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Gamma-ray laser

January 01, 1970

Not to be confused with gravity laser, also sometimes called a gaser or graser.
"Graser" redirects here. For other uses, see Graser (disambiguation).

A gamma-ray laser, or graser, is a hypothetical device that would produce coherent gamma rays, just as an ordinary laser produces coherent rays of visible light.[1] Potential applications for gamma-ray lasers include medical imaging, spacecraft propulsion, and cancer treatment.[2]

In his 2003 Nobel lecture, Vitaly Ginzburg cited the gamma-ray laser as one of the 30 most important problems in physics.[3]

The effort to construct a practical gamma-ray laser is interdisciplinary, encompassing quantum mechanics, nuclear and optical spectroscopy, chemistry, solid-state physics, and metallurgy—as well as the generation, moderation, and interaction of neutrons—and involves specialized knowledge and research in all these fields. The subject involves both basic science and engineering technology.[4]

Research edit

The problem of obtaining a sufficient concentration of resonant excited (isomeric) nuclear states for collective stimulated emission to occur turns on the broadening of the gamma-ray spectral line.[5] Of the two forms of broadening, homogeneous broadening is the result of the lifetime of the isomeric state: the shorter the lifetime, the more broadened the line.[6][7][8][9] Inhomogeneous broadening comprises all mechanisms by which the homogeneously broadened line is spread over the spectrum.[10]

The most familiar inhomogeneous broadening is Doppler recoil broadening from thermal motion of molecules in the solid containing the excited isomer and recoil from gamma-ray emission, in which the emission spectrum is both shifted and broadened. Isomers in solids can emit a sharp component superimposed on the Doppler-broadened background; this is called the Mössbauer effect.[11] This recoilless radiation exhibits a sharp line on top of the Doppler-broadened background that is only slightly shifted from the center of the background.[12][13][14][15][16]

With the inhomogeneous background removed, and a sharp line, it would seem that we have the conditions for gain.[17][18][19] But other difficulties that would degrade gain are unexcited states that would resonantly absorb the radiation, opaque impurities, and loss in propagation through the crystal in which the active nuclei are embedded.[20] Much of the latter can be overcome by clever matrix crystal alignment[21] to exploit the transparency provided by the Borrmann effect.[22][23][24]

Another difficulty, the graser dilemma, is that properties that should enable gain and those that would permit sufficient nuclear inversion density seem incompatible.[25][26] The time required to activate, separate, concentrate, and crystallize an appreciable number of excited nuclei by conventional radiochemistry is at least a few seconds. To ensure the inversion persists, the lifetime of the excited state must be considerably longer. Furthermore, the heating that would result from neutron-pumping the inversion in situ seems incompatible with maintaining the Mössbauer effect, although there are still avenues to explore.[citation needed]

Heating may be reduced by two-stage neutron-gamma pumping,[27] in which neutron capture occurs in a parent-doped converter, where it generates Mössbauer radiation that is then absorbed by ground-state nuclei in the graser.[28] Two-stage pumping of multiple levels offers multiple advantages.[29][30][clarification needed]

Another approach is to use nuclear transitions driven by collective electron oscillations.[31][32] The scheme would employ a triad of isomeric states: a long-lived storage state, in addition to an upper and lower lasing state. The storage state would be energetically close to the short-lived upper lasing state but separated by a forbidden transition involving one quantum unit of spin angular momentum. The graser would be enabled by a very intense optical laser to slosh the electron cloud back and forth and saturate the forbidden transition in the near field of the cloud. The population of the storage state would then be quickly equalized with the upper lasing state whose transition to the lower lasing state would be both spontaneous and stimulated by resonant gamma radiation. A "complete" chart of nuclides likely contains a very large number of isomeric states, and the existence of such a triad seems likely, but it has yet to be found.[21][33]

Nonlinearities can result in both spatial and temporal harmonics in the near field at the nucleus,[34][35] opening the range of possibilities for rapid transfer from the storage state to the upper lasing state using other kinds of triads involving transition energies at multiples of the optical laser quantum energy and at higher multipolarities.

See also edit

References edit

  1. ^ Baldwin, G. C. (1979). "Bibliography of GRASER research". Los Alamos Scientific Laboratory Report LA-7783-MS. doi:10.2172/6165356. OSTI 6165356.
  2. ^ Pittalwala, Iqbal (2019-12-05). "Gamma-ray laser moves a step closer to reality". University of California, Riverside. Retrieved 2022-11-27.
  3. ^ Ginzburg, V. L. (2003). "On superconductivity and superfluidity". The Nobel Prize in Physics 2003: 96–127.
  4. ^ Baldwin, G. C.; Solem, J. C.; Gol'danskii, V. I. (1981). "Approaches to the development of gamma-ray lasers". Reviews of Modern Physics. 53 (4): 687–744. Bibcode:1981RvMP...53..687B. doi:10.1103/revmodphys.53.687.
  5. ^ Baldwin, G. C.; Solem, J. C. (1979). "On the direct pumping of gamma-ray lasers by neutron capture". Nuclear Science & Engineering. 72 (3): 290–292. doi:10.13182/NSE79-A20385.
  6. ^ Vali, V.; Vali, W. (1963). "Induced gamma y-ray emission". Proceedings of the IEEE. 51 (1): 182–184. doi:10.1109/proc.1963.1677.
  7. ^ Letokhov, V. S. (1973). . Journal of Experimental and Theoretical Physics. 37 (5): 787–793. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  8. ^ Kamenov, P.; Bonchev, T. (1975). "On the possibility of realizing a gamma laser with long-living isomer nuclei". Bolgarskaia Akademiia Nauk, Doklady. 28 (9): 1175–1177. Bibcode:1975BlDok..28.1175K.
  9. ^ Il'inskii, Yu. A.; Khokhlov, R. V. (1976). "Possibility of creating a gamma-laser". Radiophysics and Quantum Electronics. 19 (6): 561–567. Bibcode:1976R&QE...19..561I. doi:10.1007/bf01043541. S2CID 120340405.
  10. ^ Baldwin, G. C. (1977). "On the Feasibility of Grasers". Laser Interaction and Related Plasma Phenomena. Vol. 4A. pp. 249–257. doi:10.1007/978-1-4684-8103-7_13. ISBN 978-1-4684-8105-1.
  11. ^ Andreev, A. V.; Il'inskii, Yu. A.; Khokhlov, R. V. (1977). . Journal of Experimental and Theoretical Physics. 46 (4): 682–684. Bibcode:1977JETP...46..682A. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  12. ^ Hien, P. Z. (1970). . Journal of Experimental and Theoretical Physics. 31 (1): 83–86. Bibcode:1970JETP...31...83Z. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  13. ^ Gol'danskii, V. I.; Kagan, Yu. M. (1973). "Feasibility of the nuclear-transition gamma laser (Graser)". Soviet Physics Uspekhi. 16 (4): 563–565. doi:10.1070/pu1974v016n04abeh005305.
  14. ^ Namiot, V. A. (1973). . JETP Letters. 18 (6): 369–373. Archived from the original on 2019-02-07. Retrieved 2016-02-24.
  15. ^ Andreev, A. V.; Il'inskii, Yu. A.; Khokhlov, R. V. (1974). . Journal of Experimental and Theoretical Physics. 40 (5): 819–820. Bibcode:1975JETP...40..819A. Archived from the original on 2016-09-27. Retrieved 2016-02-24.
  16. ^ Baldwin, G. C. (1979). "Time-domain spectroscopy of recoilless gamma rays". Nuclear Instruments and Methods. 159 (2–3): 309–330. Bibcode:1979NucIM.159..309B. doi:10.1016/0029-554x(79)90656-6.
  17. ^ Terhune, I. H.; Baldwin, G. C. (1965). "Nuclear superradiance in solids". Physical Review Letters. 14 (15): 589–591. Bibcode:1965PhRvL..14..589T. doi:10.1103/physrevlett.14.589.
  18. ^ Baldwin, G. C. (1974). "Is There a High Frequency Limit to Laser Action?". Laser Interaction and Related Plasma Phenomena. Vol. 3B. pp. 875–888. doi:10.1007/978-1-4684-8416-8_23. ISBN 978-1-4684-8418-2.
  19. ^ Andreev, A V.; Il'inskii, Yu. A. (1975). . Journal of Experimental and Theoretical Physics. 41 (3): 403–405. Bibcode:1975JETP...41..403A. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  20. ^ Il'inskii, Yu. A.; Khokhlov, R. V. (1974). "On the possibility of observation of stimulated gamma radiation". Soviet Physics Uspekhi. 16 (4): 565–567. doi:10.1070/pu1974v016n04abeh005306.
  21. ^ a b Baldwin, G. C.; Solem, J. C. (1997). "Recoilless gamma-ray lasers". Reviews of Modern Physics. 69 (4): 1085–1117. Bibcode:1997RvMP...69.1085B. doi:10.1103/revmodphys.69.1085.
  22. ^ Borrmann, G. (1941). "Über Extinktionsdiagramme der Röntgenstrahlen von Quarz". Physikalische Zeitschrift. 42: 157–162.
  23. ^ Kagan, Yu. M. (1974). . JETP Letters. 20 (1): 11–12. Archived from the original on 2016-09-06. Retrieved 2016-02-24.
  24. ^ Andreev, A. V.; Il'inskii, Yu. A. (1976). . Journal of Experimental and Theoretical Physics. 43 (5): 893–896. Bibcode:1976JETP...43..893A. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  25. ^ Baldwin, G. C.; Solem, J. C. (1979). "Maximum density and capture rates of neutrons moderated from a pulsed source". Nuclear Science & Engineering. 72 (3): 281–289. Bibcode:1979NSE....72..281B. doi:10.13182/NSE79-A20384.
  26. ^ Baldwin, G. C.; Solem, J. C. (1995). "Kinetics of neutron-burst pumped gamma-ray lasers". Laser Physics. 5 (2): 326–335.
  27. ^ Gol'danskii, V. I.; Kagan, Yu.; Namiot, V. A. (1973). . JETP Letters. 18 (1): 34–35. Archived from the original on 2016-03-06. Retrieved 2016-02-24.
  28. ^ Gol'danskii, V. I.; Kagan, Yu. (1973). . Journal of Experimental and Theoretical Physics. 37 (1): 49. Bibcode:1973JETP...37...49G. Archived from the original on 2016-03-11. Retrieved 2016-02-24.
  29. ^ Baldwin, G. C.; Solem, J. C. (1980). "Two-stage pumping of three-level Mössbauer gamma-ray lasers". Journal of Applied Physics. 51 (5): 2372–2380. Bibcode:1980JAP....51.2372B. doi:10.1063/1.328007.
  30. ^ Baldwin, G. C. (1984). "Multistep Pumping Schemes for Short-Wave Lasers". Laser Interaction and Related Plasma Phenomena. Vol. 6. pp. 107–125. doi:10.1007/978-1-4615-7332-6_8. ISBN 978-1-4615-7334-0.
  31. ^ Solem, J. C.; Biedenharn, L. C. (1987). "Primer on coupling collective electronic oscillations to nuclei" (PDF). Los Alamos National Laboratory Report LA-10878. Bibcode:1987pcce.rept.....S.
  32. ^ Biedeharn, L. C.; Baldwin, G. C.; Boer, K. (1986). Nuclear excitation by laser driven coherent outer shell electron oscillations. Proceedings of the First International Laser Science Conference, Dallas, TX, November 18–22, 1985. Stwalley, W. C.; Lapp, M.; Eds. Vol. 146. pp. 52–53. Bibcode:1986AIPC..146...52B. doi:10.1063/1.35933.
  33. ^ Solem, J. C.; Biedenharn, L. C.; Rinker, G. A. (1987). "Calculation of harmonic radiation from atoms subjected to strong laser fields and the possibility of nuclear excitation". Journal of the Optical Society of America A. 4: P53. Bibcode:1987JOSAA...4...53S.
  34. ^ Solem, J. C.; Biedenharn, L. C. (1988). "Laser coupling to nuclei via collective electronic oscillations: A simple heuristic model study". Journal of Quantitative Spectroscopy and Radiative Transfer. 40 (6): 707–712. Bibcode:1988JQSRT..40..707S. doi:10.1016/0022-4073(88)90066-0.
  35. ^ Solem, J. C. (1988). "Theorem relating spatial and temporal harmonics for nuclear interlevel transfer driven by collective electronic oscillation". Journal of Quantitative Spectroscopy and Radiative Transfer. 40 (6): 713–715. Bibcode:1988JQSRT..40..713S. doi:10.1016/0022-4073(88)90067-2.

Further reading edit

January 01, 1970
gamma, laser, confused, with, gravity, laser, also, sometimes, called, gaser, graser, graser, redirects, here, other, uses, graser, disambiguation, gamma, laser, graser, hypothetical, device, that, would, produce, coherent, gamma, rays, just, ordinary, laser, . Not to be confused with gravity laser also sometimes called a gaser or graser Graser redirects here For other uses see Graser disambiguation A gamma ray laser or graser is a hypothetical device that would produce coherent gamma rays just as an ordinary laser produces coherent rays of visible light 1 Potential applications for gamma ray lasers include medical imaging spacecraft propulsion and cancer treatment 2 In his 2003 Nobel lecture Vitaly Ginzburg cited the gamma ray laser as one of the 30 most important problems in physics 3 The effort to construct a practical gamma ray laser is interdisciplinary encompassing quantum mechanics nuclear and optical spectroscopy chemistry solid state physics and metallurgy as well as the generation moderation and interaction of neutrons and involves specialized knowledge and research in all these fields The subject involves both basic science and engineering technology 4 Contents 1 Research 2 See also 3 References 4 Further readingResearch editThe problem of obtaining a sufficient concentration of resonant excited isomeric nuclear states for collective stimulated emission to occur turns on the broadening of the gamma ray spectral line 5 Of the two forms of broadening homogeneous broadening is the result of the lifetime of the isomeric state the shorter the lifetime the more broadened the line 6 7 8 9 Inhomogeneous broadening comprises all mechanisms by which the homogeneously broadened line is spread over the spectrum 10 The most familiar inhomogeneous broadening is Doppler recoil broadening from thermal motion of molecules in the solid containing the excited isomer and recoil from gamma ray emission in which the emission spectrum is both shifted and broadened Isomers in solids can emit a sharp component superimposed on the Doppler broadened background this is called the Mossbauer effect 11 This recoilless radiation exhibits a sharp line on top of the Doppler broadened background that is only slightly shifted from the center of the background 12 13 14 15 16 With the inhomogeneous background removed and a sharp line it would seem that we have the conditions for gain 17 18 19 But other difficulties that would degrade gain are unexcited states that would resonantly absorb the radiation opaque impurities and loss in propagation through the crystal in which the active nuclei are embedded 20 Much of the latter can be overcome by clever matrix crystal alignment 21 to exploit the transparency provided by the Borrmann effect 22 23 24 Another difficulty the graser dilemma is that properties that should enable gain and those that would permit sufficient nuclear inversion density seem incompatible 25 26 The time required to activate separate concentrate and crystallize an appreciable number of excited nuclei by conventional radiochemistry is at least a few seconds To ensure the inversion persists the lifetime of the excited state must be considerably longer Furthermore the heating that would result from neutron pumping the inversion in situ seems incompatible with maintaining the Mossbauer effect although there are still avenues to explore citation needed Heating may be reduced by two stage neutron gamma pumping 27 in which neutron capture occurs in a parent doped converter where it generates Mossbauer radiation that is then absorbed by ground state nuclei in the graser 28 Two stage pumping of multiple levels offers multiple advantages 29 30 clarification needed Another approach is to use nuclear transitions driven by collective electron oscillations 31 32 The scheme would employ a triad of isomeric states a long lived storage state in addition to an upper and lower lasing state The storage state would be energetically close to the short lived upper lasing state but separated by a forbidden transition involving one quantum unit of spin angular momentum The graser would be enabled by a very intense optical laser to slosh the electron cloud back and forth and saturate the forbidden transition in the near field of the cloud The population of the storage state would then be quickly equalized with the upper lasing state whose transition to the lower lasing state would be both spontaneous and stimulated by resonant gamma radiation A complete chart of nuclides likely contains a very large number of isomeric states and the existence of such a triad seems likely but it has yet to be found 21 33 Nonlinearities can result in both spatial and temporal harmonics in the near field at the nucleus 34 35 opening the range of possibilities for rapid transfer from the storage state to the upper lasing state using other kinds of triads involving transition energies at multiples of the optical laser quantum energy and at higher multipolarities See also editParticle induced gamma emissionReferences edit Baldwin G C 1979 Bibliography of GRASER research Los Alamos Scientific Laboratory Report LA 7783 MS doi 10 2172 6165356 OSTI 6165356 Pittalwala Iqbal 2019 12 05 Gamma ray laser moves a step closer to reality University of California Riverside Retrieved 2022 11 27 Ginzburg V L 2003 On superconductivity and superfluidity The Nobel Prize in Physics 2003 96 127 Baldwin G C Solem J C Gol danskii V I 1981 Approaches to the development of gamma ray lasers Reviews of Modern Physics 53 4 687 744 Bibcode 1981RvMP 53 687B doi 10 1103 revmodphys 53 687 Baldwin G C Solem J C 1979 On the direct pumping of gamma ray lasers by neutron capture Nuclear Science amp Engineering 72 3 290 292 doi 10 13182 NSE79 A20385 Vali V Vali W 1963 Induced gamma y ray emission Proceedings of the IEEE 51 1 182 184 doi 10 1109 proc 1963 1677 Letokhov V S 1973 On the problem of the nuclear transition gamma laser Journal of Experimental and Theoretical Physics 37 5 787 793 Archived from the original on 2016 03 11 Retrieved 2016 02 24 Kamenov P Bonchev T 1975 On the possibility of realizing a gamma laser with long living isomer nuclei Bolgarskaia Akademiia Nauk Doklady 28 9 1175 1177 Bibcode 1975BlDok 28 1175K Il inskii Yu A Khokhlov R V 1976 Possibility of creating a gamma laser Radiophysics and Quantum Electronics 19 6 561 567 Bibcode 1976R amp QE 19 561I doi 10 1007 bf01043541 S2CID 120340405 Baldwin G C 1977 On the Feasibility of Grasers Laser Interaction and Related Plasma Phenomena Vol 4A pp 249 257 doi 10 1007 978 1 4684 8103 7 13 ISBN 978 1 4684 8105 1 Andreev A V Il inskii Yu A Khokhlov R V 1977 Role of collective and induced processes in the generation of Mossbauer gamma radiation Journal of Experimental and Theoretical Physics 46 4 682 684 Bibcode 1977JETP 46 682A Archived from the original on 2016 03 11 Retrieved 2016 02 24 Hien P Z 1970 Spontaneous emission of gamma quanta by a system containing identical nuclei Journal of Experimental and Theoretical Physics 31 1 83 86 Bibcode 1970JETP 31 83Z Archived from the original on 2016 03 11 Retrieved 2016 02 24 Gol danskii V I Kagan Yu M 1973 Feasibility of the nuclear transition gamma laser Graser Soviet Physics Uspekhi 16 4 563 565 doi 10 1070 pu1974v016n04abeh005305 Namiot V A 1973 Stimulated line narrowing and the Mossbauer effect for long lived isomers JETP Letters 18 6 369 373 Archived from the original on 2019 02 07 Retrieved 2016 02 24 Andreev A V Il inskii Yu A Khokhlov R V 1974 Narrowing of gamma resonance lines in crystals by continuous radio frequency fields Journal of Experimental and Theoretical Physics 40 5 819 820 Bibcode 1975JETP 40 819A Archived from the original on 2016 09 27 Retrieved 2016 02 24 Baldwin G C 1979 Time domain spectroscopy of recoilless gamma rays Nuclear Instruments and Methods 159 2 3 309 330 Bibcode 1979NucIM 159 309B doi 10 1016 0029 554x 79 90656 6 Terhune I H Baldwin G C 1965 Nuclear superradiance in solids Physical Review Letters 14 15 589 591 Bibcode 1965PhRvL 14 589T doi 10 1103 physrevlett 14 589 Baldwin G C 1974 Is There a High Frequency Limit to Laser Action Laser Interaction and Related Plasma Phenomena Vol 3B pp 875 888 doi 10 1007 978 1 4684 8416 8 23 ISBN 978 1 4684 8418 2 Andreev A V Il inskii Yu A 1975 Amplification in a gamma laser when the Bragg condition is satisfied Journal of Experimental and Theoretical Physics 41 3 403 405 Bibcode 1975JETP 41 403A Archived from the original on 2016 03 11 Retrieved 2016 02 24 Il inskii Yu A Khokhlov R V 1974 On the possibility of observation of stimulated gamma radiation Soviet Physics Uspekhi 16 4 565 567 doi 10 1070 pu1974v016n04abeh005306 a b Baldwin G C Solem J C 1997 Recoilless gamma ray lasers Reviews of Modern Physics 69 4 1085 1117 Bibcode 1997RvMP 69 1085B doi 10 1103 revmodphys 69 1085 Borrmann G 1941 Uber Extinktionsdiagramme der Rontgenstrahlen von Quarz Physikalische Zeitschrift 42 157 162 Kagan Yu M 1974 Use of the anomalous passage effect to obtain stimulated emission of gamma quanta in a crystal JETP Letters 20 1 11 12 Archived from the original on 2016 09 06 Retrieved 2016 02 24 Andreev A V Il inskii Yu A 1976 Possible use of the Borrmann effect in the gamma laser Journal of Experimental and Theoretical Physics 43 5 893 896 Bibcode 1976JETP 43 893A Archived from the original on 2016 03 11 Retrieved 2016 02 24 Baldwin G C Solem J C 1979 Maximum density and capture rates of neutrons moderated from a pulsed source Nuclear Science amp Engineering 72 3 281 289 Bibcode 1979NSE 72 281B doi 10 13182 NSE79 A20384 Baldwin G C Solem J C 1995 Kinetics of neutron burst pumped gamma ray lasers Laser Physics 5 2 326 335 Gol danskii V I Kagan Yu Namiot V A 1973 Two stage pumping of Mossbauer gamma ray lasers JETP Letters 18 1 34 35 Archived from the original on 2016 03 06 Retrieved 2016 02 24 Gol danskii V I Kagan Yu 1973 The possibility of creating a nuclear gamma laser Journal of Experimental and Theoretical Physics 37 1 49 Bibcode 1973JETP 37 49G Archived from the original on 2016 03 11 Retrieved 2016 02 24 Baldwin G C Solem J C 1980 Two stage pumping of three level Mossbauer gamma ray lasers Journal of Applied Physics 51 5 2372 2380 Bibcode 1980JAP 51 2372B doi 10 1063 1 328007 Baldwin G C 1984 Multistep Pumping Schemes for Short Wave Lasers Laser Interaction and Related Plasma Phenomena Vol 6 pp 107 125 doi 10 1007 978 1 4615 7332 6 8 ISBN 978 1 4615 7334 0 Solem J C Biedenharn L C 1987 Primer on coupling collective electronic oscillations to nuclei PDF Los Alamos National Laboratory Report LA 10878 Bibcode 1987pcce rept S Biedeharn L C Baldwin G C Boer K 1986 Nuclear excitation by laser driven coherent outer shell electron oscillations Proceedings of the First International Laser Science Conference Dallas TX November 18 22 1985 Stwalley W C Lapp M Eds Vol 146 pp 52 53 Bibcode 1986AIPC 146 52B doi 10 1063 1 35933 Solem J C Biedenharn L C Rinker G A 1987 Calculation of harmonic radiation from atoms subjected to strong laser fields and the possibility of nuclear excitation Journal of the Optical Society of America A 4 P53 Bibcode 1987JOSAA 4 53S Solem J C Biedenharn L C 1988 Laser coupling to nuclei via collective electronic oscillations A simple heuristic model study Journal of Quantitative Spectroscopy and Radiative Transfer 40 6 707 712 Bibcode 1988JQSRT 40 707S doi 10 1016 0022 4073 88 90066 0 Solem J C 1988 Theorem relating spatial and temporal harmonics for nuclear interlevel transfer driven by collective electronic oscillation Journal of Quantitative Spectroscopy and Radiative Transfer 40 6 713 715 Bibcode 1988JQSRT 40 713S doi 10 1016 0022 4073 88 90067 2 Further reading editBalko B Cohen L Sparrow D A eds 1989 Gamma Ray Lasers Pergamon ISBN 978 0 08 037015 6 http www sciencedirect com science book 9780080370156 Provides a definitive overview of the current status of gamma ray lasers Killus J 2006 The gamma laser Unintentional Irony A review for laymen Retrieved from https en wikipedia org w index php title Gamma ray laser amp oldid 1218171156, wikipedia, wiki, book, books, library,

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