set a new global benchmark for the<br>
accuracy of controlling a single quantum bit, achieving the lowest-ever error rate for<br>
a quantum logic operation--just 0.000015%, or one error in 6.7 million operations.<br>
This record-breaking result represents nearly an order of magnitude improvement over<br>
the previous benchmark, set by the same research group a decade ago.<br>
The article is featured here because it connects current quantum research with a<br>
broader scientific or technological problem.<br>
The preview highlights the main idea while leaving the detailed evidence, figures and<br>
technical discussion to the original source.<br>
Topic area: Computers and Internet; Computer Modeling; Computer Science; Hacking;<br>
Quantum Computers; Distributed Computing; Communications; Math Puzzles.<br>
The selected source is ScienceDaily; the full article link appears below this preview.
</div>

<div style="margin-top:8px;">
[https://www.sciencedaily.com/releases/2025/06/250610074301.htm Read the full article at ScienceDaily ->]
</div>

<div style="margin-top:8px; font-size:90%; color:#666;">
External source: ScienceDaily. Selected external quantum article.
</div>

<div style="margin-top:4px; font-size:90%; color:#666;">
Credits: ScienceDaily
</div>

</div>

Biography:Margaret Murnane

2026-05-23T15:08:12Z

Maintenance script: Clean biography and add portrait

{{Short description|Irish physicist and pioneer of ultrafast x-ray science}}
{{Infobox scientist
| name = Margaret Murnane
| image = Margaret_Murnane_2016.jpg
| caption = Margaret Murnane
| birth_name = Margaret Mary Murnane
| birth_date = 23 January 1959
| birth_place = County Limerick, Ireland
| fields = Physics; atomic, molecular, and optical physics; laser science; ultrafast x-ray science
| work_institutions = University of Colorado Boulder; University of Michigan; Washington State University; University of California, Berkeley
| alma_mater = University College Cork; University of California, Berkeley
| known_for = Ultrafast x-ray science; high-harmonic generation; tabletop coherent x-ray sources; nanometer-scale imaging
| spouse = [[Biography:Henry Kapteyn|Henry Kapteyn]]
| awards = MacArthur Fellowship (2000); Frederic Ives Medal/Jarus W. Quinn Prize; Benjamin Franklin Medal in Physics; R. W. Wood Prize
}}

'''Margaret Mary Murnane''' (born 23 January 1959) is an Irish physicist known for work in ultrafast laser science, high-harmonic generation, and coherent x-ray sources. She is a Distinguished Professor at the University of Colorado Boulder and a fellow of JILA, where her research connects laser physics, atomic and molecular physics, nanoscience, and materials imaging.<ref>{{Cite web |title=Margaret Murnane |url=https://en.wikipedia.org/wiki/Margaret_Murnane |publisher=Wikipedia |access-date=2026-05-23}}</ref><ref>{{Cite web |title=Murnane, Margaret |url=https://history.aip.org/phn/11607013.html |publisher=American Institute of Physics |access-date=2026-05-23}}</ref>

Murnane's work helped establish tabletop ultrafast x-ray science: the use of compact laser-driven sources to generate coherent extreme-ultraviolet and soft x-ray light. These sources allow researchers to observe fast electronic, magnetic, chemical, and structural dynamics in matter.

== Quantum and optical physics ==
High-harmonic generation is a strongly quantum process in which intense laser fields drive electrons away from atoms or solids and then back again, producing bursts of high-frequency light. Murnane and collaborators developed experimental methods that made this process useful as a coherent laboratory-scale x-ray source.

In the Quantum Collection, Murnane is especially connected with:
* [[Physics:Quantum optics]]
* [[Physics:Quantum dynamics]]
* [[Physics:Quantum matter]]
* [[Physics:Quantum spectroscopy]]

== Ultrafast x-ray science ==
Murnane's research group uses femtosecond and attosecond light pulses to study how electrons, spins, and lattice motion evolve in materials. This work links quantum dynamics with practical imaging and spectroscopy tools. It is important for observing processes that are too fast for ordinary optical or x-ray instruments.

She has also worked closely with [[Biography:Henry Kapteyn|Henry Kapteyn]] on laser-driven coherent x-ray generation and founded KMLabs with him to commercialize ultrafast laser technology.

== Recognition ==
Murnane received a MacArthur Fellowship in 2000. Her later honors include major awards from optics and physics organizations for contributions to ultrafast optical science, coherent x-ray generation, and imaging.<ref>{{Cite web |title=Margaret Murnane, Ph.D. |url=https://www.simonsfoundation.org/people/margaret-murnane/ |publisher=Simons Foundation |access-date=2026-05-23}}</ref>

== See also ==
* [[Biography:Henry Kapteyn]]
* [[Physics:Quantum optics]]
* [[Physics:Quantum dynamics]]
* [[Physics:Quantum spectroscopy]]

== References ==
{{reflist|3}}

== External links ==
* [https://www.colorado.edu/physics/margaret-murnane University of Colorado Boulder profile]
* [https://jila.colorado.edu/kmgroup/ Kapteyn-Murnane group]
* [https://history.aip.org/phn/11607013.html American Institute of Physics profile]

{{Author|Harold Foppele}}

{{Sourceattribution|Biography:Margaret Murnane|1}}

File:Margaret Murnane 2016.jpg

2026-05-23T15:08:12Z

Maintenance script: Import Margaret Murnane portrait

== Summary ==
Importing file

File:Mr. Toshikazu Sunada.jpg

2026-05-23T14:41:16Z

Maintenance script: Import biography image for Quantum Collection

== Summary ==
Import biography image for Quantum Collection

File:Xue Qikun 2023.jpg

2026-05-23T14:41:16Z

Maintenance script: Import biography image for Quantum Collection

== Summary ==
Import biography image for Quantum Collection

Biography:Thomas Young (scientist)

2026-05-23T14:41:16Z

Maintenance script: Create compact quantum-linked biography

{{Short description|English polymath known for the double-slit experiment}}
{{Infobox scientist
| name = Thomas Young
| birth_date = 13 June 1773
| birth_place = Milverton, Somerset, England
| death_date = 10 May 1829
| death_place = London, England
| fields = Physics; physiology; linguistics
| work_institutions = Royal Institution; St George's Hospital
| alma_mater = University of Edinburgh; University of Gottingen; Emmanuel College, Cambridge
| known_for = Double-slit experiment; wave theory of light; Young's modulus
}}

'''Thomas Young''' (13 June 1773 - 10 May 1829) was an English polymath whose double-slit interference experiment became a classic demonstration of the wave nature of light.

== Quantum context ==
Young's interference experiment predated quantum mechanics, but it became central to quantum physics because single-particle interference shows that wave-like probability amplitudes govern quantum behavior.

His name is therefore linked from the [[Physics:Quantum eraser experiment]], where interference and which-path information are used to probe complementarity.

== Linked Quantum Collection pages ==
* [[Physics:Quantum eraser experiment]]
* [[Physics:Quantum Wave-particle duality]]
* [[Physics:Quantum interference]]
* [[Physics:Quantum Complementarity principle]]

== References ==
{{reflist|3}}
* {{Cite web |title=Thomas Young |url=https://www.britannica.com/biography/Thomas-Young |publisher=Encyclopaedia Britannica |access-date=2026-05-23}}
* {{Cite journal |last=Young |first=Thomas |year=1804 |title=Experiments and calculations relative to physical optics |journal=Philosophical Transactions of the Royal Society of London |volume=94 |pages=1-16 |doi=10.1098/rstl.1804.0001}}

{{Author|Harold Foppele}}

{{Sourceattribution|Biography:Thomas Young (scientist)|1}}

Biography:Toshikazu Sunada

2026-05-23T14:41:14Z

Maintenance script: Create compact quantum-linked biography

{{Short description|Mathematician known for spectral geometry}}
{{Infobox scientist
| name = Toshikazu Sunada
| image = Mr._Toshikazu_Sunada.jpg
| caption = Toshikazu Sunada
| birth_date = 7 September 1948
| birth_place = Tokyo, Japan
| fields = Mathematics; spectral geometry; discrete geometric analysis
| work_institutions = Meiji University; Tohoku University; Nagoya University
| alma_mater = University of Tokyo
| known_for = Sunada's method; isospectral manifolds; spectral geometry
}}

'''Toshikazu Sunada''' (born 7 September 1948) is a Japanese mathematician known for Sunada's method in spectral geometry and for work on discrete geometric analysis.

== Quantum context ==
Sunada's method constructs different geometric spaces with the same spectral data. Such isospectral examples are important background for quantum chaos and quantum ergodicity, where spectra encode dynamical and geometric information.

The Quantum Collection link to [[Physics:Quantum ergodicity]] reflects this connection between eigenvalues, wave behavior, and the geometry of quantum systems.

== Linked Quantum Collection pages ==
* [[Physics:Quantum ergodicity]]
* [[Physics:Quantum chaos]]
* [[Physics:Quantum Eigenstates and eigenvalues]]
* [[Physics:Quantum Wavefunction]]

== References ==
{{reflist|3}}
* {{Cite journal |last=Sunada |first=Toshikazu |year=1985 |title=Riemannian coverings and isospectral manifolds |journal=Annals of Mathematics |volume=121 |issue=1 |pages=169-186 |doi=10.2307/1971195}}
* {{Cite web |title=Toshikazu Sunada |url=https://www.ms.u-tokyo.ac.jp/people/sunada.html |publisher=University of Tokyo |access-date=2026-05-23}}

{{Author|Harold Foppele}}

{{Sourceattribution|Biography:Toshikazu Sunada|1}}

Biography:Viacheslav Belavkin

2026-05-23T14:41:12Z

Maintenance script: Create compact quantum-linked biography

{{Short description|Mathematical physicist known for quantum filtering}}
{{Infobox scientist
| name = Viacheslav Belavkin
| birth_date = 17 May 1946
| birth_place = Soviet Union
| death_date = 27 November 2012
| death_place = United Kingdom
| fields = Mathematical physics; probability; quantum information
| work_institutions = University of Nottingham; Moscow Institute of Physics and Technology
| alma_mater = Moscow Institute of Physics and Technology
| known_for = Quantum filtering; quantum stochastic calculus; Belavkin equation
}}

'''Viacheslav Pavlovich Belavkin''' (17 May 1946 - 27 November 2012) was a mathematical physicist known for quantum filtering, quantum stochastic calculus, and the theory of continuous quantum measurement.

== Quantum context ==
Belavkin developed mathematical tools for updating quantum states under continuous observation. These ideas are used in quantum trajectories, feedback control, and the operational description of measurement.

His work is relevant to [[Physics:Quantum logic]], quantum operations, and open-system descriptions where information is acquired over time.

== Linked Quantum Collection pages ==
* [[Physics:Quantum logic]]
* [[Physics:Quantum operation]]
* [[Physics:Quantum Trajectory Theory]]
* [[Physics:Quantum measurement theory]]

== References ==
{{reflist|3}}
* {{Cite journal |last=Belavkin |first=V. P. |year=1989 |title=A new wave equation for a continuous nondemolition measurement |journal=Physics Letters A |volume=140 |issue=7-8 |pages=355-358 |doi=10.1016/0375-9601(89)90066-2}}
* {{Cite journal |last=Belavkin |first=V. P. |year=1992 |title=Quantum continual measurements and a posteriori collapse on CCR |journal=Communications in Mathematical Physics |volume=146 |pages=611-635 |doi=10.1007/BF02097018}}

{{Author|Harold Foppele}}

{{Sourceattribution|Biography:Viacheslav Belavkin|1}}