Optical methods have two indisputable advantages: contact free and panoram- ic view. In other words, they do not affect the "object - air" system and in many cases make it possible to obtain data in the form of an image at once over the en- tire flow field or, for example, a flame front. Among the optical methods, one can single out the methods of visualizing the flow, which are no less important than measuring its parameters, because they give a visual representation of the general picture of the flow process in a certain medium or the propagation of the combus- tion front. It is clear that it is important to visualize the flows and fronts of chem- ical reactions in liquids or gases that arise spontaneously or under the influence of external sources initiated by various physical factors (ultrasound, laser radiation, magnetic and electric fields, etc.). In flows of liquids and gases, the fields of vel- ocities, pressure and temperature are usually visualized. Visualization of chemical processes in flow conditions by means of a variety of methods and means is used to establish their qualitative characteristics: observation of the optical spectrum of a chemical reaction, streamlines, boundary layer separation regions, vortices and shock waves, flow states (laminar or turbulent, stationary or unsteady, etc.). Visualization of the fronts of chemical reactions and flows is carried out by both non-optical and optical methods. Non-optical (direct) visualization of gas and li- quid flows includes: the method of introducing rags of smoke (for gas) or colored liquid (for hydrodynamic flows) into the flow, the method of tracing particles. It includes also the method of applying drops or films of a specific liquid (colored, with solid impurities or fluorescent), the use of a thin light sheet (laser sheet) to illuminate particles, etc. Optical methods make it possible to visualize flows using optical instruments and installations. These methods provide visualization of in- homogeneous flows of reacting gas and liquid, qualitative analysis of the state and structure of the flow, non-contact and inertialess measurement simultaneously within the entire visualized section of the flow of the flux density. The first experiments with chronophotography, which made it possible to re- cord the movement of an object by photographing its individual phases at short equal intervals of time, and which became the prototype of cinema, were carried out for the same purposes. They allowed studying the imperceptible phenomena. Modern equipment allows you to shoot from several thousand to tens of millions of frames per second, making it possible to observe very fast processes. High- speed digital devices are used to analyze many fast-moving phenomena, in par- ticular, to analyze the processes of flame propagation, transition of combustion to detonation, spark discharges and other phenomena. The frames obtained in laboratory conditions make it possible to measure the parameters of the medium flows, the velocity and structure of the combustion fronts, and ultimately present the visualization results in a form that is convenient for understanding and modeling. Modern electronic recording devices, as a rule, do not contain moving parts that limit performance. CCD-matrices allow registering fast processes with a fre - quency of up to 1000 frames per second. The CMOS sensors made it possible to shoot millions of frames per second and completely replace cine film. The speed level reached at the beginning of the decade at 0.6 trillion frames per second made it possible to record the movement of the light front of a pulsed laser. Even some digital compact cameras, such as the Casio Exilim series, are equipped with high- speed video recording at up to 1200 frames per second at reduced frame sizes. For accelerated filming, special digital cinema cameras are used, the most famous of which are Phantom devices capable of shooting up to a million frames per second, infrared video cameras (for example, Xeva-2.35-320) are already capable of re- cording radiation with an acceptable resolution of up to 400 frames per second. At present, along with the above visualization methods, remote sensing meth- ods for studying various processes using the latest optoelectronic devices are becoming more and more widespread. This book focuses on the use of hyper - spectrometers, the domestic line of which is being intensively developed, unique UV-C sensors, as well as the combined use of hyperspectrometers and high-speed color filming. Hyperspectrometers are devices that allow remote registration of reflected, scattered and upward radiation to obtain its spectrum in a wide range of wavelengths. Measurements in the range from several hundred to a thousand spec- tral channels are called hyperspectral, and a hyperspectral image sensor is a device that simultaneously measures spectral and spatial coordinates. This book exam - ines domestic lines of hyperspectrometers, which at one point in time register a narrow band of emitting, reflecting or scattering radiation surface (the so-called push broom systems). Registration is carried out on a two-dimensional matrix, along one coordinate of which the spatial coordinate x is fixed (along a narrow strip of the recorded surface), and along the other - the spectral one. As a rule, the third coordinate y is formed due to the movement of the hyperspectrometer by some kind of carrier (airplane, helicopter, car, satellite), or this movement is carried out using a rotary device. In addition to the two standard coordinates x and y, the spectral coordinate and the intensity of the spectral line are added, which provides a 4D dimension of the data space. If the hyperspectrometer is in the state of rest, then since the data is read from the recording device of the hyperspectrom- eter in frames accumulated on the recording device for a certain time, in this case (instead of the y coordinate) the t-time coordinate appears. It becomes possible to study the temporal characteristics of the processes occurring on a narrow strip of the surface, i.e. the 4D dimension is formed by the x coordinate, the spectral coordinate - by the wavelength λ, the intensity of the spectral line I and the time t. In the first Chapter of this book, methods and means of remote shooting in the optical range are considered. The advantages of using multispectral multisen- sory imaging, which significantly increase the efficiency of remote analysis of both images and combustion and explosion processes, are demonstrated. In the second Chapter, optoelectronic devices are considered, such as the domestic line of hyperspectral sensors of the optical range and the UV-C sensor, developed and created at "RDC "Reagent", JSC. The following Chapters are devoted to the re - sults of studying combustion and explosion processes, including the help of op- toelectronic devices. In the third Chapter, a study of instabilities arising from the propagation of hydrogen and hydrocarbon flames by the method of high-speed filming is carried out. The regimes of flame propagation during combustion of lean hydrogen-air mixtures in the presence of additives under conditions of central initiation by the method of high-speed filming are considered. The onset of acous- tic instability in hydrogen-air mixtures in a closed reactor with central initiation by a spark discharge is analyzed. The regularities of the interaction of spherical flames of hydrogen-air and methane-air mixtures with fine-mesh obstacles at cen- tral initiation by a spark discharge have been established. The features of thermal ignition in gas vortices are investigated. The fourth Chapter presents the results of studying the patterns of propagation of an unstable flame front using optical 4D spectroscopy and color high-speed filming. The fifth Chapter describes the use of a high-speed optical multidimensional technique to establish the characteristics of ignition and combustion of 40% H2 - air mixture in the presence of platinum metal. In the sixth Chapter, 4D spectroscopy and high-speed filming are used to establish the gasdynamic and kinetic features of the penetration of methane-oxy- gen flames through obstacles. The gasdynamic and kinetic features of the penetra- tion of a methane-oxygen flame through single holes and fine-mesh obstacles have been investigated. The regularities of the penetration of flames of dilute mixtures of methane with oxygen through a single hole in a flat obstacle, diffuser, confuser and combined obstacles have been established. The factors determining the length of the flame jump after penetration through a small hole are revealed. The spectral features of the emission of methane-oxygen flames under the conditions of pene- tration through obstacles have been established. The seventh Chapter describes the establishment of the basic features of com- bustion of mixtures of hydrogen-air and hydrogen-hydrocarbon (C 1 - C 6) -air above the surface of palladium metal with the combined use of a hyperspectral sensor and high-speed color filming. The combustion of mixtures hydrogen-air and hydrogen-methane-air over the palladium surface, the ignition of mixtures hydrogen - hydrocarbon (C 1-C6) - air over the palladium surface at pressures of 1÷2 atm is investigated. Regularities are established and numerical simulation of the ignition of hydrogen-oxygen and hydrogen-methane-oxygen mixtures by heated wires at low pressure is carried out. The eighth Chapter is devoted to the establishment of the laws governing the combustion of copper, tungsten and iron nanopowders and compacted samples of iron nanopowders by the methods of vis- ible and infrared filming.

1. Vision system overview, C&PS Flight Technical Services, 2013. https://www.mygdc.com/ assets / public_files / gdc_services / pilot_services / presentations / Vision_Systems_Overview.pdf

2. Rodionov I. D., Rodionov A. I., Vedeshin L. A., Vinogradov A. N., Yegorov V.V.,. Kalinin A.P. Aviation hyperspectral complexes for solving problems of remote sensing, Earth exploration from space. 2013. No. 6. P. 81-93.

3. Kalinin A. P., Orlov A. G., Rodionov A. I. Troshin K. Ya. Demonstration of the possibility of studying combustion and explosion processes using remote hyperspectral sensing, Physical-chemical kinetics in gas dynamics. 2009. Volume 8. 12 p. http://www.chemphys.edu.ru/pdf/2009-06-18-001.pdf

4. Kalinin A. P., Troshin K. Ya. Orlov A. G. Rodionov A. I. Hyperspectrometer as a system for monitoring and studying combustion and explosion processes, Sensors and Systems, 2008, No. 12, pp.19-21.

5. RF patent. Vinogradov A. N., Kalinin A. P., Rodionov I. D., Rodionov A. I., Rodionova I. P., Rubtsov N. M., Chernysh V. I., Tsvetkov G. I., Troshin K.Ya. Device for remote study of combustion and explosion processes using hyperspectrometry and high-speed photography, Utility model. Patent No. 158856 dated July 22, 2015 Published on January 20, 2016 Bull. No. 2.

6. Belov A. A., Egorov V. V., Kalinin A. P., Korovin, Rodionov A. I., Rodionov I. D., Stepanov S. N. Ultraviolet Monophoton Sensor "Korona" Automation and Remote Control, 2014, Vol. 75, No. 12, pp. 345-349, Pleiades Publishing, Ltd., 2014. (ISSN 0005-1179).

7. Ishimaru A. Wave Propagation and Scattering in Random Media. M.: Mir. 1980. Vol. 1. 280 p.

8. Nepobedimy S. P., Rodionov I. D., Vorontsov D. V., Orlov A. G., Kalashnikov S. K., Kalinin A. P., Ovchinnikov M. Yu., Rodionov A. I., Shilov I. B., Lyubimov V. N., Osipov A. F. Hyperspectral Earth Remote Sensing, Reports of the Academy of Sciences. 2004. Vol. 397. No. 1. P. 45-48.

9. Rodionov I. D., Rodionov A. I., Vedeshin L. A., Vinogradov A. N., Yegorov V. V., Kalinin A. P. Aviation hyperspectral complexes for solving problems of remote sensing, Earth exploration from space. 2013. No. 6. P. 81-93.

10. Yegorov V. V., Kalinin A. P., Rodionov I. D., Rodionova I. P., Orlov A. G. Hyperspectrometer - as an element of an intelligent technical vision system, Sensors and systems. 2007. No. 8, P. 33-35.

11. Vinogradov A. N., Yegorov V. V., Kalinin A. P., Rodionov A. I., Rodionov I. D. Onboard hyperspectrometer of visible and near infrared range with high spatial resolution. Contemporary problems of telecommuting. Sensing the Earth from space. 2012. Vol. 8. Number 2. P. 101-107.

12. E.L.Akim, P.Behr, K.Bries, V.V.Egorov, E.Yu.Fedunin, A.P.Kalinin, S.K.Kalashnikov, K.-H. Kolk, S.Montenegro, A.I.Rodionov, I.D.Rodionov, M.Yu.Ovchinnikov, A.G.Orlov, S.Pletner, B.R.Shub, L.A.Vedeshin, D.V.Vorontsov, THE FIRE INFRARED-HYPERSPECTRAL MONITORING (Russian – Germany Proposals for an International Earth Observation Mission), Preprint of the Keldysh Institute of Applied Mathematics, Russian Academy of Sciences. № 32, 36 pp, Moscow, 2004.

13. Belov A. A., Yegorov V. V., Kalinin A. P., Korovin N. A., Rodionov A. I., Rodionov I. D., Stepanov S. N. Ultraviolet monophotonic sensor “Corona”. Sensors and systems. No. 12. 2012. P. 58-60.

14. Belov A. A., Yegorov V. V., Kalinin A. P., Korovin, Rodionov A. I., Rodionov I. D., Stepanov S. N. Ultraviolet monophotonic sensor “Corona” Automation and Remote Control, 2014, Vol. 75, No. 12, pp. 345-349.

15. Belov A. A., Yegorov V. V., Kalinin A.P., Krysiuk I. V., Osipov A. F., Rodionov A. I., Rodionov I. D., Stepanov S. N. Universal ultraviolet monophotonic sensor. Preprint IPMech RAS, No. 935, 48p, 2010.

16. Belov A. A., Yegorov V. V., Kalinin A. P., Korovin N. A., Rodionov I.D., Stepanov S. N. Application of the monophotonic sensor "Corona" for remote monitoring of the state of high-voltage equipment Chief Power Engineer No. 6 2012 p. 12-17.

17. Belov A. A., A.N. Vinogradov, Yegorov V. V., Zavalishin O. I., Kalinin A. P., Korovin N. A., Rodionov A. I., Rodionov I. D., Possibilities of using position-sensitive monophotonic UV sensors for aircraft navigation in the airfield area, Sensors and systems. 2014. No. 1. 37-42.

18. Ronney, P. D., “Premixed-Gas Flames,” in: Microgravity Combustion: Fires in Free Fall (H. Ross, Ed.), Academic Press, London, U.K., 2001, pp. 35-82.

19. F.A. Williams , J.F.Grcar, A hypothetical burning-velocity formula for very lean hydrogen–air mixtures , Proc. of the Combustion Institute. 2009. V. 32. №1. P.1351 -1360.

20. Nonsteady flame propagation, ed. by George H.Markstein, Perg.Press, Oxford, London, 1964.

21. Ya.B. Zeldovich, Selected Works. Chemical Physics and Hydrodynamics, p/r ak. Yu.A. Khariton, M :; Publishing house "Nauka", 1984, 379 pp.

22. Z. Chen and Y. Ju, Theoretical analysis of the evolution from ignition kernel to flame ball and planar flame, Combustion Theory and Modelling, Vol. 11, No. 3, R. 427–453.

23. H. F. Coward and F. Brinsley, Influence of additives on flames, J. Chem. Soc. 105 (1914) 1859-1866.

24. P.D.Ronney, Near-limit flame structures at low Lewis number, Comb, and Flame, 1990,V.82,P.1-14.

25. Ya.B. Zeldovich, N. P. Drozdov, Diffusion phenomena at the limits of flame propagation, Journal of Physical Chemistry, 1943, Vol. 17, issue 3, pp. 134-144.

26. N.M.Rubtsov, B.S.Seplyarsky, G.I.Tsvetkov, V.I.Chernysh, Numerical investigation of the effects of surface recombination and initiation for laminar hydrogen flames at atmospheric pressure , Mendeleev Communications, 2008, V.18, P.220-222.

27. Rubtsov N.M., Seplyarsky B.S., Troshin K.Ya., Chernysh V.I., Tsvetkov G.I., Features of the propagation of laminar spherical flames initiated by a spark discharge in mixtures of methane, pentane and hydrogen with air at atmospheric pressure // Journal of Physical Chemistry, 2011, Vol. 85, issue 10, pp. 1834-1844.

28. Rubtsov N.M., Kotelkin V.D. Seplyarskii B.S., Tsvetkov G.I.,Chernysh V.I. Investigation into the combustion of lean hydrogen–air mixtures at atmospheric pressure by means of high-speed cinematography, Mendeleev Communications, 2011, V.21, N5,p. 215-217.

29. B. Lewis, G. Von Elbe, Combustion, Explosions and Flame in Gases, New York, London.: Acad.Press, 1987, P.566.

30. Dahoe A.E. Laminar burning velocities of hydrogen–air mixtures from closed vessel gas explosions, Journal of Loss Prevention in the Process Industries. 2005. V.18. P.152-169.

31. Rubtsov N. M., Kotelkin V. D., Seplyarskiy B. S., Tsvetkov G. I., Chernysh V. I. Chemical physics and mesoscopy, V.13, issue 3, pp. 331-339.

32. G. Backstrom, Simple Fields of Physics by Finite Element Analysis (Paperback), GB Publishing (2005), P 324.

33. V. Polezhaev, S. Nikitin, Thermoacoustics and heat transfer in an enclosure induced by a wall heating, 16th International Congress on Sound and Vibration, Kraków, Poland, 5–9 July 2009, p.2-8

34. Rayleigh J.W. On convection currents in a horizontal layer of fluid, when the higher temperature is on the under side, Phil. Mag., 1916. V. 32. P. 529-546.

35. N. M. Rubtsov, V. V. Azatyan, D. I. Baklanov, G. I.Tsvetkov, V. I. Chernysh, The effect of chemically active additives on the detonation wave velocity and detonation limits in poor fuel mixtures, Theoretical foundations of Chemical Technology, 2007, Vol. 41, issue 2, 166-175.

36. T.C. Lieuwen. Experimental investigation of limit-cycle oscillations, Journal of Propulsion and Power, 2002, V.18, P.61-67.

37. Larionov V. M., Zaripov R. G. Gas self-oscillations in combustion installations. Kazan: Publishing House of Kazan State Tech. Univer., 2003. 227 p.

38. Kampen, J. F. van, Acoustic pressure oscillations induced by confined turbulent premixed natural gas flames, PhD thesis, University of Twente, Enschede, The Netherlands, March 2006, ISBN 90-365-2277-3, Printed by Febodruk BV, Enschede, The Netherlands.

39. Williams, F. A. (1985) Combustion Theory. 2nd Ed., The Benjamin/Cummings Pub. Co., Menlo Park, Ca.

40. Ya. B. Zeldovich, G. A. Barenblatt, D.V. Makhviladze, A.B. Librovich, Mathematical theory of flame propagation, Moscow, Publishing house of the AS of the USSR, 1980, 620 pp.

41. Zeldovich Ya. B., Structure and stability of a stationary laminar flame at moderately high Reynolds numbers, Chernogolovka: Publishing house of the AS of the USSR, Preprint OIKhF, 1979, 36 pp.

42. Nickolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya.Troshin, Victor I.Chrenysh, Georgii I.Tsvetkov, Initiation and propagation of laminar spherical flames at atmospheric pressure, Mendeleev Comm., 2011, Vol. 21, P.218-221.

43. J. W. S. Rayleigh, The theory of sound. New York: Dover, 1945.

44. Putnam A.A., Dennis W.R. Organ-pipe oscillations in a burner with deep ports, JASA. 1956. Vol.28. R.260-268.

45. Al-Shahrany, AS, Bradley, D., Lawes, M., Liu, K. and Woolley, R., Darrieus-Landau and thermo-acoustic instabilities in closed vessel explosions, Combustion Science and Technology, 2006, V. 178, N10, P. 1771 -1802.

46. Maxwell, G.B. and Wheeler, R.V., Some flame characteristics of motor fuels, Ind. Eng. Chem., 1928, V. 20, 1041-1044.

47. Megalchi, M. and Keck, J.C., Burning velocities of mixtures of air with methanol, isooctane and indolene at high pressure and temperature, Combust. Flame, 1982, V. 48, P. 191-210.

48. Clanet, C., Searby, G., (1998), First experimental study of the Darrieus-Landau instability. Phys. Rev. Lett., 27, 3867-3870.

49. Clavin, P. Premixed combustion and gasdynamics. Ann. Rev. Fluid Mech. 1994, 26, 321-352.25. Nickolai M.Rubtsov, Boris S.Seplyarskii, Kirill Ya.Troshin, Victor I.Chrenysh, Georgii I.Tsvetkov, Initiation and propagation of laminar spherical flames at atmospheric pressure, Mendeleev Comm., 2011, T.21, P.218-221.

50. J. W. S. Rayleigh, The theory of sound. New York: Dover, 1945.

51. Putnam A.A., Dennis W.R. Organ-pipe oscillations in a burner with deep ports, JASA. 1956. Vol.28. R.260-268.

52. Al-Shahrany, A. S. , Bradley, D. , Lawes, M. , Liu, K. and Woolley, R., Darrieus-Landau and thermo-acoustic instabilities in closed vessel explosions, Combustion Science and Technology, 2006, V.178, N10, P.1771 -1802.

53. Maxwell, G.B. and Wheeler, R.V., Some flame characteristics of motor fuels, Ind. Eng. Chem., 1928, V.20, 1041–1044.

54. Megalchi, M. and Keck, J.C., Burning velocities of mixtures of air with methanol, isooctane and indolene at high pressure and temperature, Combust. Flame, 1982, V.48, P.191–210.

55. Clanet, C. , Searby, G., (1998), First experimental study of the Darrieus-Landau instability. Phys. Rev. Lett., 27, 3867-3870.

56. Clavin, P. Premixed combustion and gasdynamics. Ann. Rev. Fluid Mech. 1994, 26, 321-352.

57. I. P. Solovyanova, I. S. Shabunin, Theory of wave processes. Acoustic waves, Yekaterinburg: SEI HVE USTU-UPI, ISBN 5-321-00398 X, 2004. P. 142

58. Teodorczyk Α., Lee J.H.S., Knystautas R.: The Structure of Fast Turbulent Flames in Very Rough, Obstacle-Filled Channels. Twenty-Third Symposium (Int.) on Combustion, The Combustion Institute 1990, pp. 735-741.

59. Gorev V. A. , Miroshnikov S. N., Accelerating combustion in gas volumes, Chem. Physics, 1982, No. 6, pp. 854-858.

60. Moen I.O., Donato Μ., Knystautas R., Lee J.H. and Wagner H.G.: Turbulent Flame Propagation and Acceleration in the Presence of Obstacles, Gasdynamics of Detonations and Explosions. Progress in Astronautics and Aeronautics. 1981, No. 75, pp. 33-47.

61. Wagner H.G.: Some Experiments about Flame Acceleration. Proc. International Conference on Fuel-Air Explosions. SM Study 16, University of Waterloo Press, Montreal 1981, pp.77-99.

62. Nikolayev Yu.A., Topchiyan M. E. Calculation of equilibrium flows in detonation waves in gases, Physics of Combustion and Explosion, 1977, Vol. 13b No. 3, pp. 393-404.

63. A. S. Sokolik, Self-ignition, flame and detonation in gases. M: Publishing house of the AS of the USSR, 1960, 470 pp.

64. Fischer V., Pantow E. and Kratzel T., Propagation, decay and re-ignition of detonations in technical structures , in “Gaseous and heterogeneous detonations:Science to applications”, Moscow: ENASH Publishers,1999, P. 197.

65. Rubtsov N. M., Tsvetkov G. I., Chernysh V.I. Different nature of the action of small active additives on the ignition of hydrogen and methane. Kinetics and catalysis. 2007. Vol. 49. No. 3. P. 363.

66. N. M. Rubtsov, B.S. Seplyarsky, G. I. Tsvetkov, V. I. Chernysh, Influence of vapors of organometallic compounds on the processes of ignition and combustion of hydrogen, propylene and natural gas, Theoretical Foundations of Chemical Technology, 2009, Vol. 43, No. 2, pp. 187–193

67. J.H.S. Lee, R. Knystautas and C.K. Chan, Turbulent Flame Propagation in Obstacle-Filled Tubes, in 20th Symposium (International) on Combustion, The Combustion Institute, 1985, P. 1663.

68. C.K. Chan, J.H.S. Lee, I.O. Moen and P. Thibault, Turbulent Flame Acceleration and Pressure Development in Tubes, In Proc. of the First Specialist Meeting (International) of the Combustion Institute, Bordeaux, France, 1981, P.479.

69. C.J.M. Van Wingerden and J.P. Zeeuwen, Investigation of the Explosion-Enhancing Properties of a Pipe-Rack-Like Obstacle Array, Progress in Astronautics and Aeronautics 1986, V.106, P.53.

70. J.C. Cummings, J.R. Torczynski and W.B. Benedick, Flame Acceleration in Mixtures of Hydrogen and Air, Sandia National Laboratory Report, SAND-86-O173, 1987.

71. W. Breitung, C. Chan, S. Dorofeev. A. Eder, B. Gelfand, M. Heitsch, R. Klein, A. Malliakos, E. Shepherd, E. Studer, P. Thibault, State-of-the-Art Report On Flame Acceleration And Deflagration-to-Detonation Transition In Nuclear Safety, Nuclear Safety NEA/CSNI/R 2000, OECD Nuclear Energy Agency, http://www.nea.fr.

72. Nickolai M. Rubtsov, The Modes of Gaseous Combustion, Springer International Publishing Switzerland 2016, 294 P.

73. Poinsot, T. and D. Veynante. Theoretical and Numerical Combustion, 2001, RT Edwards, Flourtown, PA.

74. Zeldovich, Y.B.: Selected Works. Chemical Physics and Hydrodynamics. Nauka, Moscow, 1980, (in Russian).

75. Laurent Joly P. Chassaing, V. Chapin, J.N. Reinaud, J. Micallef, J. Suarez, L. Bretonnet, J. Fontane, Baroclinic Instabilities, ENSICA - Département de Mécanique des Fluides, Variable Density Turbulent Flows – Villanova i la Geltru – 2003, oatao.univ-toulouse.fr›2366/.

76. S. B. Pope, Turbulemt premixed Flames, Ann. Rev. Fluid Mech., 1987, V. 19, P. 237.

77. Bray K.N.C. Turbulent flows with premixed reactants. In P.A. Libby and F.A. Williams, editors, Turbulent Reacting Flows, volume 44 of Topics in Applied Physics, chapter 4, pages 115–183. Springer Verlag, 1980.

78. A. A. Borisov, V. A. Smetanyuk, K. Ya. Troshin, and I.O. Shamshin, Self-ignition in gas vortices, Gorenie i vzryv (Moskva) – Combustion and explosion, 2016, V. 9 no. 1, P.219 (in Russian).

79. Khalil, A.E.E., and Gupta, A.K., Fuel Flexible Distributed Combustion With Swirl For Gas Turbine Applications, Applied Energy, 2013, V. 109, P. 2749.

80. Khalil, A.E.E., and Gupta, A.K., Swirling Flowfield for Colorless Distributed Combustion, Applied Energy, 2014, V. 113, P. 208.

81. Margolin,A.D., and V. P.Karpov. Combustion of rotating gas, Dokl. AN USSR, 1974, V.216, P.346.

82. Babkin, V. S., A.M. Badalyan, A. V. Borisenko, and V. V. Zamashchikov. Flame extinction in rotating gas, Combust. Explo. Shock Waves, 1982, V.18, P.272.

83. Ishizuka, S. Flame propagation along a vortex axis, 2002, Prog. Energ. Combust. Sci.,V. 28, P.477.

84. Zel’dovich, Ya.B., B. E. Gelfand, S.A. Tsyganov, S.M. Frolov, and A.N. Polenov. Concentration and temperature nonuniformities of combustible mixtures as reason for pressure waves generation. Dynamics of explosions. Eds. A. Borisov, A. L. Kuhl, J.R. Bowen, and J.-C. Leyer, 1988, Progress in astronautics and aeronautics ser. Washington, D.C., AIAA, V. 114, P.99.

85. K. Ya. Troshin, I. O. Shamshin, V. A. Smetanyuk, A. A. Borisov, Self-ignition and combustion of gas mixtures in a volume with a eddy flow, Chemical Physics, 2017, V. 36, No. 11, p. 1-12.

86. Borisov, A. A., N. M. Rubtsov, G. I. Skachkov, and K. Ya. Troshin. 2012. Gas-phase spontaneous ignition of hydrocarbons. Russ. J. Phys. Chem. B, V.6, P. 517.

87. Nonsteady flame propagation, ed. by George H.Markstein, Perg.Press, Oxford, London, 1964.

88. Landau L., On the theory of slow combustion. Acta Phys.-Chim. URSS, 1944, 19, 77-85.

89. F.A. Williams, J.F.Grcar, A hypothetical burning-velocity formula for very lean hydrogen–air mixtures, Proc. of the Combustion Institute. 2009. V. 32. №1. P.1351 -1360.

90. Ya.B. Zeldovich, Selected Works. Chemical Physics and Hydrodynamics, p/r ak. Yu .A. Khariton, M:; Publishing house "Nauka", 1984, 379 P.

91. B. Lewis, G. Von Elbe, Combustion, Explosions and Flame in Gases, New York, London: Acad.Press, 1987, P.566.

92. Sivashinsky, G.I., Nonlinear analysis of hydrodynamic instability in laminar flames-I. Derivation of basic equations,Acta Astronaut., 1977, 4. 1177-1206.

93. Clavin, P.,Williams, F.A., Effects of molecular diffusion and of thermal expansion on the structure and dynamics of premixed flames in turbulent flows of large scale and low intensity // J. Fluid Mech., 1982, 116, P. 251-282.

94. Pelcé, P. , Clavin, P. Influence of hydrodynamics and diffusion upon the stability limits of laminar premixed flame. J. Fluid Mech. 1982. 124, 219-237.

95. Kampen, J. F. van, Acoustic pressure oscillations induced by confined turbulent premixed natural gas flames, PhD thesis, University of Twente, Enschede, The Netherlands, March 2006, ISBN 90-365-2277-3, Printed by Febodruk BV, Enschede, The Netherlands.

96. Ronney, P. D., “Premixed-Gas Flames,” in: Microgravity Combustion: Fires in Free Fall (H. Ross, Ed.), Academic Press, London, U.K., 2001, pp. 35-82

97. Clanet, C., Searby, G., (1998), First experimental study of the Darrieus-Landau instability. Phys. Rev. Lett., 27, 3867-3870.

98. Ya.B. Zeldovich, G. A. Barenblatt, D.V. Makhviladze, A. B. Librovich, Mathematical theory of flame propagation, M., Publishing House of AS of USSR, 1980, 620 P.

99. Kalinin A. P., Orlov A. G., Rodionov A. I., Troshin K.Ya., Demonstration of the possibility of studying combustion and explosion processes using remote hyperspectral sensing, Physicochemical kinetics in gas dynamics, www.chemphys .edu.ru / pdf / 2009-06-18-001.pdf

100. Vinogradov A. N., Yegorov V. V., Kalinin A. P., Melnikova E. M., Rodionov A. I., Rodionov I. D. Line of hyperspectral sensors of the optical range: Preprint of SRI of RAS Pr-2176, 2015.16 p.

101. Yegorov V. V., Kalinin A. P., Rodionov I. D., Rodionova I. P., Orlov A. G., Hyperspectrometer as an element of an intelligent technical vision system // Sensors and Systems, 2007, No. 8, pp. 33-35

102. Thomas Alasard, Low Mach number limit of the full Navier-Stokes equations, Archive for Rational Mechanics and Analysis 180 (2006), no. 1, 1-73.

103. F. Nicoud, Conservative High-Order Finite-Difference Schemes for Low-Mach Number Flows, Journal of Computational Physics 2000, 158, 71.

104. Williams, F. A. (1985) Combustion Theory. 2nd Ed., The Benjamin/Cummings Pub. Co., Menlo Park, Ca., 450 P.

105. V.Akkerman, V.Bychkov, A.Petchenko, L.-E. Eriksson, Flame oscillations in tubes with nonslip at the walls, Combustion and Flame, 2006, V.145. P.675-687.

106. A.Majda, Compressible fluid flow and systems of conservation laws in several space variables, Applied Mathematical Sciences, vol. 53, Springer-Verlag, New York, 1984.

107. D. I. Abugov, V. M. Bobylev, Theory and calculation of solid propellant rocket engines, M:; Mechanical engineering, 1987, 271 P.

108. Clavin, P. Premixed combustion and gasdynamics. Ann. Rev. Fluid Mech. 1994, 26, 321-352.

109. G. Backstrom, Simple Fields of Physics by Finite Element Analysis (Paperback), GB Publishing (2005), 324 P.

110. Pierse, R., Gaydon, A., The identification of molecular spectra, 1941, N.-Y., London, Acad. Press, 240 p.

111. T. Icitaga, Emission spectrum of the oxy-hydrogen flame and its reaction mechanism. (1) Formation of the Activated Water Molecule in Higher Vibrational States. The Review of Physical Chemistry of Japan Vol. 13f, No. 2 (1939), P. 96-107.

112. L. S. Rothman, I. E. Gordon, Y. Babikov, A. Barbe, D. Chris Benner etc ,"The HITRAN 2012 Molecular Spectroscopic Database," Journal of Quantitative Spectroscopy & Radiative Transfer, 130, 4-50 (2013).

113. P.-F. Coheur, P.F. Bernath, M. Carleer and R. Colin, et al. A 3000 K laboratory emission spectrum of water, The Journal of Chemical Physics, 122, 074307, 2005.

114. Herzberg G. Molecular Spectra and Molecular Structure, Vol. 1, Spectra of Diatomic Molecules. 2nd ed. Van Nostrand. New York. 1950.

115. C. Appel, J. Mantsaras, R. Schaeren, R. Bombach, and A. Inauen, Catalytic combustion of hydrogen – air mixtures over platinum: validation of hetero-homogeneous reaction schemes, 2004, Clean Air, 5, 21–44.

116. J. C. Chaston, Reaction of Oxygen with the Platinum Metals. The oxidation of platinum, Platinum Metals Rev., 1964, 8, (2), 50-54

117. Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Victor I. Chernysh and Georgii I. Tsvetkov, Investigation into spontaneous ignition of hydrogen–air mixtures in a heated reactor at atmospheric pressure by high-speed cinematography, Mendeleev Commun., 2012, 22, 222-224.

118. Perry, D. L. (1995). Handbook of Inorganic Compounds. CRC Press. pp. 296–298. ISBN 0-8493-8671-3.

119. Lagowski, J. J., ed. (2004). Chemistry Foundations and Applications 3. Thomson Gale. pp. 267–268. ISBN 0-02-865724-1.

120. Ya. B. Zel’dovich, G. I. Barenblatt, V. B. Librovich and G. M. Machviladze, Matematicheskaya teoriya goreniya i vzryva (Mathematical Theory of Combustion and Explosion), Nauka, Moscow, 1980 (in Russian).

121. A.A. Borisov, N.M. Rubtsov, G.I. Skachkov, K.Ya. Troshin, Gas Phase Spontaneous Ignition of Hydrocarbons, 2012, Khimicheskaya Fizika, 2012, 31, N8, 30–36. [Engl.transl. Russian Journal of Physical Chemistry B, 2012, 6, 517].

122. A. A. Borisov, V. G. Knorre, E. L. Kudrjashova and K.Ya. Troshin, Khim.Fiz., 1998, 17, 80 [Chem. Phys. Rep. (Engl. Transl.), 1998, 17, 105].

123. Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Georgii I. Tsvetkov and Victor I. Chernysh, High-speed colour cinematography of the spontaneous ignition of propane–air and n-pentane–air mixtures, Mendeleev Commun., 2011, 21, 31-33.

124. Ahmed E.E.Khalil and Ashwani K.Gupta, Dual Injection distributed Combustion for Gas Turbine application, J.Energy Resources Technol, 2013, 136, 011601.

125. Ahmed E.E.Khalil, Ashwani K.Gupta, Kenneth M. Bryden and Sang C.Lee, Mixture preparation effects on distributed Combustion for Gas Turbine application, J.Energy Resources Technol, 2012, 134, 032201.

126. Kalinin A. P., Orlov A. G., Rodionov A. I., Troshin K.Ya., Demonstration of the possibility of studying combustion and explosion processes using remote hyperspectral sensing, Physicochemical kinetics in gas dynamics, www.chemphys .edu.ru / pdf / 2009-06-18-001.pdf

127. Vinogradov A. N., Yegorov V. V., Kalinin A. P., Melnikova E. M., Rodionov A. I., Rodionov I. D. Line of hyperspectral optical sensors Preprint SRI RAN Pr-2176, 2015.16 p.

128. N. M. Rubtsov, A. N. Vinogradov, A. P. Kalinin, A. I. Rodionov, K. Ya. Troshin, G. I. Tsvetkov, Establishing the Regularities of the Propagation of an Unstable Flame Front by the Methods of Optical 3D Spectroscopy and Color High-Speed Filming, Ishlinsky Institute for Problems in Mechanics RAS, Preprint No. 1097, 2015.

129. N.M.Rubtsov, B.S.Seplyarsky, G.I.Tsvetkov, V.I.Chernysh, Influence of inert additives on the time of formation of steady spherical fronts of laminar flames of mixtures of natural gas and isobutylene with oxygen under spark initiation, Mendeleev Communications, 2009, V.19, P.15.

130. Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Victor I. Chernysh and Georgii I. Tsvetkov, Initiation and propagation of laminar spherical flames at atmospheric pressure, Mendeleev Commun., 2011, 21, 218-220.

131. Pierse, R., Gaydon, A., The identification of molecular spectra, 1941, N.-Y., London, Acad. Press, 240 R.

132. T. Icitaga, Emission spectrum of the oxy-hydrogen flame and its reaction mechanism. (1) Formation of the Activated Water Molecule in Higher Vibrational States. The Review of Physical Chemistry of Japan Vol. 13f, No. 2 (1939), P. 96-107.

133. P. Stamatoglou, Spectral Analysis of Flame Emission for Optimization Of Combustion Devices on Marine Vessels, Master of Science Thesis, Department of Physics, Lund University, Kockumation Group, Malmö(Sweden), May 2014

134. NIST Atomic Spectra Database http://physics.nist.gov/ PhysRefData/ASD/ lines_form. html

135. B. Lewis, G. Von Elbe, Combustion, Explosions and Flame in Gases, New York, London.: Acad.Press, 1987, 566 P.

136. V. M. Maltsev, M. I. Maltsev, L. Y. Kashporov, Axial combustion characteristics, M:, Chemistry, 1977, 320 p.

137. N.Hamoushe, Trace element analysis in aluminium alloys, Alcan International Limited, Quebec, Canada, http://www.riotintoalcan.com/ENG/media/76.asp

138. Constructional materials, p/r B. I. Arzamasov, M:, Mechanical Engineering, 1990, 360 P.

139. W. Meyerriecks and K. L. Kosanke, Color Values and Spectra of the Principal Emitters in Colored Flames, Journal of Pyrotechnics, 2003, No. 18, R. 720 - 731.

140. S. G. Saytzev and R. I. Soloukhin, "Proceedings of the 8th symposium (International) on combustion," in California Institute of Technology Pasadenia, California, (The Combust. Inst., Pittsburgh, PA), 1962, p. 2771.

141. R.K.Eckhoff, Dust Explosions in the Process Industries, 2nd edn., Butterworth-Heinemann, Oxford, 1997.

142. J. C. Livengood and W. A. Leary, "Autoignition by rapid compression," Industrial and Engin. Chem., 1951, 43, 2797.

143. T. C. Germann, W. H. Miller, Quantum mechanical pressure dependent reaction and recombination rates for OH + O →O2 + H, J. Phys. Chem. A: 1997, V.101, P.6358-6367.

144. Frank-Kamenetsky D. A., Diffusion and heat transfer in chemical kinetics. Publishing house "Nauka", 1967, 489 p.

145. S.Chakraborty, A.Mukhopadhyay, S.Sen, International Journal of Thermal Sciences, 2008, 47, 84.

146. G.K. Hargrave, S.J. Jarvis, and T.C. Williams, Meas. Sci. Technol., 2002, 13, 1036.

147. V. Polezhaev, S. Nikitin, Thermoacoustics and heat transfer in an enclosure induced by a wall heating , 16th International Congress on Sound and Vibration, Kraków, Poland, 5–9 July 2009, p.2-8

148. I.O. Moen, M.Donato, R. Knystautas and J.H. Lee, Combust.Flame, 1980, 39, 21.

149. S.S. Ibrahim and A.R. Masri, J. Loss Prev. in the Process Ind., 2001, 14, 213.

150. G.D. Salamandra, T.V.Bazhenova, I.M.Naboko, Zhurnal Technicheskoi fiziki, 1959, 29, 1354 (in Russian).

151. N. Ardey, F. Mayinger, Highly turbulent hydrogen flames, Proc. of the 1st Trabson Int. Energy and Environment Symp., Karadeniz Techn.Univ., Trabson,Turkey, 1996. 679

152. B.Durst, N. Ardey, F. Mayinger, OECD/NEA/CSNI Workshop on the Implementation of Hydrogen Mitigation Techniques, Winnipeg, Manitoba. 1996, AECL-11762, 433.

153. M.Jourdan, N. Ardey, F. Mayinger and M.Carcassi, Influence of turbulence on the deflagrative flame propagation in lean premixed hydrogen air mixtures, Heat Transfer, Proceedings of 11th IHTC, Kuongju, Korea, 1998, 7, 295.

154. Gussak L.A., Turkish M.C. LAG Stratiff. Charge Engines, 1 Mech. Conference Publication. London, 1976, 137.

155. Naboko I. M., Rubtsov N. M., Seplyarsky B. S., Troshin K.Ya., Tsvetkov G.I., Chernysh V. I., Modes of flame propagation during combustion of lean hydrogen-air mixtures in the presence of additives under conditions of central initiation at atmospheric pressure, "Physical-Chemical kinetics in gas dynamics", 2012. Volume 13, URL: http://www.chemphys.edu.ru/pdf/2012-11-02-001.pdf P .1-17

156. I. M. Naboko, N. M. Rubtsov, B. S. Seplyarskii and V. I. Chernysh, Interaction of Spherical Flames of Hydrogen-Air and Methane-Air Mixtures in the Closed Reactor at the Central Spark Initiation with Closed Meshed Obstacles, J Aeronaut Aerospace Eng, 2013, 2:5, http://dx.doi.org/10.4172/2168-9792.1000127.

157. N.M. Rubtsov, The Modes of Gaseous Combustion, Springer International Publishing, 2016, 302 R.

158. Ideya M. Naboko, Nikolai M. Rubtsov, Boris S. Seplyarskii, Victor I. Chernysh and Georgii I. Tsvetkov, Influence of an acoustic resonator on flame propagation regimes in spark initiated H2 combustion in cylindrical reactor in the vicinity of the lower detonation limit, Mendeleev Commun., 2013, 23, 163.

159. Thomas Alasard, Low Mach number limit of the full Navier-Stokes equations, Archive for Rational Mechanics and Analysis 180 (2006), no. 1, 1-73.

160. F. Nicoud, Conservative High-Order Finite-Difference Schemes for Low-Mach Number Flows.

161. V.Akkerman, V.Bychkov, A.Petchenko, L.-E. Eriksson, Flame oscillations in tubes with nonslip at the walls, Combustion and Flame, 2006, V.145. P.675-687.

162. A.Majda, Compressible fluid flow and systems of conservation laws in severalspace variables, Applied Mathematical Sciences, vol. 53, Springer-Verlag, New York, 1984.

163. D. I. Abugov, V. M. Bobylev, Theory and calculation of solid fuel rocket engines, M: Mechanical engineering, 1987, 271 P.

164. Clavin, P. Premixed combustion and gasdynamics. Ann. Rev. Fluid Mech. 1994, 26, 321-352.

165. C. Clanet, G. Searby and P. Clavin, Primary acoustic instability of flames propagating in tubes: cases of spray and premixed gas combustion, J. Fluid Mech.,1999, 385, 157.

166. B. Lewis, G. Von Elbe, Combustion, Explosions and Flame in Gases, New York, London.: Acad.Press, 1987, P.566.

167. Kampen, J. F. van, Acoustic pressure oscillations induced by confined turbulent premixed natural gas flames, PhD thesis, University of Twente, Enschede, The Netherlands, March 2006, ISBN 90-365-2277-3, Printed by Febodruk BV, Enschede, The Netherlands.

168. G. Backstrom, Simple Fields of Physics by Finite Element Analysis (Paperback), GB Publishing (2005), P 324.

169. Omar D. Lopez, Robert Moser and Ofodike A. Ezekoye, High-Order Finite Difference Scheme For The Numerical Solution Of The Low Mach-Number Equations. Mecánica Computacional, 2006, XXV, 1127.

170. N. M. Rubtsov, B.S. Seplyarskii, I. M. Naboko, V.I. Chernysh, G.I. Tsvetkov and K.Ya. Troshin, Non-steady propagation of single and counter flames in hydrogen–oxygen and natural gas–oxygen mixtures in closed cylindrical vessels with spark initiation in initially motionless gas, Mendeleev Commun., 2014, 24, 163.

171. Griffiths J.F., Barnard J.A. , Flame and Combustion, 1995, 3rd Edition, CRC Press, 328 P.

172. Abdel-Gayed R. G., Bradley D., Criteria for turbulent propagation limits of premixed flames.1985, Combust. Flame, 62, 61.

173. Bradley D.; Abdel-Gayed R.G.; Lung F.K.-K.. , Combustion regimes and the straining of turbulent premixed flames, 1989, Combust. Flame, 76, 213.

174. Melvin R. Baer and Robert J. Gross, 2001, SANDIA REPORT, Sandia National Laboratories Albuquerque, New Mexico 87185 and Livermore, California 94550.

175. Nickolai M.Rubtsov, Boris S.Seplyarskii, Kirill Ya.Troshin, Victor I.Chrenysh, Georgii I.Tsvetkov, Initiation and propagation of laminar spherical flames at atmospheric pressure // Mendeleev Comm., 2011, T.21, P.218-221.

176. Naboko I.M., Rubcov N.M., Seplyarskiy B.S., Cvetkov G.I., Chernysh V.I. Vozniknovenie termoakusticheskoy neustoychivosti v vodorodo- vozdushnyh smesyah v zamknutom reaktore pri central'nom iniciirovanii iskrovym razryadom//Fiziko-himicheskaya kinetika v gazovoy dinamike. 2011. Tom 12, URL: http://www.chemphys.edu.ru/pdf/2011-12-23-002.pdf

177. Erin Richardson, An experimental study of unconfined hydrogen –oxygen and hydrogen-air explosions, https://ntrs.nasa.gov/search.jsp?R=20150002596 2018-09-27T16:35:29+00:00Z

178. Ya. B. Zeldovich, A. S. Sompaneets, Detonation Theory, Moscow.: Gostechizdat, 1955, 268 P. (in Russian).

179. J.E. Shepherd, Detonation in gases Proceedings of the Combustion Institute, 2009, V.32, P. 83–98.

180. Stephen B. Murray, Fundamental and Applied Studies of Fuel-Air Detonation - A Quarter Century of Large-Scale Testing at DRDC Suffield (Stephen. Murray @ drdc-rddc.gc.ca), 2010, DRDC Suffield, P.O. Box 4000, Station Main, Medicine Hat, Alberta, Canada T1A 8K6

181. Steven A. Orzag and Lawrence C. Kellst, J. Fluid Mech., 1980, 96, 159.

182. Saric W.S., Reed H.L., Kerschen E.J., Annu. Rev. Fluid Mech., 2002, 34, 291.

183. S.S. Ibrahim and A.R. Masri, J. Loss Prev. in the Process Ind., 2001, 14, 213.

184. C. Clanet and G. Searby, Combustion and flame, 1996, 105, 225.

185. N. M. Rubtsov, B. S. Seplyarskii V. I. Chernysh and G.I.Tsvetkov, International Journal of Chemistry and Materials Research, 2014, 2,102, http://pakinsight.com/?ic=journal&journal=64

186. G. N. Abramovich, Teorija turbulentnych struj (The theory of turbulent flows), 1960, Moscow, Ekolit, reprint, 2011 (in Russian).

187. V.V.Lemanov, V.I.Terechov, K.A, Sharov, A.A.Shumeiko, JETP Letters, 2013, 39, 89 (Pis'ma v ZhETF, 2013, 39, 34).

188. F. Durst, K. Haddad, O. Ertun, in Advances in Turbulence ed. Prof. B. Erkhardt, Proceedings of the 12th Euromech European Turbulence Conference September 7-10 Marburg Germany, Springer Publishing, 160.

189. Vinogradov A. N., Yegorov V. V., Kalinin A. P., Melnikova E. M., Rodionov A. I., Rodionov I. D. Line of hyperspectral optical sensors Preprint SRI RAN Pr-2176, 2015.16 p.

190. N. M. Rubtsov, A. N. Vinogradov, A. P. Kalinin, A. I. Rodionov, K. Ya. Troshin, G. I. Tsvetkov, Establishing the Regularities of the Propagation of an Unstable Flame Front by the Methods of Optical 3D Spectroscopy and Color High-Speed Filming, IPMech RAS, Preprint No. 1097, 2015.

191. Nickolai M.Rubtsov, Boris S.Seplyarskii, Kirill Ya.Troshin, Victor I.Chrenysh, Georgii I.Tsvetkov, Initiation and propagation of laminar spherical flames at atmospheric pressure // Mendeleev Comm., 2011, T.21, P.218-221.

192. Coheur P.-F., Bernath P.F., Carleer M., Colin R., et al. A 3000 K laboratory emission spectrum of water, The Journal of Chemical Physics. 2005. 122. 074307

193. Herzberg G. Molecular Spectra and Molecular Structure. Vol. 1, Spectra of Diatomic Molecules. 2nd edn. Van Nostrand. New York. 1950.

194. Kreshkov A. P. Fundamentals of analytical chemistry. Theoretical basis. Qualitative analysis, 1970, M:; Publishing house "Khimiya", V. 3.

195. Davy H. Some new experiments and observations on the combustion of gaseous mixtures, with an account of a method of preserving a continuous light in mixtures of inflammable gases and air without flame. 1817, Phil. Trans. R. Soc. Lond. A v. 107, P.77-100.(magazine ? )

196. Lee J. H. and Trimm D. L. Catalytic combustion of methane, Fuel Processing Technology, 1995, v.42. P.339-355.

197. Deutschmann, O., Maier, L. I., Riedel, U.et al. Hydrogen assisted catalytic combustion of methane on platinum. Catalysis Today. 2000. V.59, P.141-165.

198. Lyubovsky M., Karim H., Menacherry P. et al. Complete and partial catalytic oxidation of methane over substrates with enhanced transport properties. Catalysis Today. 2003. V.83. P. 183-201.

199. Salomons S., Hayes R. E., Poirier M. et al. Flow reversal reactor for the catalytic combustion of lean methane mixtures. Catalysis Today. 2003. v.83. P. 59-75.

200. Lampert J. K., Kazia M. S., and Farrauto, R. J. Palladium catalyst performance for methane emissions abatement from lean burn natural gas vehicles. //Applied catalysis B: Environmental. 1997. v. 14, P. 211-230.

201. IAEA SAFETY STANDARDS SERIES. Design of Reactor Containment Systems for Nuclear Power Plants SAFETY GUIDE No. NS-G-1.10, 2004.

202. Frennet A. Chemisorption and exchange with deuterium of methane on metals. // Catal. Rev.- Sci.Eng. 1974. v. 10. P. 37-51.

203. Cullis C.F., Willatt B.M. Oxidation of methane over supported precious metal catalysts. // Journal of Catalysis. 1983. v. 83, P. 267-281.

204. Hicks R.F., Qi H., Young M.L. and Lee, R.G. Structure sensitivity of methane oxidation over platinum and palladium. // Journal of Catalysis. 1990. v.122. P. 280-291.

205. Hayes R.E, Kolaczkowskii S., Lib P., Awdryb S., The palladium catalyzed oxidation of methane: reaction kinetics and the effect of diffusion barriers, Chemical Engineering Science, 2001. v. 56. P. 4815-4830.

206. S. Choudhury, R. Sasikala, V. Saxena, D. Kumar-Aswalb and D. Bhattacharyac, A new route for the fabrication of an ultrathin film of a PdO–TiO2 composite photocatalyst, Dalton Trans. 2012, 41, 12090-12095.

207. P.O. Nilsson and M.S. Shivaraman. Optical properties of PdO in the range of 0.5–5.4 eV. J. Phys. C: Solid State Phys. 12, 1423-1427 (1979).

208. F. Ling, O. Chika Anthony, Q. Xiong, M. Luo,X. Pan, L. Jia, J. Huang, D. Sun, Q. Li. PdO/LaCoO3 heterojunction photocatalysts for highly hydrogen production from formaldehyde aqueous solution under visible light,International journal o f hydrogen energy 41, 6115-6122, (2016).

209. S.Diaz, M.L.Valenzuela, C.Rios and M.Segovia, Oxidation facility by a temperature dependence on the noble metals nanostructured M°/MxOy phase products using a solid state method: the case of Pd, J. Chil. Chem. Soc., 2016, 61 no.4, http://dx.doi.org/10.4067/S0717-97072016000400024

210. Rodionov I. D., Rodionov A. I., Vedeshin L. A., Vinogradov A. N., Yegorov V. V., Kalinin A. P., Aviation hyperspectral complexes for solving problems of remote sensing. Exploration of the Earth from space 2013. №6. P. 81; Rodionov I. D., Rodionov A. I., Vedeshin L. A., Yegorov V. V., Kalinin A. P. , Izvestija, Atmospheric and Oceanic Physics. 2014. V. 50. No. 9. 2014. P. 983.

211. Vinogradov A. N., Yegorov V. V., Kalinin A. P., Rodionov A. I., Rodionov I. D. // Optical instrument engineering. 2016. Vol. 83. No. 4. P. 54.

212. Kalinin A. P., Orlov A. G., Rodionov A. I., Troshin K.Ya. Demonstration of the possibility of studying combustion and explosion processes using remote hyperspectral sensing // Physicochemical kinetics in gas dynamics. 2009. V. 8. [Electronic resource] Access mode: http://chemphys.edu.ru/issues/2009-8/articles/202/.

213. Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Victor I. Chernysh and Georgii I. Tsvetkov, Mendeleev Commun. 2012, V. 22. P. 222.

214. Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Georgii I. Tsvetkov and Victor I. Chernysh High-speed colour cinematography of the spontaneous ignition of propane–air and n-pentane–air mixtures,  Mendeleev Communications 2011, 21, 31-33.

215. Nikolai M. Rubtsov , Victor I. Chernysh, Georgii I. Tsvetkov, Kirill Ya. Troshin, Igor O. Shamshin, Ignition of hydrogen–air mixtures over Pt at atmospheric pressure, Mendeleev Communications, 2017, 27, 307-309.

216. Nikolai M. Rubtsov, Alexey N. Vinogradov, Alexander P. Kalinin, Alexey I. Rodionov, Victor I. Chernysh, Cellular combustion and delay periods of ignition of a nearly stoichiometric H2–air mixture over a platinum surface, Mendeleev Communications, 2016, 160-162.

217. K.L. Cashdollar, I.A. Zlochower, G.M. Green, R.A. Thomas and M.Hertzberg, Journal of Loss Prevention in the Process Industries, 2000. V.13, N3-5, P.327-340.

218. Lewis B., Von Elbe G., Combustion, Explosions and Flame in Gases. New York, London. Acad. Press. 1987.

219. S.M.Repinski, Vvedenie v himicheskuyu fiziky poverhnosti tvyordych tel (Introduction into chemical physics of the surface of solids), Novosibirsk:; “Nauka”, Sibir publishing company, 1993 (in Russian).

220. M. Johansson, E. Skulason, G. Nielsen, S. Murphy, R.M. Nielsen, I. Chorkendorff, A systematic DFT study of hydrogen diffusion on transition metal surfaces. Surface Science, 2010, 604, 718.

221. Rothman L.S., Gordon I.E., Babikov Y., Barbe A., Chris Benner D., et al. The HITRAN 2012 Molecular Spectroscopic Database//Journal of Quantitative Spectroscopy & Radiative Transfer. 2013. 130. P. 4-50

222. N. M. Rubtsov, A. N. Vinogradov, A. P. Kalinin, A. I. Rodionov, I. D. Rodionov, K. Ya. Troshin, G. I. Tsvetkov, V. I. Chernysh, The use of a high-speed optical multidimensional technique for establishing the characteristics of ignition and combustion of a 40% H2 - air mixture in the presence of platinum metal, Physical and chemical kinetics in gas dynamics 2016 Vol.17 (1) http://chemphys.edu.ru/issues/ 2016-17-1 / articles / 615 /.

223. R.G. Stützer, S. Kraus, M. Oschwald, Characterization of Light Deflection on Hot Exhaust Gas for a LIDAR Feasibility Study, May 2014 Conference 4th Space Propulsion 2014, https://www.researchgate.net/publication/263586493.

224. T. Icitaga, Emission spectrum of the oxy-hydrogen flame and its reaction mechanism. (1) Formation of the Activated Water Molecule in Higher Vibrational States. The Review of Physical Chemistry of Japan Vol. 13f, No. 2 (1939), Pp. 96‒107.

225. N.M.Rubtsov, V.I.Chernysh, G.I.Tsvetkov, K.Ya.Troshin, I. O.Shamshin, A.P. Kalinin, The features of hydrogen ignition over Pt and Pd foils at low pressures Mendeleev Communications, 2018, 28, 216-218

226. Tang, C., Zhang, Y., Huang, Z ., (2014). Progress in combustion investigations of hydrogen enriched hydrocarbons, Renewable and Sustainable Energy Reviews, 30, 195–216.

227. Knyazkov, A., Shvartsberg, V.M., Dmitriev, A.M., Osipova, K.N., Shmakov, A.G., Korobeinichev, O.P., Burluka, A., (2017). Combustion Chemistry of Ternary Blends of Hydrogen and C1–C4 Hydrocarbons at Atmospheric Pressure, Combustion, Explosion, and Shock Waves, 53(5), 491–499.

228. Biswas, S., Tanvir, S., Wang, H., Qiao, L., 2016. On ignition mechanisms of premixed CH4/air and H2/air using a hot turbulent jet generated by pre-chamber combustion, Applied Thermal Engineering, 106, 925–937.

229. Cho, E.-S., & Chung, S. H., (2009). Improvement of flame stability and NOx reduction in hydrogen-added ultralean premixed combustion, Journal of Mechanical Science and Technology, 23, 650-658.

230. Razali, H., Sopian, K., Mat, S. (2015). Green fuel: 34% reduction of hydrocarbons via hydrogen (AL+HCl) blended with gasoline at maximum torque for motorcycle operation. ARPN Journal of Engineering and Applied Sciences, 10(17), 7780-7783.

231. Flores, R. M., McDonell, V. G., Samuelsen, G. S., (2003). Impact of Ethane and Propane Variation in Natural Gas on Performance of a Model Gas Turbine Combustor, J. Eng. Gas Turbines Power, 125, 701–708.

232. Hassan, H., & Khandelwal, B., (2014). Reforming Technologies to Improve the Performance of Combustion Systems, Aerospace, 1, 67-96.

233. Xiong, H., Wiebenga, M. H., Carrillo, C., Gaudet, J. R., Pham, H.N. , Kunwar, D., et.al (2018). Design considerations for low-temperature hydrocarbon oxidation reactions on Pd based catalysts, Applied Catalysis B: Environmental, 236 (15), 436-444.

234. Persson, K., Pfefferle, L.D., Schwartz, W., Ersson, A., Jaras, S.G., (2007). Stability of palladium-based catalysts during catalytic combustion of methane: The influence of water, Applied Catalysis B: Environmental, 74, 242–250.

235. Rubtsov, N.M., Chernysh, V.I., Tsvetkov, G.I., Troshin, K.Ya., Shamshin I.O., (2019). Ignition of hydrogen-methane-air mixtures over Pd foil at atmospheric pressure, Mendeleev Commun., 2019, 29, (in press).

236. Rubtsov, N.M. (2016), The Modes of Gaseous Combustion, Cham, Switzerland, Springer International Publishing.

237. Markstein, G. H., (1949). Cell structure of propane flames burning in tubes, The Journal of Chemical Physics, 17, 428.

238. Zeldovich, Ya. B., (1944). Theory of Combustion and Detonation in Gases, Moscow, Acad. Sci. USSR, (in Russian).

239. Kreshkov A. P. Osnovy analiticheskoy himii. Teoreticheskie osnovy. Kachestvennyy analiz, 1970, M:; Izd-vo “Himiya”, T.3.

240. Nikolai M.Rubtsov, Alexey N.Vinogradov, Alexander P.Kalinin,Alexey I.Rodionov, Kirill Ya.Troshin,Georgii I.Tsvetkov,Victor I.Chernysh, Gas dynamics and kinetics of the penetration of methane–oxygen flames through complex obstacles, as studied by 3D spectroscopy and high-speed cinematography, Mendeleev Communications, 2017, 27, 192-194.

241. Ideya M. Naboko, Nikolai M. Rubtsov, Boris S. Seplyarskii, Kirill Ya. Troshin, Victor I. Chernysh, Cellular combustion at the transition of a spherical flame front to a flat front at the initiated ignition of methane–air, methane–oxygen and n-pentane–air mixtures, Mendeleev Communications, 2013, 23, 358-360.

242. M.Fisher, Safety aspects of hydrogen combustion in hydrogen energy systems, Int. J. Hydrogen Energy, 1986, 11, 593-601.

243. A.B.Welch and J.S.Wallace, Performance characteristics of a hydrogen-fueled diesel engine, SAE Paper 902070.

244. R.K.Kumar, Ignition of hydrogen-oxygen- diluent mixtures adjacent to a hot, non-reactive surface, Combustion and Flame, 1989, 197-215.

245. R.S.Silver, The ignition of gaseous mixture by hot particles, Phil. Mag. J.Sci., 1937, 23, 633-657.

246. K.B.Brady, Ignition Propensity of hydrogen/air mixtures in the presence of heated platinum surfaces, Master of Science Thesis, Department of Mechanical and Aerospace Engineering, Case Western Reserve University, January, 2010 .

247. Rinnemo, M., et al., Experimental and numerical investigation of the catalytic ignition of mixtures of hydrogen and oxygen on platinum. Combustion and Flame, 1997, 111, 312-326.

248. S.K. Menon, P.A. Boettcher, B.Ventura, G. Blanquart and J.E. Shepherd, Investigation of hot surface ignition of a flammable mixture, Western States Section of the Combustion Institute (WSSCI), 2012, Arizona University, Tempe, Paper # 12S-39.

249. Dong-Joon Kim, Ignition Temperature of Hydrogen/Air Mixture by Hot Wire in Pipeline, Fire Sci. Eng., 2014, 28, No. 4, 8-13.

250. Tables of Physical Values, handbook, ed. I. K.Kikoin, Atomizdat, Moscow, 1976, p. 1007 (in Russian).

251. Marchuk G.I. Methods of computational mathematics, Moscow; Nauka, 1989, 608 p. (in Russian).

252. Rubtsov N. M., Kotelkin V. D., Karpov V. P., Transition of flame propagation from isothermal to chain-thermal mode in chain processes with nonlinear branching of chains, Kinetics and Catalysis, 2004, Vol. 45, P. 3.

253. N. N. Semenov, O nekotorykh problemakh khimicheskoi kinetiki i reaktsionnoi sposobnosti (On Some Problems of Chemical Kinetics and Reactivity), 2nd edn., AN SSSR, Moscow, 1958 (in Russian).

254. D.C.Montgomery, E.A.Peck, G.G.Vining, Introduction to linear regression analysis, 5 th ed., John Wiley@Sons Inc., Wiley Series in probability and statistics, Hoboken, New Jersey, US, 2012, 659 P.

255. Rubtsov N. M., Seplyarsky B. S., Alymov M. I. Critical Phenomena and Dimensional Effects in Autowave Processes with Exothermic Reactions. Saratov: Publishing House "KUBiK", 2019, 338 p. ISBN 978-5-91818-595-7.

256. B.S. Seplyarsky, T. P. Ivleva, M. I. Alymov. Macrokinetic analysis of the process of passivation of pyrophoric powders. Reports of the Academy of Sciences. Physical chemistry. 2018. Vol. 478, No. 3, pp. 310-314.

257. Michail I. Alymov, Nikolai M. Rubtsov, Boris S. Seplyarskii, V.A.Zelensky, A.B.Ankudinov, The Method of Preparation of Ni Nanopowders with Controlled Mean Specific Surface and Pyrophoricity, UNITED JOURNAL OF CHEMISTRY www.unitedjchem.org, 2018, Vol. 01, No.(1): Pg. 82-91.

258. P. Zijlstra, M. Orrit, Single metal nanoparticles: optical detection, spectroscopy and applications, Reports on Progress in Physics, 2011, 74, 106401.

259. A. Kamyshny, J. Steinke, S. Magdassi, Metal-based inkjet inks for printed electronics, Open Applied Physics J., 2011, 4, 19.

260. R. Gréget, G.L. Nealon, B. Vileno, P. Turek, C. Mény, F. Ott, A. Derory, E. Voirin, E. Rivière, A. Rogalev, Magnetic properties of gold nanoparticles: a room-temperature quantum effect, ChemPhysChem, 2012, 13, 3092.

261. R.R. Letfullin, C.B. Iversen, T.F. George, Modeling nanophotothermal therapy: kinetics of thermal ablation of healthy and cancerous cell organelles and gold nanoparticles, Nanomedicine: Nanotech., Bio. and Med., 2011, 7, 137.

262. Wei, Y.; Chen, S.; Kowalczyk, B.; Huda, S.; Gray, T. P.; Grzybowski, B. A. , 2010, Synthesis of stable, low-dispersity copper nanoparticles and nanorods and theirantifungal and catalytic properties, J. Phys. Chem. C. 114, 15612.

263. Ramyadevi, J.; Jeyasubramanian, K.; Marikani, A.; Rajakumar, G.; Rahuman, A. A. , 2012, Synthesis and antimicrobial activity of copper nanoparticles, Mater. Lett. 71: 114.

264. Dhas, N.A.; Raj, C.P.; Gedanken, A. , Synthesis, Characterization, and Properties of Metallic Copper Nanoparticles, 1998, Chem. Mater., 10, 1446.

265. H. Hashemipour, M.E. Zadeh, R. Pourakbari, P. Rahimi, Inter. J. of Physical Sciences, Investigation on synthesis and size control of copper nanoparticle via electrochemical and chemical reduction method, 2011, 6, 4331.

266. M. Salavati-Niasari, F. Davar, Synthesis of copper and copper (I) oxide nanoparticles by thermal decomposition of a new precursor, Materials Letters, 2009, 63, 441.

267. B.K. Park, D. Kim, S. Jeong, J. Moon, J.S. Kim, Direct writing of copper conductive patterns by ink-jet printing, Thin Solid Films, 2007, 515, 7706.

268. E. Egorova, A. Revina, Synthesis of metallic nanoparticles in reverse micelles in the presence of quercetin, Colloids and Surfaces A: Physicochem. and Eng. Aspects, 2000, 168, 87.

269. R. Zhou, X. Wu, X. Hao, F. Zhou, H. Li, W. Rao, Oxidation of Copper Nanoparticles Protected with Different Coatings, Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2008, 266, 599.

270. J.N. Solanki, R. Sengupta, Z. Murthy, Synthesis of Copper Nanoparticles, Solid State Sciences, 2010, 12, 1560. 17 L. Francis, A.S. Nair, R. Jose, S. Ramakrishna, V. Thavasi and E. Marsano, Fabrication and characterization of dye-sensitized solar cells from rutile nanofibers and nanorods, Energy, 36, 627-632, (2011)

271. K. Tian, C. Liu, H. Yang, X. Ren, Sensors and Actuators of transition metal elements, Colloids and Surfaces A: Physicochem. and Eng. Aspects, 2012, 397, 12.

272. Michail I. Alymov, Nikolai M. Rubtsov, Boris S. Seplyarskii, Victor A. Zelensky and Alexey B. Ankudinov, Temporal characteristics of ignition and combustion of iron nanopowders in the air, Mendeleev Commun., 2016, 26, 452.

273. Thomas M.Gorrie, Peter W.Kopf and Sidney Toby, Kinetics of the reaction of some pyrophoric metals with oxygen, J.Phys.Chem., 1967, 71, 3842.

274. B.K. Sharma, Objective Question Bank in Chemistry, Krishns Prakashan Media Ltd., India, 2009, 488 P. 22. https://www.nanoshel.com/topics/nanoshel-llc-news/

275. A. G. Gnedovets, A. B. Ankudinov, V. A. Zelenskii, E. P. Kovalev, H. Wisniewska_Weinert, and M. I. Alymov, Perspektivnye Materialy, 2015, 12, 62 [Inorganic Materials: Applied Research, 2016, 7, 303] (in Russian).

276. W. R. Morcom W. L. Worrell H. G. Sell H. I. Kaplan The preparation and characterization of beta-tungsten, a metastable tungsten phase, Metallurgical Transactions,January 1974, 5:155,

277. Žutić, J. Fabian, and S. Das Sarma, Spintronics: Fundamentals and Applications, Rev. Mod. Phys. 76, 323 (2004).

278. S. A. Wolf, D. D. Awschalom, R. A. Buhrman, J. M. Daughton, S. von Molnár, M. L. Roukes, A. Y. Chtchelkanova, and D. M. Treger, Spintronics: A Spin-Based Electronics Vision for the Future, Science 294, 1488 (2001)

279. M. Johnson and R. H. Silsbee, Interfacial Charge-Spin Coupling: Injection and Detection of Spin Magnetization in Metals, Phys. Rev. Lett. 55, 1790 (1985).

280. T. Jungwirth, J. Wunderlich, and K. Olejnik, Spin Hall Effect Devices, Nat. Mater. 11, 382 (2012).

281. C. F. Pai, L. Liu, Y. Li, H. W. Tseng, D. C. Ralph, and R. A. Buhrman, Spin Transfer Torque Devices Utilizing the Giant Spin Hall Effect of Tungsten, Appl. Phys. Lett. 101, 122404 (2012).

282. Q. Hao, W. Chen, and G. Xiao, Beta (β) Tungsten Thin Films: Structure, Electron Transport, and Giant Spin Hall Effect, Appl. Phys. Lett. 106, 182403 (2015).

283. G. Hägg and N. Schönberg, 'β-Tungsten' as a Tungsten Oxide, Acta Crystallogr. 7, 351 (1954).

284. P. Petroff, T. T. Sheng, A. K. Sinha, G. A. Rozgonyi, and F. B. Alexander, Microstructure, Growth, Resistivity, and Stresses in Thin Tungsten Films Deposited by RF Sputtering, J. Appl. Phys. 44, 2545 (1973).

285. Erik Lassner and Wolf-Dieter Schubert, Tungsten Properties, Chemistry, Technology of the Element, Alloys, and Chemical Compounds, 1998, Kluwer Academic / Plenum Publishers New York, Boston, Dordrecht, London, Moscow, 447 P.

286. Michail I. Alymov, Nikolai M. Rubtsov, Boris S. Seplyarskii,Victor A. Zelensky and Alexey B. Ankudinov, Passivation of iron nanoparticles at subzero temperatures, Mendeleev Commun., 2017, 27, 482-484.

287. Florin Saceleanu, Mahmoud Idir, Nabiha Chaumeix and John Z. Wen, Combustion Characteristics of Physically Mixed 40 nm Aluminum/Copper Oxide Nanothermites Using Laser Ignition, Frontiers in Chemistry, original research published: 09 October 2018, doi: 10.3389/fchem.2018.00465.

288. Alexander A. Gromov, Ulrich Teipel, Metal Nanopowders: Production, Characterization, and Energetic Applications, 2014, John Wiley & Sons, 417 P.

289. Michail I.Alymov, Nikolai M. Rubtsov, Boris S. Seplyarskii, Victor A. Zelensky, Alexey B. Ankudinov, Temporal characteristics of ignition and combustion of iron nanopowders in the air, Mendeleev Commun., 2016, V.26,452-454.