Latest revision as of 11:34, 22 May 2026

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The Lawson criterion is a figure of merit used in nuclear fusion research. It compares the rate of energy generated by fusion reactions within fusion fuel to the rate of energy losses from the plasma environment. When the rate of energy production exceeds the rate of energy loss, the fusion system can produce net energy. If enough of this energy is retained within the plasma to sustain further reactions, the plasma reaches ignition.^[1]

The concept was first developed by John D. Lawson in a classified 1955 report at the Atomic Energy Research Establishment in Harwell, United Kingdom.^[2] The work was later declassified and formally published in 1957.^[1]

As originally formulated, the Lawson criterion defines a minimum value for the product of plasma density and energy confinement time required to obtain net fusion power. Later refinements introduced the more useful fusion triple product, which combines plasma density, temperature, and confinement time into a single performance measure.^[1]

On 8 August 2021, researchers at the National Ignition Facility at Lawrence Livermore National Laboratory announced an inertial confinement fusion experiment that exceeded the Lawson criterion for ignition conditions.^[3]^[4]

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Lawson criterion and triple-product performance of major magnetic confinement fusion experiments.

Energy balance

The Lawson criterion is based on the energy balance of a fusion plasma. A fusion reactor can only produce net power when the fusion heating exceeds all energy losses.

Net power = Efficiency × (Fusion − Radiation loss − Conduction loss)

Fusion is the energy generated by nuclear fusion reactions.
Radiation loss is the energy lost through electromagnetic radiation such as X-rays.
Conduction loss is the energy carried away by escaping plasma particles.
Efficiency measures how effectively the reactor converts fusion energy into useful power.

Lawson estimated the fusion power using a thermalized plasma obeying a Maxwell–Boltzmann distribution.^[5]

The volumetric fusion reaction rate is approximately:

$Fusion rate = n_{A} n_{B} ⟨ σ v ⟩ E$

where:

$n_{A}$ and $n_{B}$ are the number densities of the fusion fuels,
$σ$ is the fusion cross section,
$v$ is the relative particle velocity,
$E$ is the fusion energy released per reaction.

Lawson also estimated radiation losses using the bremsstrahlung relation:

P_B = 1.4 \times 10^{-34} N^2 T^{1/2} \frac{\mathrm{W}}{\mathrm{cm}^3}

where $N$ is the plasma number density and $T$ is the plasma temperature.^[1]

By balancing fusion power against radiation losses, Lawson estimated minimum ignition temperatures of approximately:

30 million K (2.6 keV) for the deuterium–tritium reaction,
150 million K (12.9 keV) for the deuterium–deuterium reaction.^[1]^[6]

Confinement time

The energy confinement time $τ_{E}$ measures how long a plasma retains its energy before losses dominate.

\tau_E = \frac{W}{P_{\mathrm{loss}}}

where:

$W$ is the plasma energy density,
$P_{l o s s}$ is the power loss density.

For a steady-state fusion reactor, fusion heating must at least balance energy losses:

f E_{\rm ch} \ge P_{\rm loss}

For a 50–50 deuterium–tritium plasma, the Lawson criterion becomes:

n\tau_E \ge \frac{12T}{E_{\rm ch}\langle\sigma v\rangle}

For the D–T reaction, the minimum required value is approximately:

n\tau_E \ge 1.5 \times 10^{20}\ \frac{\mathrm{s}}{\mathrm{m}^3}

The minimum occurs near a plasma temperature of approximately 26 keV.^[1]

Triple product

A more useful performance parameter is the fusion triple product:

nT\tau_E

This combines plasma density, temperature, and confinement time. For the D–T reaction, the minimum required triple product is approximately:

nT\tau_E \ge 3 \times 10^{21}\ \mathrm{keV\ s\ m^{-3}}

The optimum temperature for this condition is near 14 keV.^[7]

Major fusion experiments such as JT-60, TFTR, JET, and ITER are often evaluated using the triple-product diagram shown above.^[8]

Inertial confinement

The Lawson criterion also applies to magnetic confinement fusion and inertial confinement fusion. In inertial confinement systems, confinement time is determined by the expansion time of the compressed fuel pellet.

For inertial confinement fusion, the criterion is often written as:

\rho R \ge 1\ \mathrm{g/cm^2}

where:

$ρ$ is the fuel density,
$R$ is the fuel radius.

Achieving this condition generally requires extremely high compression ratios produced by powerful laser systems.^[9]

Non-thermal systems

The Lawson criterion was originally derived for thermalized plasmas, but some fusion concepts use non-thermal particle distributions. Examples include the fusor, polywell, and migma concepts.

In such systems, energy losses from radiation and particle conduction remain major obstacles to net energy production.^[10]

Table of contents (84 articles)

Index

Composite matter

1. Materials

2. Matter

3. Plasma and fusion physics

4. Molecules

5. Nuclear matter

Sub-molecular

6. Atoms

7. Particles

8. Composite particles

9. Fields

10. Vacuum and spacetime

Full contents

1. Materials (6) Back to index

1. Physics:Quantum materials/band structure

2. Physics:Quantum materials/phonon

3. Physics:Quantum materials/superconductor

4. Physics:Quantum materials/topological phase

5. Physics:Quantum materials/crystal lattice

6. Physics:Quantum materials/solid state

2. Matter (5) Back to index

7. Physics:Quantum matter/phase

8. Physics:Quantum matter/state of matter

9. Physics:Quantum matter/thermodynamic system

10. Physics:Quantum matter/density

11. Physics:Quantum matter/temperature

3. Plasma and fusion physics (6) Back to index

12. Physics:Quantum Tokamak

13. Physics:Quantum Fusion

14. Physics:Quantum matter/plasma

15. Physics:Quantum magnetic confinement

16. Physics:Quantum Lawson criterion

17. Physics:Quantum Quark–gluon plasma

4. Molecules (6) Back to index

18. Physics:Quantum molecular structure

19. Physics:Quantum chemical bond

20. Physics:Quantum molecular orbital

21. Physics:Quantum degenerate orbitals

22. Physics:Quantum molecular spectroscopy

23. Physics:Quantum molecular vibration

5. Nuclear matter (6) Back to index

24. Physics:Quantum atomic nucleus

25. Physics:Quantum nuclear matter

26. Physics:Quantum isotope

27. Physics:Quantum deuteron

28. Physics:Quantum nuclear binding energy

29. Physics:Quantum nuclear force

6. Atoms (7) Back to index

30. Physics:Quantum atoms/electron

31. Physics:Quantum atoms/energy level

32. Physics:Quantum atoms/electron configuration

33. Physics:Quantum atoms/transition

34. Physics:Quantum atoms/ion

35. Physics:Quantum atoms/orbital

36. Physics:Quantum atoms/hydrogen

7. Particles (12) Back to index

37. Physics:Quantum particle

38. Physics:Quantum elementary particle

39. Physics:Quantum fermion

40. Physics:Quantum boson

41. Physics:Quantum lepton

42. Physics:Quantum electron

43. Physics:Quantum neutrino

44. Physics:Quantum quark

45. Physics:Quantum photon

46. Physics:Quantum gluon

47. Physics:Quantum W and Z bosons

48. Physics:Quantum Higgs boson

8. Composite particles (12) Back to index

49. Physics:Quantum hadron

50. Physics:Quantum baryon

51. Physics:Quantum meson

52. Physics:Quantum nucleon

53. Physics:Quantum proton

54. Physics:Quantum neutron

55. Physics:Quantum pion

56. Physics:Quantum kaon

57. Physics:Quantum glueball

58. Physics:Quantum tetraquark

59. Physics:Quantum pentaquark

60. Physics:Quantum exotic hadron

9. Fields (12) Back to index

61. Physics:Quantum field theory

62. Physics:Quantum electromagnetic field

63. Physics:Quantum gauge field

64. Physics:Quantum scalar field

65. Physics:Quantum vacuum field

66. Physics:Quantum wavefunction field

67. Physics:Quantum spinor field

68. Physics:Quantum matter field

69. Physics:Quantum Higgs field

70. Physics:Quantum Yang-Mills field

71. Physics:Quantum photon field

72. Physics:Quantum gluon field

10. Vacuum and spacetime (12) Back to index

73. Physics:Quantum spacetime

74. Physics:Quantum vacuum energy

75. Physics:Quantum virtual particle

76. Physics:Quantum zero-point energy

77. Physics:Quantum curved spacetime

78. Physics:Quantum quantum gravity

79. Physics:Quantum vacuum state

80. Physics:Quantum false vacuum

81. Physics:Quantum Planck scale

82. Physics:Quantum spacetime foam

83. Physics:Quantum metric field

84. Physics:Quantum field theory in curved spacetime

References

↑ ^1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 Lawson, J. D. (1957). "Some Criteria for a Power Producing Thermonuclear Reactor". Proceedings of the Physical Society, Section B 70 (1): 6–10. doi:10.1088/0370-1301/70/1/303. Bibcode: 1957PPSB...70....6L.
↑ ^{[|permanent dead link|dead link}}]}
↑ [[1](https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it) "Scientists Achieved Self-Sustaining Nuclear Fusion… But Now They Can't Replicate It"]. ScienceAlert. August 16, 2022. [2](https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it).
↑ Abu-Shawareb, H.; Acree, R.; Adams, P.; Adams, J.; Addis, B. (2022-08-08). "Lawson Criterion for Ignition Exceeded in an Inertial Fusion Experiment". Physical Review Letters 129 (7). doi:10.1103/PhysRevLett.129.075001. PMID 36018710. Bibcode: 2022PhRvL.129g5001A.
↑ Spitzer, Lyman; Seeger, Raymond J. (1963). "Physics of Fully Ionized Gases". American Journal of Physics 31 (11): 890–891. doi:10.1119/1.1969155. Bibcode: 1963AmJPh..31..890S.
↑ [[3](https://www.phys.ksu.edu/personal/cdlin/phystable/econvert.html) "Energy Converter"]. Kansas State University. [4](https://www.phys.ksu.edu/personal/cdlin/phystable/econvert.html).
↑ Wesson, J. (2004). [[5](https://pdfhost.io/view/NMf0wmfoq_Wesson_J_Tokamaks_3Ed_Oxford_2004_K_T_755Spdf) "Tokamaks"]. Oxford Engineering Science Series (Oxford: Clarendon Press) (48). [6](https://pdfhost.io/view/NMf0wmfoq_Wesson_J_Tokamaks_3Ed_Oxford_2004_K_T_755Spdf).
↑ [[7](http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html) "World Highest Fusion Triple Product Marked in High-βp H-mode Plasmas"]. [8](http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html).
↑ Hirsch, Robert L. (1967). "Inertial-Electrostatic Confinement of Ionized Fusion Gases". Journal of Applied Physics 38 (11): 4522–4534. doi:10.1063/1.1709162. Bibcode: 1967JAP....38.4522H.
↑ Rider, Todd H. (1997-04-01). "Fundamental limitations on plasma fusion systems not in thermodynamic equilibrium". Physics of Plasmas 4 (4): 1039–1046. doi:10.1063/1.872556. Bibcode: 1997PhPl....4.1039R.

Author: Harold Foppele

Source attribution: Physics:Quantum Lawson criterion

[Lawson-1] 1.0 ^1.1 ^1.2 ^1.3 ^1.4 ^1.5 Lawson, J. D. (1957). "Some Criteria for a Power Producing Thermonuclear Reactor". Proceedings of the Physical Society, Section B 70 (1): 6–10. doi:10.1088/0370-1301/70/1/303. Bibcode: 1957PPSB...70....6L.

[2] {[|permanent dead link|dead link}}]}

[3] [[1](https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it) "Scientists Achieved Self-Sustaining Nuclear Fusion… But Now They Can't Replicate It"]. ScienceAlert. August 16, 2022. [2](https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it).

[4] Abu-Shawareb, H.; Acree, R.; Adams, P.; Adams, J.; Addis, B. (2022-08-08). "Lawson Criterion for Ignition Exceeded in an Inertial Fusion Experiment". Physical Review Letters 129 (7). doi:10.1103/PhysRevLett.129.075001. PMID 36018710. Bibcode: 2022PhRvL.129g5001A.

[autogenerated1963-5] Spitzer, Lyman; Seeger, Raymond J. (1963). "Physics of Fully Ionized Gases". American Journal of Physics 31 (11): 890–891. doi:10.1119/1.1969155. Bibcode: 1963AmJPh..31..890S.

[6] [[3](https://www.phys.ksu.edu/personal/cdlin/phystable/econvert.html) "Energy Converter"]. Kansas State University. [4](https://www.phys.ksu.edu/personal/cdlin/phystable/econvert.html).

[7] Wesson, J. (2004). [[5](https://pdfhost.io/view/NMf0wmfoq_Wesson_J_Tokamaks_3Ed_Oxford_2004_K_T_755Spdf) "Tokamaks"]. Oxford Engineering Science Series (Oxford: Clarendon Press) (48). [6](https://pdfhost.io/view/NMf0wmfoq_Wesson_J_Tokamaks_3Ed_Oxford_2004_K_T_755Spdf).

[8] [[7](http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html) "World Highest Fusion Triple Product Marked in High-βp H-mode Plasmas"]. [8](http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html).

[9] Hirsch, Robert L. (1967). "Inertial-Electrostatic Confinement of Ionized Fusion Gases". Journal of Applied Physics 38 (11): 4522–4534. doi:10.1063/1.1709162. Bibcode: 1967JAP....38.4522H.

[10] Rider, Todd H. (1997-04-01). "Fundamental limitations on plasma fusion systems not in thermodynamic equilibrium". Physics of Plasmas 4 (4): 1039–1046. doi:10.1063/1.872556. Bibcode: 1997PhPl....4.1039R.

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@@ Line 1: / Line 1: @@
 {{Short description|Criterion for igniting a nuclear fusion chain reaction}}
+{{Quantum matter backlink|Plasma and fusion physics}}
+{{Quantum article nav|previous=Physics:Quantum magnetic confinement|previous label=Magnetic confinement|next=Physics:Quantum Quark–gluon plasma|next label=Quark–gluon plasma}}
+<div style="display:flex; gap:24px; align-items:flex-start; max-width:1200px;">
-{{Quantum matter backlink|Plasma and fusion physics}}
+<div style="width:280px;">
+__TOC__
+</div>
-The '''Lawson criterion''' is a [[figure of merit]] used in [[Physics:Quantum Fusion|nuclear fusion]] research. It compares the rate of energy generated by fusion reactions within fusion fuel to the rate of energy losses from the plasma environment. When the rate of energy production exceeds the rate of energy loss, the fusion system can produce net energy. If enough of this energy is retained within the plasma to sustain further reactions, the plasma reaches [[Physics:Quantum Fusion#Ignition|ignition]].<ref name="Lawson"/>
+<div style="flex:1; line-height:1.45; color:#006b45; column-count:2; column-gap:32px; column-rule:1px solid #b8d8c8;">
+The '''Lawson criterion''' is a figure of merit used in [[Physics:Quantum Fusion|nuclear fusion]] research. It compares the rate of energy generated by fusion reactions within fusion fuel to the rate of energy losses from the plasma environment. When the rate of energy production exceeds the rate of energy loss, the fusion system can produce net energy. If enough of this energy is retained within the plasma to sustain further reactions, the plasma reaches [[Physics:Quantum Fusion#Ignition|ignition]].<ref name="Lawson"/>
-The concept was first developed by [[John D. Lawson (scientist)|John D. Lawson]] in a classified 1955 report at the Atomic Energy Research Establishment in Harwell, United Kingdom.<ref>{{cite tech report
+The concept was first developed by John D. Lawson in a classified 1955 report at the Atomic Energy Research Establishment in Harwell, United Kingdom.<ref>{{Dead link|date=November 2023}}</ref> The work was later declassified and formally published in 1957.<ref name="Lawson">{{Cite journal
-|last=Lawson
-|first=J. D.
-|title=Some criteria for a useful thermonuclear reactor
-|date=December 1955
-|issue=A.E.R.E. GP/R 1807
-|institution=Atomic Energy Research Establishment, Harwell, Berkshire, U. K.
-|url=[https://www.euro-fusion.org/fileadmin/user_upload/Archive/wp-content/uploads/2012/10/dec05-aere-gpr1807.pdf](https://www.euro-fusion.org/fileadmin/user_upload/Archive/wp-content/uploads/2012/10/dec05-aere-gpr1807.pdf)
-}}{{Dead link|date=November 2023}}</ref> The work was later declassified and formally published in 1957.<ref name="Lawson">{{Cite journal
 |last=Lawson
 |first=J. D.
@@ Line 28: / Line 26: @@
 As originally formulated, the Lawson criterion defines a minimum value for the product of plasma density and energy confinement time required to obtain net fusion power. Later refinements introduced the more useful '''fusion triple product''', which combines plasma density, temperature, and confinement time into a single performance measure.<ref name="Lawson"/>
-On 8 August 2021, researchers at the [[National Ignition Facility]] at [[Lawrence Livermore National Laboratory]] announced an inertial confinement fusion experiment that exceeded the Lawson criterion for ignition conditions.<ref>{{cite web
+On 8 August 2021, researchers at the National Ignition Facility at Lawrence Livermore National Laboratory announced an inertial confinement fusion experiment that exceeded the Lawson criterion for ignition conditions.<ref>{{cite web
 |url=[https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it](https://www.sciencealert.com/scientists-achieved-self-sustaining-nuclear-fusion-but-now-they-cant-replicate-it)
 |title=Scientists Achieved Self-Sustaining Nuclear Fusion… But Now They Can't Replicate It
@@ Line 57: / Line 55: @@
 |doi-access=free
 }}</ref>
-<div style="float:right; border:1px solid #e0d890; background:#fff8cc; padding:6px; margin:0 0 1em 1em; width:420px;">
-[[File:The Lawson Criterion.png|400px]]
-<div style="font-size:90%;">Lawson criterion and triple-product performance of major magnetic confinement fusion experiments.</div>
 </div>
+<div style="width:300px;">
+[[File:The Lawson Criterion.png|thumb|280px|Lawson criterion and triple-product performance of major magnetic confinement fusion experiments.]]
+</div>
+</div>
 == Energy balance ==
@@ Line 68: / Line 71: @@
 #'''Fusion''' is the energy generated by nuclear fusion reactions.
-#'''Radiation loss''' is the energy lost through electromagnetic radiation such as [[X-rays]].
+#'''Radiation loss''' is the energy lost through electromagnetic radiation such as X-rays.
 #'''Conduction loss''' is the energy carried away by escaping plasma particles.
 #'''Efficiency''' measures how effectively the reactor converts fusion energy into useful power.
-Lawson estimated the fusion power using a thermalized plasma obeying a [[Maxwell–Boltzmann distribution]].<ref name="autogenerated1963">{{Cite journal
+Lawson estimated the fusion power using a thermalized plasma obeying a Maxwell–Boltzmann distribution.<ref name="autogenerated1963">{{Cite journal
 |last1=Spitzer
 |first1=Lyman
@@ Line 98: / Line 101: @@
 * <math>n_A</math> and <math>n_B</math> are the number densities of the fusion fuels,
-* <math>\sigma</math> is the fusion [[Cross section (physics)|cross section]],
+* <math>\sigma</math> is the fusion cross section,
 * <math>v</math> is the relative particle velocity,
 * <math>E</math> is the fusion energy released per reaction.
@@ Line 110: / Line 113: @@
 By balancing fusion power against radiation losses, Lawson estimated minimum ignition temperatures of approximately:
-* 30 million K (2.6 keV) for the [[deuterium]]–[[tritium]] reaction,
+* 30 million K (2.6 keV) for the [[Physics:Quantum deuteron|deuterium]]–tritium reaction,
 * 150 million K (12.9 keV) for the deuterium–deuterium reaction.<ref name="Lawson"/><ref>{{Cite web
    |title=Energy Converter
@@ Line 166: / Line 169: @@
 }}</ref>
-Major fusion experiments such as [[JT-60]], [[TFTR]], [[JET]], and [[ITER]] are often evaluated using the triple-product diagram shown above.<ref>{{cite web
+Major fusion experiments such as JT-60, TFTR, JET, and ITER are often evaluated using the triple-product diagram shown above.<ref>{{cite web
 |url=[http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html](http://www-jt60.naka.jaea.go.jp/english/html/exp_rep/rep36.html)
 |title=World Highest Fusion Triple Product Marked in High-βp H-mode Plasmas
@@ Line 175: / Line 178: @@
 == Inertial confinement ==
-The Lawson criterion also applies to [[Physics:Quantum Magnetic confinement fusion|magnetic confinement fusion]] and [[inertial confinement fusion]]. In inertial confinement systems, confinement time is determined by the expansion time of the compressed fuel pellet.
+The Lawson criterion also applies to [[Physics:Quantum Magnetic confinement fusion|magnetic confinement fusion]] and inertial confinement fusion. In inertial confinement systems, confinement time is determined by the expansion time of the compressed fuel pellet.
 For inertial confinement fusion, the criterion is often written as:
@@ Line 201: / Line 204: @@
 == Non-thermal systems ==
-The Lawson criterion was originally derived for thermalized plasmas, but some fusion concepts use non-thermal particle distributions. Examples include the [[fusor]], [[polywell]], and [[migma]] concepts.
+The Lawson criterion was originally derived for thermalized plasmas, but some fusion concepts use non-thermal particle distributions. Examples include the fusor, polywell, and migma concepts.
 In such systems, energy losses from radiation and particle conduction remain major obstacles to net energy production.<ref>{{Cite journal

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Latest revision as of 11:34, 22 May 2026

Contents

Energy balance

Confinement time

Triple product

Inertial confinement

Non-thermal systems

See also

Table of contents (84 articles)

Index

Full contents

References

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Physics:Quantum Lawson criterion: Difference between revisions

Latest revision as of 11:34, 22 May 2026

Energy balance

Confinement time

Triple product

Inertial confinement

Non-thermal systems

See also

Table of contents (84 articles)

Index

Full contents

References

Navigation

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