Theoretical analysis of hot image effect from phase scatterer

Liang Ping Xie; Jian Lin Zhao; Jing Qin Su; Feng Jing; Wen Yi Wang; Han Sheng Peng

Theoretical analysis of hot image effect from phase scatterer

Liang Ping Xie, Jian Lin Zhao, Jing Qin Su, Feng Jing, Wen Yi Wang, Han Sheng Peng

School of Physical Science and Technology

Research output: Contribution to journal › Article › peer-review

44 Scopus citations

Abstract

The nonlinear hot image effect from phase scatterer in a high-power laser system has been investigated theoretically and numerically. According to the Fresnel-Kirchhoff diffraction integral and nonlinear paraxial wave equation, we derive the functional relationship of the intensity of hot image and its location. It is shown that the image intensity is likely several times larger than that from amplitude scatterer, and the location is situated in the equidistant downstream plane of the scatterer in an optical component located upstream from a nonlinear element. Good agreements are shown between the Theoretical prediction and the computer codes developed for ns-pulse propagation simulations. The results indicate that the formation of hot image is akin to the real-time, in-line and volume-phase holographic imaging.

Original language	English
Pages (from-to)	2175-2179
Number of pages	5
Journal	Wuli Xuebao/Acta Physica Sinica
Volume	53
Issue number	7
State	Published - Jul 2004

Keywords

High-power laser
Holographic imaging
Hot image effect
Small-scale self-focusing

Cite this

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title = "Theoretical analysis of hot image effect from phase scatterer",

abstract = "The nonlinear hot image effect from phase scatterer in a high-power laser system has been investigated theoretically and numerically. According to the Fresnel-Kirchhoff diffraction integral and nonlinear paraxial wave equation, we derive the functional relationship of the intensity of hot image and its location. It is shown that the image intensity is likely several times larger than that from amplitude scatterer, and the location is situated in the equidistant downstream plane of the scatterer in an optical component located upstream from a nonlinear element. Good agreements are shown between the Theoretical prediction and the computer codes developed for ns-pulse propagation simulations. The results indicate that the formation of hot image is akin to the real-time, in-line and volume-phase holographic imaging.",

keywords = "High-power laser, Holographic imaging, Hot image effect, Small-scale self-focusing",

author = "Xie, {Liang Ping} and Zhao, {Jian Lin} and Su, {Jing Qin} and Feng Jing and Wang, {Wen Yi} and Peng, {Han Sheng}",

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T1 - Theoretical analysis of hot image effect from phase scatterer

AU - Xie, Liang Ping

AU - Zhao, Jian Lin

AU - Su, Jing Qin

AU - Jing, Feng

AU - Wang, Wen Yi

AU - Peng, Han Sheng

PY - 2004/7

Y1 - 2004/7

N2 - The nonlinear hot image effect from phase scatterer in a high-power laser system has been investigated theoretically and numerically. According to the Fresnel-Kirchhoff diffraction integral and nonlinear paraxial wave equation, we derive the functional relationship of the intensity of hot image and its location. It is shown that the image intensity is likely several times larger than that from amplitude scatterer, and the location is situated in the equidistant downstream plane of the scatterer in an optical component located upstream from a nonlinear element. Good agreements are shown between the Theoretical prediction and the computer codes developed for ns-pulse propagation simulations. The results indicate that the formation of hot image is akin to the real-time, in-line and volume-phase holographic imaging.

AB - The nonlinear hot image effect from phase scatterer in a high-power laser system has been investigated theoretically and numerically. According to the Fresnel-Kirchhoff diffraction integral and nonlinear paraxial wave equation, we derive the functional relationship of the intensity of hot image and its location. It is shown that the image intensity is likely several times larger than that from amplitude scatterer, and the location is situated in the equidistant downstream plane of the scatterer in an optical component located upstream from a nonlinear element. Good agreements are shown between the Theoretical prediction and the computer codes developed for ns-pulse propagation simulations. The results indicate that the formation of hot image is akin to the real-time, in-line and volume-phase holographic imaging.

KW - High-power laser

KW - Holographic imaging

KW - Hot image effect

KW - Small-scale self-focusing

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Theoretical analysis of hot image effect from phase scatterer

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Keywords

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