Your search keyword '"Kotaro Kondo"' showing total 6 results

1. High-Thermal-Conductivity SiC Ceramic Mirror for High-Average-Power Laser System

Author

Yasuhiro Miyasaka, Kotaro Kondo, and Hiromitsu Kiriyama

Subjects

silicon carbide ceramics, high-average-power laser, optics, thermal conductivity, Crystallography, QD901-999

Abstract

The importance of heat-resistant optics is increasing together with the average power of high-intensity lasers. A silicon carbide (SiC) ceramic with high thermal conductivity is proposed as an optics substrate to suppress thermal effects. The temperature rise of the substrate and the change in the surface accuracy of the mirror surface, which degrades the laser beam quality, are investigated. Gold mirrors on synthetic fused silica and SiC ceramic substrates are heated with a 532 nm wavelength laser diode. The synthetic fused silica substrate placed on an aluminum block shows a temperature increase by ~32 °C and a large temperature gradient. In contrast, the SiC ceramic substrate shows a uniform temperature distribution and a temperature increase of only ~4 °C with an absorbed power of ~2 W after 20 min laser irradiation. The surface accuracy (roughness) when using the synthetic fused silica substrate changes from /21.8 (29.0 nm) to /7.2 (88.0 nm), increasing by a factor of ~3.0. However, that of the SiC ceramic substrate changes from /21.0 (30.2 nm) to /13.3 (47.7 nm), increasing by only a factor of ~1.6. Based on these experimental results, detailed considerations and calculations of actively cooled SiC ceramic substrates for high-average-power laser systems are also discussed.

Published

2020

2. High-Intensity Laser-Driven Oxygen Source from CW Laser-Heated Titanium Tape Targets

Author

Kotaro Kondo, Mamiko Nishiuchi, Hironao Sakaki, Nicholas P. Dover, Hazel F. Lowe, Takumi Miyahara, Yukinobu Watanabe, Tim Ziegler, Karl Zeil, Ulrich Schramm, Emma J. Ditter, George S. Hicks, Oliver C. Ettlinger, Zulfikar Najmudin, Hiromitsu Kiriyama, Masaki Kando, and Kiminori Kondo

Subjects

Ti Sapphire laser, high-power laser, laser-driven heavy ion acceleration, surface treatment, CW laser heating, oxygen ion source, Crystallography, QD901-999

Abstract

The interaction of high-intensity laser pulses with solid targets can be used as a highly charged, energetic heavy ion source. Normally, intrinsic contaminants on the target surface suppress the performance of heavy ion acceleration from a high-intensity laser–target interaction, resulting in preferential proton acceleration. Here, we demonstrate that CW laser heating of 5 µm titanium tape targets can remove contaminant hydrocarbons in order to expose a thin oxide layer on the metal surface, ideal for the generation of energetic oxygen beams. This is demonstrated by irradiating the heated targets with a PW class high-power laser at an intensity of 5 × 1021 W/cm2, showing enhanced acceleration of oxygen ions with a non-thermal-like distribution. Our new scheme using a CW laser-heated Ti tape target is promising for use as a moderate repetition energetic oxygen ion source for future applications.

Published

2020

3. Petawatt Femtosecond Laser Pulses from Titanium-Doped Sapphire Crystal

Author

Hiromitsu Kiriyama, Alexander S. Pirozhkov, Mamiko Nishiuchi, Yuji Fukuda, Akito Sagisaka, Akira Kon, Yasuhiro Miyasaka, Koichi Ogura, Nicholas P. Dover, Kotaro Kondo, Hironao Sakaki, James K. Koga, Timur Zh. Esirkepov, Kai Huang, Nobuhiko Nakanii, Masaki Kando, Kiminori Kondo, Stefan Bock, Tim Ziegler, Thomas Püschel, Karl Zeil, and Ulrich Schramm

Subjects

chirped-pulse amplification, ultra-fast laser, ultra-high intensity laser, Ti:sapphire laser, high field science, Crystallography, QD901-999

Abstract

Ultra-high intensity femtosecond lasers have now become excellent scientific tools for the study of extreme material states in small-scale laboratory settings. The invention of chirped-pulse amplification (CPA) combined with titanium-doped sapphire (Ti:sapphire) crystals have enabled realization of such lasers. The pursuit of ultra-high intensity science and applications is driving worldwide development of new capabilities. A petawatt (PW = 1015 W), femtosecond (fs = 10−15 s), repetitive (0.1 Hz), high beam quality J-KAREN-P (Japan Kansai Advanced Relativistic ENgineering Petawatt) Ti:sapphire CPA laser has been recently constructed and used for accelerating charged particles (ions and electrons) and generating coherent and incoherent ultra-short-pulse, high-energy photon (X-ray) radiation. Ultra-high intensities of 1022 W/cm2 with high temporal contrast of 10−12 and a minimal number of pre-pulses on target has been demonstrated with the J-KAREN-P laser. Here, worldwide ultra-high intensity laser development is summarized, the output performance and spatiotemporal quality improvement of the J-KAREN-P laser are described, and some experimental results are briefly introduced.

Published

2020

4. Petawatt Femtosecond Laser Pulses from Titanium-Doped Sapphire Crystal

Author

Ulrich Schramm, Tim Ziegler, Mamiko Nishiuchi, Masaki Kando, Kiminori Kondo, Alexander S. Pirozhkov, Koichi Ogura, Kotaro Kondo, Akito Sagisaka, Karl Zeil, Yasuhiro Miyasaka, Kai Huang, Thomas Püschel, Nobuhiko Nakanii, Stefan Bock, Timur Zh. Esirkepov, Yuji Fukuda, James K. Koga, Hironao Sakaki, Akira Kon, Nicholas P. Dover, and Hiromitsu Kiriyama

Subjects

Chirped pulse amplification, Materials science, Photon, ultra-fast laser, General Chemical Engineering, Physics::Optics, Ti:sapphire laser, 01 natural sciences, law.invention, 010309 optics, Inorganic Chemistry, law, 0103 physical sciences, lcsh:QD901-999, General Materials Science, 010306 general physics, chirped-pulse amplification, ultra-high intensity laser, business.industry, Condensed Matter Physics, Laser, Charged particle, Femtosecond, Sapphire, Optoelectronics, Laser beam quality, lcsh:Crystallography, high field science, business

Abstract

Ultra-high intensity femtosecond lasers have now become excellent scientific tools for the study of extreme material states in small-scale laboratory settings. The invention of chirped-pulse amplification (CPA) combined with titanium-doped sapphire (Ti:sapphire) crystals have enabled realization of such lasers. The pursuit of ultra-high intensity science and applications is driving worldwide development of new capabilities. A petawatt (PW = 1015 W), femtosecond (fs = 10&minus, 15 s), repetitive (0.1 Hz), high beam quality J-KAREN-P (Japan Kansai Advanced Relativistic ENgineering Petawatt) Ti:sapphire CPA laser has been recently constructed and used for accelerating charged particles (ions and electrons) and generating coherent and incoherent ultra-short-pulse, high-energy photon (X-ray) radiation. Ultra-high intensities of 1022 W/cm2 with high temporal contrast of 10&minus, 12 and a minimal number of pre-pulses on target has been demonstrated with the J-KAREN-P laser. Here, worldwide ultra-high intensity laser development is summarized, the output performance and spatiotemporal quality improvement of the J-KAREN-P laser are described, and some experimental results are briefly introduced.

Published

2020

5. High-Thermal-Conductivity SiC Ceramic Mirror for High-Average-Power Laser System

Author

Hiromitsu Kiriyama, Kotaro Kondo, and Yasuhiro Miyasaka

Subjects

Materials science, General Chemical Engineering, 02 engineering and technology, Substrate (electronics), 01 natural sciences, law.invention, 010309 optics, Inorganic Chemistry, chemistry.chemical_compound, Thermal conductivity, law, 0103 physical sciences, lcsh:QD901-999, Silicon carbide, thermal conductivity, General Materials Science, Ceramic, high-average-power laser, silicon carbide ceramics, Laser diode, business.industry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Laser, optics, Temperature gradient, chemistry, visual_art, visual_art.visual_art_medium, Optoelectronics, sense organs, lcsh:Crystallography, Laser beam quality, 0210 nano-technology, business

Abstract

The importance of heat-resistant optics is increasing together with the average power of high-intensity lasers. A silicon carbide (SiC) ceramic with high thermal conductivity is proposed as an optics substrate to suppress thermal effects. The temperature rise of the substrate and the change in the surface accuracy of the mirror surface, which degrades the laser beam quality, are investigated. Gold mirrors on synthetic fused silica and SiC ceramic substrates are heated with a 532 nm wavelength laser diode. The synthetic fused silica substrate placed on an aluminum block shows a temperature increase by ~32 &deg, C and a large temperature gradient. In contrast, the SiC ceramic substrate shows a uniform temperature distribution and a temperature increase of only ~4 &deg, C with an absorbed power of ~2 W after 20 min laser irradiation. The surface accuracy (roughness) when using the synthetic fused silica substrate changes from /21.8 (29.0 nm) to /7.2 (88.0 nm), increasing by a factor of ~3.0. However, that of the SiC ceramic substrate changes from /21.0 (30.2 nm) to /13.3 (47.7 nm), increasing by only a factor of ~1.6. Based on these experimental results, detailed considerations and calculations of actively cooled SiC ceramic substrates for high-average-power laser systems are also discussed.

Published

2020

6. High-Intensity Laser-Driven Oxygen Source from CW Laser-Heated Titanium Tape Targets

Author

Kondo, Kotaro, Nishiuchi, Mamiko, Sakaki, Hironao, Dover, NicholasPeter, Lowe, HazelFrances, Miyahara, Takumi, Watanabe, Yukinobu, Ziegler, Tim, Zeil, Karl, Schramm, Ulrich, J. Ditter, Emma, S. Hicks, George, C. Ettlinger, Oliver, Najmudin, Zulfikar, Kiriyama, Hiromitsu, Kando, Masaki, Kondo, Kiminori, Kotaro, Kondo, Mamiko, Nishiuchi, Hironao, Sakaki, Yukinobu, Watanabe, Hiromitsu, Kiriyama, Masaki, Kando, and Kiminori, Kondo

Abstract

The interaction of high-intensity laser pulses with solid targets can be used as a highly charged, energetic heavy ion source. Normally, intrinsic contaminants on the target surface suppress the performance of heavy ion acceleration from a high-intensity laser–target interaction, resulting in preferential proton acceleration. Here, we demonstrate that CW laser heating of 5 μm titanium tape targets can remove contaminant hydrocarbons in order to expose a thin oxide layer on the metal surface, ideal for the generation of energetic oxygen beams. This is demonstrated by irradiating the heated targets with a PW class high-power laser at an intensity of 5 × 10^21 W/cm2, showing enhanced acceleration of oxygen ions with a non-thermal-like distribution. Our new scheme using a CW laser-heated Ti tape target is promising for use as a moderate repetition energetic oxygen ion source for future applications.

Published

2020