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Journal articles on the topic 'Laser holography'

Author: Grafiati
Published: 4 June 2021
Last updated: 12 February 2022

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1

TSUJIUCHI, Jumpei. "Laser Holography." Review of Laser Engineering 38, no. 1 (2010): 57–59. http://dx.doi.org/10.2184/lsj.38.57.

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2

Gao, Hui, Yuxi Wang, Xuhao Fan, Binzhang Jiao, Tingan Li, Chenglin Shang, Cheng Zeng, et al. "Dynamic 3D meta-holography in visible range with large frame number and high frame rate." Science Advances 6, no. 28 (July 2020): eaba8595. http://dx.doi.org/10.1126/sciadv.aba8595.

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The hologram is an ideal method for displaying three-dimensional images visible to the naked eye. Metasurfaces consisting of subwavelength structures show great potential in light field manipulation, which is useful for overcoming the drawbacks of common computer-generated holography. However, there are long-existing challenges to achieving dynamic meta-holography in the visible range, such as low frame rate and low frame number. In this work, we demonstrate a design of meta-holography that can achieve 228 different holographic frames and an extremely high frame rate (9523 frames per second) in the visible range. The design is based on a space channel metasurface and a high-speed dynamic structured laser beam modulation module. The space channel consists of silicon nitride nanopillars with a high modulation efficiency. This method can satisfy the needs of a holographic display and be useful in other applications, such as laser fabrication, optical storage, optics communications, and information processing.
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Parasnis, D. S. "Laser holography in geophysics." Geologiska Föreningen i Stockholm Förhandlingar 112, no. 4 (December 1990): 332. http://dx.doi.org/10.1080/11035899009452732.

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4

Hecht, Jeff. "Holography and the Laser." Optics and Photonics News 21, no. 7 (July 1, 2010): 34. http://dx.doi.org/10.1364/opn.21.7.000034.

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5

Borradaile, Graham J. "Laser holography in geophysics." Earth-Science Reviews 32, no. 3 (April 1992): 192–93. http://dx.doi.org/10.1016/0012-8252(92)90029-s.

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6

Kulshrestha, Rohit. "Laser holography in dentistry." Journal of Dental Specialities 8, no. 2 (July 15, 2021): 45–46. http://dx.doi.org/10.18231/j.jds.2020.011.

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7

WERDIGER, M., S. ELIEZER, S. MAMAN, Y. HOROVITZ, B. ARAD, Z. HENIS, and I. B. GOLDBERG. "Development of holographic methods for investigating a moving free surface, accelerated by laser-induced shock waves." Laser and Particle Beams 17, no. 4 (October 1999): 653–60. http://dx.doi.org/10.1017/s026303469917410x.

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Holographic methods developed to study the behavior of surfaces shocked by high power lasers are reported. Shock waves of the order of hundreds of kilobars are generated in Sn targets 50-μm thick, by a Nd:YAG laser system with a wavelength of 1.06 μm, a pulse duration of 7.5 ns FWHM, and irradiance in the range (1.0–2.6)·1013 W/cm2. Two configurations of off-axis holography were applied: holograms based on forward scattering, and holograms of both backward and forward scattering. The hologram is produced by scattering of a pulse, 6.7 ns (FWHM), of green laser light synchronized with the laser that generates the shock wave. Holograms of the topology of the rear surface of shocked Sn targets moving in vacuum and in air (at atmospheric pressure) are reported.
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8

Markov, V., and A. Khizhnyak. "Dynamic Holography for Improved Laser Capabilities." Journal of Holography and Speckle 3, no. 2 (December 1, 2006): 62–72. http://dx.doi.org/10.1166/jhs.2006.010.

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9

Shimizu, Isao, Yoshinori Saikawa, Katsuhiro Uno, Hideaki Kano, and Seishi Shimizu. "Contrast-tuneable microscopy for single-shot real-time imaging." European Physical Journal Applied Physics 91, no. 3 (September 2020): 30701. http://dx.doi.org/10.1051/epjap/2020200101.

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A novel real image in-line laser holography has enabled a tuneable image contrast, edge sharpness, and visualization of sub-wavelength structures, using a simple pair of filters and large-diameter lenses that can incorporate higher-order scattered beams. Demonstrated also are the accuracy in object sizing and the ease of imaging along the focal depth, based on a single-shot imaging via holographic principle. In addition, the use of broad, collimated laser beam for irradiation has led to a wider field of view, making it particularly useful for an extensive monitoring of, and sweeping search for, cells and microbial colonies and for the real-time imaging of cancer-cell dynamics.
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10

Hart, Stephen, Geraldo Mendes, Kaveh Bazargan, and Shenchu Xu. "Deep-red holography using a junction laser and silver-halide holographic emulsion." Optics Letters 13, no. 11 (November 1, 1988): 955. http://dx.doi.org/10.1364/ol.13.000955.

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11

Jacquemin, Peter B., and Rodney A. Herring. "Measurements Validating the Confocal Scanning Laser Holography Microscope." Microscopy and Microanalysis 17, no. 4 (July 13, 2011): 618–23. http://dx.doi.org/10.1017/s1431927611000511.

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AbstractA confocal scanning laser holography (CSLH) microscope that uniquely combines the concepts of confocal microscopy with holography has been validated for making nonintrusive, full three-dimensional (3D) intensity and phase measurements of objects from a single viewpoint of observation without loss of object information. The phase measurements have been used to determine the 3D refractive indices of a point source heated silicone oil. The refractive indices are converted to 3D temperature measurements, which are useful for heat transfer studies. An important feature of CSLH is its nonintrusive 3D scanning method, which enables its application to the study of Marangoni convection in microgravity with minimal operational vibrations affecting the motion of fluid in the specimen.
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12

MASUDA, Mitsuharu, Hidenobu YANO, Toshiyuki AOKI, and Kazuyasu MATSUO. "Particle Sizing with Inline Laser Holography using an Ultraviolet Laser." Journal of the Visualization Society of Japan 18, Supplement2 (1998): 71–72. http://dx.doi.org/10.3154/jvs.18.supplement2_71.

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13

KUSAKARI, Haruka, and Toshio TONOUCHI. "The Application For Laser Holography In Dentistry." JOURNAL OF JAPAN SOCIETY FOR LASER SURGERY AND MEDICINE 8, no. 2 (1987): 9–14. http://dx.doi.org/10.2530/jslsm1980.8.2_9.

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14

Shi, Bing-Chuan, Xiao-Lei Wang, Wen-Gang Guo, and Li-Pei Song. "Characteristic of femtosecond laser pulsed digital holography." Chinese Physics B 24, no. 8 (August 2015): 084202. http://dx.doi.org/10.1088/1674-1056/24/8/084202.

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15

Narisawa, Ikuo. "Non-destructive testing (AE, laser holography etc.)." Kobunshi 35, no. 7 (1986): 670–73. http://dx.doi.org/10.1295/kobunshi.35.670.

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16

Uno, Katsuhiro, Norihito Mano, Koichi Saruta, Kan-ichi Fujii, Isao Shimizu, and Yasuhiro Tokita. "Photoconductive Plastic Holography Employing White-Light Laser." Japanese Journal of Applied Physics 40, Part 1, No. 10 (October 15, 2001): 5951–52. http://dx.doi.org/10.1143/jjap.40.5951.

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17

Puyo, Léo, Michel Paques, Mathias Fink, José-Alain Sahel, and Michael Atlan. "Choroidal vasculature imaging with laser Doppler holography." Biomedical Optics Express 10, no. 2 (January 31, 2019): 995. http://dx.doi.org/10.1364/boe.10.000995.

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18

Ravaro, M., M. Locatelli, E. Pugliese, I. Di Leo, M. Siciliani de Cumis, F. D’Amato, P. Poggi, et al. "Mid-infrared digital holography and holographic interferometry with a tunable quantum cascade laser." Optics Letters 39, no. 16 (August 13, 2014): 4843. http://dx.doi.org/10.1364/ol.39.004843.

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19

Ushida, Norihiko, Ritsubun Soh, Yoshio Ookuma, and Masayuki Iizuka. "Simple Color Holography Techniques Using He-Cd Laser." JOURNAL OF THE ILLUMINATING ENGINEERING INSTITUTE OF JAPAN 84, Appendix (2000): 261. http://dx.doi.org/10.2150/jieij1980.84.appendix_261.

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20

Jacquemin, PB, and RA Herring. "Measurements Validating the Confocal Scanning Laser Holography Microscope." Microscopy and Microanalysis 16, S2 (July 2010): 886–87. http://dx.doi.org/10.1017/s143192761006318x.

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21

Tjörnhammar, Staffan, Finn Klemming Eklöf, Zhangwei Yu, Davood Khodadad, Emil Hällstig, Mikael Sjödahl, and Fredrik Laurell. "Multiwavelength laser designed for single-frame digital holography." Applied Optics 55, no. 27 (September 13, 2016): 7517. http://dx.doi.org/10.1364/ao.55.007517.

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22

Yang, Weifeng, Zhihao Sheng, Xingpan Feng, Miaoli Wu, Zhangjin Chen, and Xiaohong Song. "Molecular photoelectron holography with circularly polarized laser pulses." Optics Express 22, no. 3 (January 29, 2014): 2519. http://dx.doi.org/10.1364/oe.22.002519.

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23

Samson, Benjamin, Frédéric Verpillat, Michel Gross, and Michael Atlan. "Video-rate laser Doppler vibrometry by heterodyne holography." Optics Letters 36, no. 8 (April 14, 2011): 1449. http://dx.doi.org/10.1364/ol.36.001449.

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24

Badalyan, A. M., B. V. Bondarev, Valerii I. Donin, and T. T. Timofeev. "High-power argon laser for use in holography." Soviet Journal of Quantum Electronics 16, no. 9 (September 30, 1986): 1260–62. http://dx.doi.org/10.1070/qe1986v016n09abeh007483.

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25

Wachulak, P. W., M. C. Marconi, R. A. Bartels, C. S. Menoni, and J. J. Rocca. "Soft x-ray laser holography with wavelength resolution." Journal of the Optical Society of America B 25, no. 11 (October 13, 2008): 1811. http://dx.doi.org/10.1364/josab.25.001811.

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26

Barbosa, E. A., and J. F. Carvalho. "Surface analysis by two-diode laser photorefractive holography." Applied Physics B 87, no. 3 (March 24, 2007): 417–23. http://dx.doi.org/10.1007/s00340-007-2614-x.

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27

Meng, Pu Hui, Da Yong Wang, and Yun Xin Wang. "Short-Coherence Light Source Digital Holography Imaging Using Light-Emitting Diodes." Advanced Materials Research 718-720 (July 2013): 2281–85. http://dx.doi.org/10.4028/www.scientific.net/amr.718-720.2281.

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Light-emitting diode (LED) is a kind of short-coherence light source, and it can generate time gating effect and reduce the speckle noises in digital holography. Meanwhile, it can cut down the cost of the setup since LED is cheaper than laser. In this paper, an in-line digital holography setup was designed with LED, and the holograms were reconstructed by four-step phase shifting method. Comparing with the phase image obtained by the laser-based setup, results show that the phase image of USAF test target possesses lower speckle noises with the help of LED. Finally, we reconstruct a series of intensity images with different depths of a coin, and these images are fused to get a synthesized image with more information.
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28

McLeod, RA, P. Jacquemin, S. Lai, and RA Herring. "Confocal Scanning Laser Holography: A Tool for Non-Invasive Internal Measurement." Microscopy Today 13, no. 1 (January 2005): 30–31. http://dx.doi.org/10.1017/s1551929500050835.

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Confocal Holography is a combination of two well known concepts: confocal microscopy and light (laser) holography. Confocal microscopy places an aperture at a conjugate focus to the specimen focus. This filters any rays that are not on the focus plane, allowing a 3-dimensional image of the specimen to be built up over a set of planes.Holography is the measurement of both the amplitude and phase characteristics of light. Typically most methods only measure the amplitude of the image. The phenomenon of interference allows the determination of the phase shift for a coherent source as well. The phase information is directly related to the index of refraction of a material, which in turn is a function of the temperature and composition.
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29

Adinda-Ougba, A., N. Koukourakis, N. C. Gerhardt, and M. R. Hofmann. "Simple concept for a wide-field lensless digital holographic microscope using a laser diode." Current Directions in Biomedical Engineering 1, no. 1 (September 1, 2015): 261–64. http://dx.doi.org/10.1515/cdbme-2015-0065.

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AbstractWide-field, lensless digital holographic microscopy is a new microscopic imaging technique for telemedicine and for resource limited setting [1]. In this contribution we propose a very simple wide-field lensless digital holographic microscope using a laser diode. It is based on in-line digital holography which is capable to provide amplitude and phase images of a sample resulting from numerical reconstruction. The numerical reconstruction consists of the angular spectrum propagation method together with a phase retrieval algorithm. Amplitude and phase images of the sample with a resolution of ∽2 µm and with ∽24 mm2 field of view are obtained. We evaluate our setup by imaging first the 1951 USAF resolution test chart to verify the resolution. Second, we record holograms of blood smear and diatoms. The individual specimen can be easily identified after the numerical reconstruction. Our system is a very simple, compact and low-cost possibility of realizing a microscope capable of imaging biological samples. The availability of the phase provide topographic information of the sample extending the application of this system to be not only for biological sample but also for transparent microstructure. It is suitable for fault detection, shape and roughness measurements of these structures.
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30

Tanji, T., K. Urata, and K. Ishizuka. "High-resolution electron holography of MgO." Proceedings, annual meeting, Electron Microscopy Society of America 49 (August 1991): 672–73. http://dx.doi.org/10.1017/s0424820100087677.

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Electron holography is a useful application of a transmission electron microscope instrument equipped with a field emission gun (FE-TEM). The peculiarity of holography is ability to record and reconstruct the complex amplitude of an electron wave function. This characteristic makes many kinds of image processing applicable, for instance, image restoration and interferometry. Especially the correction of aberrations is expected to overcome the resolution limit owing to the spherical aberration of an electron objective lens. A few preliminary works have been reported, where a laser optical system or a digital computer system was used to reconstruct image waves and to correct the aberrations. The image qualities, however, were not enough to improve the point resolution.
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31

NISHIDA, Kouji, Takafumi NANBA, Hiroshige FUJIO, Yasuo MINAMI, and Toshio HONDA. "Rapid Detection of Tooth Form Deviation by Laser Holography." Proceedings of the JSME annual meeting 2002.5 (2002): 13–14. http://dx.doi.org/10.1299/jsmemecjo.2002.5.0_13.

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32

Guo, Yiming, Yu Wang, Qinglei Hu, Xiaohua Lv, and Shaoqun Zeng. "High-resolution femtosecond laser beam shaping via digital holography." Optics Letters 44, no. 4 (February 14, 2019): 987. http://dx.doi.org/10.1364/ol.44.000987.

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33

Werdiger, M., S. Eliezer, Z. Henis, B. Arad, Y. Horovitz, R. Shpitalnik, and S. Maman. "Off-axis holography of laser-induced shock wave targets." Applied Physics Letters 71, no. 2 (July 14, 1997): 211–12. http://dx.doi.org/10.1063/1.120411.

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34

Clark, M., F. Linnane, S. D. Sharples, and M. G. Somekh. "Frequency control in laser ultrasound with computer generated holography." Applied Physics Letters 72, no. 16 (April 20, 1998): 1963–65. http://dx.doi.org/10.1063/1.121235.

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35

Puyo, Leo, Mathias Fink, Michel Paques, Jose Alain Sahel, and Michael Atlan. "Laser Doppler holography reveals retinal blood flow in humans." Journal of Vision 17, no. 15 (December 1, 2017): 30. http://dx.doi.org/10.1167/17.15.30.

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36

Amer, Eynas, Per Gren, and Mikael Sjödahl. "Stimulated laser induced fluorescence holography for imaging fluorescent species." Optics Communications 311 (January 2013): 124–28. http://dx.doi.org/10.1016/j.optcom.2013.08.056.

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37

MASUDA, Mitsuharu, Hidenobu YANO, Hiromitsu KIYOSE, Yoshitomo SATO, Kazuyasu MATSUO, and Terutoshi MURAKAMI. "Liquid Atomization by Supersonic Jet Observed with Laser Holography." Journal of the Visualization Society of Japan 11, Supplement2 (1991): 235–38. http://dx.doi.org/10.3154/jvs.11.supplement2_235.

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38

Robertson, B., C. Godsalve, and M. R. Taghizadeh. "Dichromated gelatin holography: an investigation into laser-induced damage." Applied Optics 32, no. 33 (November 20, 1993): 6587. http://dx.doi.org/10.1364/ao.32.006587.

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39

Puyo, L., M. Paques, M. Fink, J. A. Sahel, and M. Atlan. "In vivo laser Doppler holography of the human retina." Biomedical Optics Express 9, no. 9 (August 6, 2018): 4113. http://dx.doi.org/10.1364/boe.9.004113.

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40

Takahashi, K., Y. Murakami, and Daisuke Shindo. "Charging and Discharging Phenomena in Organic Photoconductors Observed Using Electron Holography." Key Engineering Materials 508 (March 2012): 315–22. http://dx.doi.org/10.4028/www.scientific.net/kem.508.315.

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The Phenomenon of Laser-Induced Discharging in an Organic Photoconductor Sample Was Directly Observed Using Electron Holography and Sophisticated Techniques for In Situ Observations. Mechanical Friction Was Used to Induce Negative Tribocharges on the Surface of the Photoconductor Sample. the Observation of Equipotential Contour Lines (i.e., the Electric Potential Distribution) outside the Specimen Revealed that the Amount of Tribocharges Was Reduced by the Laser Exposure. Computer Simulations of the Equipotential Lines Provided Useful Information for Evaluating the Quantity of Tribocharges.
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41

Liu, Y. J., and X. W. Sun. "Holographic Polymer-Dispersed Liquid Crystals: Materials, Formation, and Applications." Advances in OptoElectronics 2008 (April 27, 2008): 1–52. http://dx.doi.org/10.1155/2008/684349.

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By combining polymer-dispersed liquid crystal (PDLC) and holography, holographic PDLC (H-PDLC) has emerged as a new composite material for switchable or tunable optical devices. Generally, H-PDLC structures are created in a liquid crystal cell filled with polymer-dispersed liquid crystal materials by recording the interference pattern generated by two or more coherent laser beams which is a fast and single-step fabrication. With a relatively ideal phase separation between liquid crystals and polymers, periodic refractive index profile is formed in the cell and thus light can be diffracted. Under a suitable electric field, the light diffraction behavior disappears due to the index matching between liquid crystals and polymers. H-PDLCs show a fast switching time due to the small size of the liquid crystal droplets. So far, H-PDLCs have been applied in many promising applications in photonics, such as flat panel displays, switchable gratings, switchable lasers, switchable microlenses, and switchable photonic crystals. In this paper, we review the current state-of-the-art of H-PDLCs including the materials used to date, the grating formation dynamics and simulations, the optimization of electro-optical properties, the photonic applications, and the issues existed in H-PDLCs.
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42

Liu, Shan, Leszek Mateusz Mazur, Wieslaw Krolikowski, and Yan Sheng. "Nonlinear Volume Holography: Nonlinear Volume Holography in 3D Nonlinear Photonic Crystals (Laser Photonics Rev. 14(11)/2020)." Laser & Photonics Reviews 14, no. 11 (November 2020): 2070064. http://dx.doi.org/10.1002/lpor.202070064.

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43

London, R. A., N. M. Ceglio, D. C. Eder, A. U. Hazi, C. J. Keane, B. J. Macgowan, D. L. Matthews, et al. "The Soft X-Ray Laser Program at Livermore." International Astronomical Union Colloquium 102 (1988): 221. http://dx.doi.org/10.1017/s0252921100107754.

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AbstractWe describe the experiments and supporting theoretical modelling to develop and characterize soft x-ray lasers. The x-ray lasers are created in dense plasmas produced by optical laser irradiation of solid targets with line focussed beams. We use mainly thin foil targets, which upon appropriate illumination, produce rather uniform plasmas. We consider laser schemes pumped by electron collisional excitation and dielectronic recombination in Ne-like and Ni-like ions, and schemes pumped by collisional and radiative recombination following rapid cooling for H-like and Li-like ions.Experimental measurements of the time and space resolved spectra taken both along the lasing axis and at other viewing angles, in addition to data on the angular pattern of x-ray laser radiation and on the absorption and scattering of the optical laser light are presented. These data allow us the determine the characteristics of the plasmas which have been created, as well as the properties of the x-ray lasers, such as the gain coefficients for the inverted transitions, and their spatial and temporal distributions. The modelling includes calculations of the absorption of the optical laser light, the hearing and hydrodynamics of the targets and the evolution of the atomic level populations within the plasma. Transfer of the emitted radiation is calculated, including resonance line trapping, amplification for inverted transitions, and refraction of the x-ray laser beam due to electron density gradients. Results are used to optimize x-ray laser designs before the experiments and to interpret the measured spectra.The latest experimental results from the NOVA laser facility on the performance of several laser schemes and on the use of multilayer mirrors to produce x-ray laser cavities are reported. These results arc compared to the models to test and improve our understanding of the complex physics involved in making x-ray lasers. Based on current experiments, we show how the modelling can be use to design shorter wavelength and more efficient schemes for use in applications such as x-ray holography.
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44

Blotter, Jonathan D., and Shannon Bybee. "Electro-optic holography fringe control using diode laser current modulation." Optics and Lasers in Engineering 41, no. 3 (March 2004): 489–504. http://dx.doi.org/10.1016/s0143-8166(03)00014-9.

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45

Ferri, Lucilla Croce. "Visualization of 3D information with digital holography using laser printers." Computers & Graphics 25, no. 2 (April 2001): 309–21. http://dx.doi.org/10.1016/s0097-8493(00)00133-3.

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46

Nicolas, F., S. Coëtmellec, M. Brunel, and D. Lebrun. "Digital in-line holography with a sub-picosecond laser beam." Optics Communications 268, no. 1 (December 2006): 27–33. http://dx.doi.org/10.1016/j.optcom.2006.06.069.

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47

Lukin, A. V. "The coherent properties of laser sources in interferometry and holography." Journal of Optical Technology 79, no. 3 (March 1, 2012): 194. http://dx.doi.org/10.1364/jot.79.000194.

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48

Donnarumma, Dario, Alexey Brodoline, Daniel Alexandre, and Michel Gross. "Blood flow imaging in zebrafish by laser doppler digital holography." Microscopy Research and Technique 81, no. 2 (May 7, 2016): 153–61. http://dx.doi.org/10.1002/jemt.22678.

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49

TREBES, J. E., S. B. BROWN, E. M. CAMPBELL, D. L. MATTHEWS, D. G. NILSON, G. F. STONE, and D. A. WHELAN. "Demonstration of X-ray Holography with an X-ray Laser." Science 238, no. 4826 (October 23, 1987): 517–19. http://dx.doi.org/10.1126/science.238.4826.517.

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50

Cavan, D. L. "Patterned wafer inspection using laser holography and spatial frequency filtering." Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures 6, no. 6 (November 1988): 1934. http://dx.doi.org/10.1116/1.584136.

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