О верификации методов определения импульса отдачи…
17
[4]
Andreev S., Firsov K., Kazantsev S., Kononov I., Samokhin A. Explosive
boiling of water induced by the pulsed HF-laser radiation.
Laser Physics
, 2007,
vol. 17, no. 6. pp. 834–841.
[5]
Giao M.A.P., Rodrigues N.A.S., Riva R., Schwab C. PVDF sensor in laser
ablation experiments.
Review of Scientific Instruments
, 2004, vol. 75, no. 12,
pp. 5213–5215.
[6]
Kanesue T., Tamura J., Okamura M. Ag ion generation irradiated by Nd:YAG
laser onto solid target for use of direct plasma injection scheme.
Proceedings of
12th international conference on ion sources (ICIS 2007)
. Jeju (Korea), AIP,
2008, p. 02B311-3.
[7]
Аскарьян Г.А., Манзон Б.М. Исследование импульса отдачи и
светореактивного ускорения при воздействии лазерного излучения
различной длительности. Применение бегущей фокусировки при
ускорении.
Физика плазмы
, 1981, т. 7, № 2, с. 255–266.
[8]
Phipps C., Birkan M., Bohn W., Eckel H.-A., Horisawa H., Lippert T.,
Michaelis M.M., Rezunkov Y., Sasoh A., Schall W., Scharring S., Sinko J.
Review: Laser-Ablation Propulsion.
Journal of Propulsion and Power
, 2010,
vol. 26, no. 4, pp. 609–637.
[9]
Luther-Davies B. An introduction to the physics of laser fusion.
Laser Physics
.
Springer, Berlin-Heidelberg, 1983, pp. 226–237.
[10]
Zhang N., Wang W., Zhu X., Liu J., Xu K., Huang P., Zhao J., Li R., Wang M.
Investigation of ultrashort pulse laser ablation of solid targets by measuring the
ablation-generated momentum using a torsion pendulum.
Opt. Express
, 2011,
vol. 19, no. 9, pp. 8870–8878.
[11] D'Souza B.C.
Development of impulse measurement techniques for the
investigation of transient forces due to laser-induced ablation
. Dis. … Ph.D.
2007, 124 p.
[12]
Sinko J.
Vaporization and shock wave dynamics for impulse generation in laser
propulsion
. Dis. ... Ph.D. Hunstsville, 2008, 249 p.
[13]
Scharring S., Sinko J., Sasoh A., Eckel H.-A., Röser H.-P. Experimental
Determination of the Impulse Coupling Coefficient — Standardization Issues.
International Journal of Aerospace Innovations
, 2011, vol. 3, no. 1, pp. 33–43.
[14]
Phipps C.R., Turner T.P., Harrison R.F., York G.W., Osborne W.Z., Anderson
G.K., Corlis X.F., Haynes L.C., Steele H.S., Spicochi K.C., King T.R. Impulse
coupling to targets in vacuum by KrF, HF, and CO
2
single-pulse lasers.
Journal
of Applied Physics
, 1988, vol. 64, no. 3, pp. 1083–1096.
[15] Vorobyev A.Y., Guo C. Residual thermal effects in laser ablation of metals.
Journal of Physics: Conference Series
, 2007, vol. 59, pp. 418-423.
[16] Mori K. Characteristics of laser ablation of pre-heated polymer materials.
27th
Plasma Processing Technical Committee (SPP-27)
. Yokohama, 2010, pp. B2–
02.
[17] Hosoya N., Kajiwara I., Hosokawa T. Vibration testing based on impulse
response excited by pulsed-laser ablation: Measurement of frequency response
function with detection-free input.
Journal of Sound and Vibration
, 2012, vol.
331, no. 6, pp. 1355–1365.
[18] Rocca S., Menon C., Nicolini D. FEEP micro-thrust balance characterization
and testing.
Measurement Science and Technology
, 2006, vol. 17, no. 4,
p. 711.
[19] Horisawa H., Sumida S., Funaki I. Low-Power Laser-Metal Interaction for
Space Propulsion Applications.
AIP Conference Proceedings
, 2010, vol. 1278,
no. 1, pp. 184–190.
