• Title/Summary/Keyword: High Energy Photon

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High-Energy Proton Generation with High Energy Conversion Efficiency Driven by Ultrashort High-Intensity Ti:Sapphire Laser (극초단 고출력 티타늄 사파이어 레이저에 의한 높은 에너지 변환효율을 가지는 고에너지 양성자 발생)

  • Choe, Il-U;Yu, Tae-Jun;Seong, Jae-Hui;Kim, Hyeong-Taek;Jeong, Tae-Mun;Hong, Gyeong-Han;Kim, Jeong-Hun;No, Yeong-Cheol;Go, Do-Gyeong;Lee, Jong-Min;Sagisaka, Akito;Yogo, Akifumi;Orimo, Satoshi;Ogura, Koichi;Li, Zhong;Pirozhkov, Alexander;Daido, Hiroyuki;Oishi, Yuji;Nemoto, Koshichi;Nakamura, Shyu;Noda, Akira;Iwashita, Yoshihisa;Shirai, Toshiyuki
    • Proceedings of the Optical Society of Korea Conference
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    • 2006.07a
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    • pp.379-380
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    • 2006
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Development of Laser-driven Proton Source Toward Its Applications

  • Sagisaka, Akito;Daido, Hiroyuki;Pirozhkov, Alexander S.;Yogo, Akifumi;Ogura, Koichi;Orimo, Satoshi;Ma, Jinglong;Mori, Michiaki;Nishiuchi, Mamiko;Bulanov, Sergei V.;Esirkepov, Timur Zh.;Oishi, Yuji;Nayuki, Takuya;Fujii, Takashi;Nemoto, Koshichi;Nagatomo, Hideo
    • Journal of the Optical Society of Korea
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    • v.13 no.1
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    • pp.37-41
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    • 2009
  • We observe the proton signals produced by laser interaction with thin-foil targets of polyimide and of copper. We change the thickness of the polyimide target to $7.5{\mu}m$, $12.5{\mu}m$, and $50{\mu}m$. High-energy protons with the maximum energy of ${\sim}2.3\;MeV$ from $7.5{\mu}m$ thick polyimide are observed. This proton beam with the maximum energy of multi-MeV has various applications such as a proton shadowgraphy.

A Study of Dark Photon at the Electron-Positron Collider Experiments Using KISTI-5 Supercomputer

  • Park, Kihong;Cho, Kihyeon
    • Journal of Astronomy and Space Sciences
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    • v.38 no.1
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    • pp.55-63
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    • 2021
  • The universe is well known to be consists of dark energy, dark matter and the standard model (SM) particles. The dark matter dominates the density of matter in the universe. The dark matter is thought to be linked with dark photon which are hypothetical hidden sector particles similar to photons in electromagnetism but potentially proposed as force carriers. Due to the extremely small cross-section of dark matter, a large amount of data is needed to be processed. Therefore, we need to optimize the central processing unit (CPU) time. In this work, using MadGraph5 as a simulation tool kit, we examined the CPU time, and cross-section of dark matter at the electron-positron collider considering three parameters including the center of mass energy, dark photon mass, and coupling constant. The signal process pertained to a dark photon, which couples only to heavy leptons. We only dealt with the case of dark photon decaying into two muons. We used the simplified model which covers dark matter particles and dark photon particles as well as the SM particles. To compare the CPU time of simulation, one or more cores of the KISTI-5 supercomputer of Nurion Knights Landing and Skylake and a local Linux machine were used. Our results can help optimize high-energy physics software through high-performance computing and enable the users to incorporate parallel processing.

Review of laser-plasma physics research and applications in Korea

  • W. Bang;B. I. Cho;M. H. Cho;M. S. Cho;M. Chung;M. S. Hur;G. Kang;K. Kang;T. Kang;C. Kim;H. N. Kim;J. Kim;K.B. Kim;K. N. Kim;M. Kim;M. S. Kim;M. Kumar;H. Lee;H. W. Lee;K. Lee;I. Nam;S. H. Park;V. Phung;W. J. Ryu;S. Y. Shin;H. S. Song;J. Song;J. Won;H. Suk
    • Journal of the Korean Physical Society
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    • v.80
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    • pp.698-716
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    • 2022
  • Laser plasmas can be produced when high-power laser beams are focused in matter. A focused laser beam of TW(terawatt)-level high power has an extremely strong electric field, so neutral atoms are immediately ionized by the laser electric field, leading to a laser-produced plasma. The laser plasma can be produced by small table-top TW lasers based on the CPA (chirped-pulse amplification) technique, and now they are rather easily available even in university laboratories. In Korea, there are several CPA-based TW (or even petawatt) lasers in a few institutions, and they have been used for diverse laser plasma physics research and applications, including the laser acceleration for electrons and ions, high-power THz (tera-hertz) generation, advanced light sources, high-energy-density plasmas, plasma optics, etc. This paper reviews some of the laser plasma physics research and applications that have been performed in several universities and research institutes.

Irradiant Energy into an Eye from a Flash Light (섬광에 의하여 사람 눈에 입사되는 광 에너지)

  • Park, Seung-Man;Han, Seungoh
    • The Transactions of The Korean Institute of Electrical Engineers
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    • v.65 no.7
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    • pp.1225-1230
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    • 2016
  • Since a flash light produces enormous amount of photon energy in short time, not only electro-optic and infrared(EO/IR) systems utilized for Intelligence Surveillance Target Acquisition and reconnaissance(ISTAR) activities but also the people of a combat field can be severely influenced by a high flash light bursting in front of them. The people who bumped into a flash could not escape such enormous amount of photon energy, resulting in being blind temporarily or even permanently. In order to investigate the effect of a high flash source on a human eye, it is essential to know how much photon energy be incident into an eye from the flash source. In this paper, the model of irradiated photon energy to individuals from some flashes is proposed. The proposed irradiated photon energy per unit area of retina is based on taking the situation to be modeled as a simple EO system in front of a flash light. The validity of proposed model was proved by the application of the model to human on the surface of the earth with the well known light source, the Sun. The model of this study can be utilized to simulate the retinal intensity and energy of a flash for various conditions such as the illumination levels, the distance from a flash busting site, luminous intensity and time of a flash.

Optimization of Energy Modulation Filter for Dual Energy CBCT Using Geant4 Monte-Carlo Simulation

  • Ju, Eun Bin;Ahn, So Hyun;Choi, Sang Gyu;Lee, Rena
    • Progress in Medical Physics
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    • v.27 no.3
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    • pp.125-130
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    • 2016
  • Dual energy computed tomography (DECT) is used to classify two materials and quantify the mass density of each material in the human body. An energy modulation filter based DECT could acquire two images, which are generated by the low- and high-energy photon spectra, in one scan, with one tube and detector. In the case of DECT using the energy modulation filter, the filter should perform the optimization process for the type of materials and thicknesses for generating two photon spectra. In this study, Geant4 Monte-Carlo simulation toolkit was used to execute the optimization process for determining the property of the energy modulation filter. In the process, various materials used for the energy modulation filter are copper (Cu, $8.96g/cm^3$), niobium (Nb, $8.57g/cm^3$), stannum (Sn, $7.31g/cm^3$), gold (Au, $19.32g/cm^3$), and lead (Pb, $11.34g/cm^3$). The thickness of the modulation filter varied from 0.1 mm to 1.0 mm. To evaluate the overlap region of the low- and high-energy spectrum, Geant4 Monte-Carlo simulation is used. The variation of the photon flux and the mean energy of photon spectrum that passes through the energy modulation filter are evaluated. In the primary photon spectrum of 80 kVp, the optimal modulation filter is a 0.1 mm lead filter that can acquire the same mean energy of 140 kVp photon spectrum. The lead filter of 0.1 mm based dual energy CBCT is required to increase the tube current 4.37 times than the original tube current owing to the 77.1% attenuation in the filter.

실리콘 박막 태양전지를 위한 CdSe계 양자점 광변환구조체

  • Sin, Myeong-Hun
    • Proceedings of the Korean Vacuum Society Conference
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    • 2014.02a
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    • pp.135.2-135.2
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    • 2014
  • Photon conversion technology for thin film solar cells is reviewed. The high-energy photons which are hardly absorbed in solar cells can be transformed the low energy photon by the photon conversion process such as down conversion or down shift, which can improve the solar cell efficiency over the material limit. CdSe-based quantum dot materials commonly used in LED can be used as the photon conversion layer for Si thin film solar cells. The photon conversion structure of CdSe-based quantum dot for Si thin film solar cells will be presented and the pros and cons for the Si thin film solar cells integrated with the photon conversion layers will be discussed.

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Selective Graphene Oxide Reduction Utilizing Photon Energy (광에너지를 활용한 선택적 산화그래핀의 환원)

  • Shin, Jae-Soo;Choi, Eunmi
    • Journal of the Semiconductor & Display Technology
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    • v.17 no.4
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    • pp.16-20
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    • 2018
  • Graphene is attracting attention due to its outstanding properties as line material for next-generation semiconductor. Graphene pattern technology is essential to apply graphene line. Selective graphene oxide reduction as one of graphene pattern method does not require a substrate thereby a high flexibility device can be applied. Particularly, the method using photon energy has advantages of short process time and environment friendly. In this review, we introduce the photocatalytic method and the photo-thermal energy conversion method using photon energy in the selective reduction process of graphene oxides.

Enhance photoelectric efficiency of PV by optical-thermal management of nanofilm reflector

  • Liang, Huaxu;Wang, Baisheng;Su, Ronghua;Zhang, Ao;Wang, Fuqiang;Shuai, Yong
    • Advances in nano research
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    • v.13 no.5
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    • pp.475-485
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    • 2022
  • Crystalline silicon photovoltaic cells have advantages of zero pollution, large scale and high reliability. A major challenge is that sunlight wavelength with photon energy lower than semiconductor band gap is converted into heat and increase its temperature and reduce its conversion efficiency. Traditional cooling PV method is using water flowing below the modules to cool down PV temperature. In this paper, the idea is proposed to reduce the temperature of the module and improve the energy conversion efficiency of the module through the modulation of the solar spectrum. A spectrally selective nanofilm reflector located directly on the surface of PV is designed, which can reflect sunlight wavelength with low photon energy, and even enhance absorption of sunlight wavelength with high photon energy. The results indicate that nanofilm reflector can reduce spectral reflectivity integral from 9.0% to 6.93% in 400~1100 nm wavelength range, and improve spectral reflectivity integral from 23.1% to 78.34% in long wavelength range. The nanofilm reflector can reduce temperature of PV by 4.51℃ and relatively improved energy conversion efficiency of PV by 1.25% when solar irradiance is 1000 W/m2. Furthermore, the nanofilm reflector is insensitive in sunlight's angle and polarization state, and be suitable for high irradiance environment.

Electric Permittivity Properties and $ZnO/TiO_2$Thin Film Fabrication ($ZnO/TiO_2$ 박막 제작과 유전율 특성)

  • 김창석;최창주;이우선;오무송;김태성;김병인
    • Proceedings of the Korean Institute of Electrical and Electronic Material Engineers Conference
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    • 2001.07a
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    • pp.290-294
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    • 2001
  • In this study, ZnO is evaporated to be coated on n-type Si wafer substrate. Refractive coefficient of thin film that is evaporating TiO$_2$ onto ZnO increases linearly as thickness is getting thinner to have high value and high angle and it satisfies theoretical equation I(x)=Io exp (-$\alpha$x) theory that represents the strength of photon energy advancing through ZnO thin film. And dielectric constant of TiO$_2$ thin film evaporated onto ZnO is high and $\varepsilon$$_2$ is smaller than $\varepsilon$$_1$. The specimen TiO$_2$ thin film evaporated onto ZnO has much higher dielectric constant when photon energy is increased.

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