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One-dimensional pre-mixed model for a pulsed chemical oxygen-iodine laser is presented according to the reaction mechanism in chemical oxygen-iodine laser. The influences of gas temperature of 150-450 K and pressure of 660-2660 Pa on single pulse energy, pulse duration and peak power are studied. The internal reason of the influences of pressure and temperature on laser characteristics is analyzed. The results show that the higher laser peak power can be obtained in the case of gas temperature of 150 K and pressure of 1330 Pa than in the case of 400 K and 2660 Pa. Thus an efficient pulsed chemical oxygen-iodine laser is promising if the abundant atomic iodine is generated instantaneously. The approach to atomic iodine generation does not disturb the state of supersonic flow.
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Keywords:
- atomic iodine /
- pulse /
- chemical oxygen-iodine laser /
- supersonic
[1] Wani F, Nakabayashi T, Hayakawa A 2002 Proc. SPIE 4631 128
[2] Matsuzaka F, Ohga T 1989 Proc. Int. Conf. "Lasers'89" 223
[3] Highland R, Crowell P, Hager G 1990 Proc. SPIE 1225 512
[4] Schmiedberger J, Kodymova J 1991 IEEE J. Quant. Electron. 27 1262
[5] Yuryshev N N 1991 Proc. SPIE 1397 221
[6] Zhang R Y, Chen F, Sang F T, Min X D, Shao M Y 1989 Proc. SPIE 1031 308
[7] Li G F, Yu H J, Duo L P, Jin Y Q 2009 Chin. Phys. Lett. 26 114201
[8] Jin Y, Pan B L, Chen G, Chen K, Yao Z X 2004 Acta Phys. Sin. 53 1799 (in Chinese) [金毅, 潘佰良, 陈钢, 陈坤, 姚志欣 2004 53 1799]
[9] Ding C L, Wan C Y 2006 Acta Phys. Sin. 55 1165 (in Chinese) [丁长林, 万重怡 2006 55 1165]
[10] Cheng C 2003 Acta Phys. Sin. 52 3068 (in Chinese) [程成 2003 52 3068]
[11] Yuryshev N N 1998 Quant. Electron. 28 397
[12] Zhuang Q, Sang F T, Zhou D Z 1997 Short Wavelength Chemical Laser (Beijing: National Defence Industrial Press) p178 (in Chinese) [庄琦, 桑风亭, 周大正 1997 短波长化学激光 (北京:国防工业出版社) 第178页]
[13] Li G F, Duo L P, Jin Y Q, Yu H J, Wang D Z, Sang F T 2010 Acta Phys. Sin. 59 4672 (in Chinese) [李国富, 多丽萍, 金玉奇, 于海军, 王德真, 桑风亭 2010 59 4672]
[14] Carroll D L 1995 AIAA Journal 33 1454
[15] Yuryshev N N, Vagin N P 2002 Proceeding of SPIE 4760 515
[16] Zhang Y L, Sang F T, Zhang P, Jin Y Q 2007 Appl. Phys. Lett. 91 01110
[17] Duo L P, Yang B L, Sang F T, Jin Y Q 1998 IEEE J. Quan. Electron. 34 1258
[18] Go I, Tran T S, Masataro S, Wataru M 2007 Proceeding of SPIE 6346 63463A
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[1] Wani F, Nakabayashi T, Hayakawa A 2002 Proc. SPIE 4631 128
[2] Matsuzaka F, Ohga T 1989 Proc. Int. Conf. "Lasers'89" 223
[3] Highland R, Crowell P, Hager G 1990 Proc. SPIE 1225 512
[4] Schmiedberger J, Kodymova J 1991 IEEE J. Quant. Electron. 27 1262
[5] Yuryshev N N 1991 Proc. SPIE 1397 221
[6] Zhang R Y, Chen F, Sang F T, Min X D, Shao M Y 1989 Proc. SPIE 1031 308
[7] Li G F, Yu H J, Duo L P, Jin Y Q 2009 Chin. Phys. Lett. 26 114201
[8] Jin Y, Pan B L, Chen G, Chen K, Yao Z X 2004 Acta Phys. Sin. 53 1799 (in Chinese) [金毅, 潘佰良, 陈钢, 陈坤, 姚志欣 2004 53 1799]
[9] Ding C L, Wan C Y 2006 Acta Phys. Sin. 55 1165 (in Chinese) [丁长林, 万重怡 2006 55 1165]
[10] Cheng C 2003 Acta Phys. Sin. 52 3068 (in Chinese) [程成 2003 52 3068]
[11] Yuryshev N N 1998 Quant. Electron. 28 397
[12] Zhuang Q, Sang F T, Zhou D Z 1997 Short Wavelength Chemical Laser (Beijing: National Defence Industrial Press) p178 (in Chinese) [庄琦, 桑风亭, 周大正 1997 短波长化学激光 (北京:国防工业出版社) 第178页]
[13] Li G F, Duo L P, Jin Y Q, Yu H J, Wang D Z, Sang F T 2010 Acta Phys. Sin. 59 4672 (in Chinese) [李国富, 多丽萍, 金玉奇, 于海军, 王德真, 桑风亭 2010 59 4672]
[14] Carroll D L 1995 AIAA Journal 33 1454
[15] Yuryshev N N, Vagin N P 2002 Proceeding of SPIE 4760 515
[16] Zhang Y L, Sang F T, Zhang P, Jin Y Q 2007 Appl. Phys. Lett. 91 01110
[17] Duo L P, Yang B L, Sang F T, Jin Y Q 1998 IEEE J. Quan. Electron. 34 1258
[18] Go I, Tran T S, Masataro S, Wataru M 2007 Proceeding of SPIE 6346 63463A
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