Your search keyword '"Lan Mu-Jie"' showing total 6 results

1. Effect of irradiation damage on the dark electric properties of single junction GaAs/Ge solar cells

Author

Zhang Yanqing, Sun Chengyue, Hao Ming-Ming, Wu Yiyong, Lan Mu-Jie, Hu Jian-Min, and Yue Long

Subjects

Materials science, business.industry, General Physics and Astronomy, Optoelectronics, Electric properties, Irradiation, business

Abstract

In this paper, the dark electrical properties are studied by measuring the dark current-voltage characteristics of a type of domestic single-junction (SJ) GaAs/Ge solar cell after proton irradiation. Using a double exponential mode for the dark electrical properties of p-n junction, the dark I-V curves of the proton-irradiated SJ cells are mathematically fitted, and there are four kinds of typical parameters, namely serious resistance (Rs), parallel resistance (Rsh), diffusion current (Is1), and recombination current (Is2), which are determined to characterize the irradiation effects. Hence, four parameters such as Rs, Rsh, Is1 and Is2 are significantly changed after proton irradiation, where Rs, Rsh, Is1 increase while Rsh decreases with increasing the displacement damage dose. In addition, R_{s } increases with displacement damage dose, which is unrelated to proton energies. Theoretical analysis indicates that the above-mentioned changes of the parameters result from the damage distributions in different regions of the solar cells. Irradiation-induced damage in the base and emitter regions of the cells could induce Rs and Is1 to augment, while junction-region damage causes the Rsh to decrease but the Is2 to increase.

Published

2014

2. Radiation damage induced by various particles on CC4013 devices

Author

Lan Mu-Jie, Li Xing-Ji, He Shi-Yu, Sun Zhong-Liang, Xiao Li-Yi, and Liu Chao-Ming

Subjects

Materials science, Nuclear Theory, Radiation damage, Physics::Accelerator Physics, General Physics and Astronomy, Composite material, Nuclear Experiment

Abstract

During serving in orbit, spacecraft will be affected by the radiation environment of the space high-energy charged particles, leading to the performance degradation or even malfunctions of electronic components. The complementary metal oxide semiconductor (CMOS) devices are sensitive to ionization damage. Therefore, it is valuable to research the mechanism of radiation effects on CMOS devices, and is significant to engineering and theory. The CC4013 CMOS integrated circuits are irradiated with 60 MeV Br ions, 5 MeV protons and 1 MeV electrons. Based on the data calculated by Geant4 code, the ionizing absorbed dose induced by 60 MeV Br ions is greatest, and the ionizing absorbed dose induced by 1 MeV electrons is lowest. The degradation of CC4013 device during the irradiation test is in-situ measured with Keithley 4200-SCS semiconductor characteristic system. From the experimental results, the threshold voltage degradation in CC4013 under an exposure of 1 MeV electrons is greatest at the same dose, a little lower under 5 MeV protons, and lowest under 60 MeV Br ions.

Published

2013

3. The influence of bias conditions on ionizing radiation damage of NPN and PNP transistors

Author

Sun Zhong-Liang, Liu Chao-Ming, Lan Mu-Jie, He Shi-Yu, Li Xing-Ji, Xiao Li-Yi, and Yang Jian-Qun

Subjects

Materials science, business.industry, law, Transistor, General Physics and Astronomy, Optoelectronics, business, Ionizing radiation, law.invention

Abstract

Bipolar junction transistors (BJTs), as important electronic components in analog or mixed-signal integrated circuits (ICs) and BiCMOS (Bipolar Complementary Metal Oxide Semiconductor) circuits, are employed in the space environment. Therefore, the research on characteristics and mechanisms of ionization damage in the BJTs is very important. Lower energy electrons are used as irradiation source to study the ionization damage in NPN and PNP transistors. Various bias conditions are imposed on the emitter-base junction to reveal the different bias conditions that contribute to the radiation effect on NPN and PNP transistors during irradiation processing. The semiconductor parameter analyzer, Keithley 4200-SCS, is used to measure the change of electrical parameters of transistors with increasing electron irradiation fluence in situ. Based on the measurement results, we find the degradation of transistors is severe under reverse emitter-base bias, and is lowest under forward emitter-base bias, while it is medium under zero emitter-base bias at a given irradiation fluence.

Published

2013

4. Radiation damage of space GaAs/Ge solar cells evaluated by displacement damage dose

Author

Zhang Zhong-Wei, Lan Mu-Jie, Xiao Jingdong, Wang Xun-Chun, Chen Mingbo, Wu Yiyong, Yue Long, He Shi-Yu, Hu Jian-Min, Qian Yong, and Yang Dezhuang

Subjects

Materials science, law, Electromagnetic shielding, Solar cell, Radiation damage, General Physics and Astronomy, Degradation (geology), Irradiation, Electron, Atomic physics, Displacement (vector), Charged particle, law.invention

Abstract

In this paper,the degradation of irradiated GaAs/Ge single junction (SJ) solar cells is evaluated under the orbital environments using the displacement damage dose method. Firstly the electric-property changes of the SJ solar cells are experimentally obtained with the fluencies of electrons and protons of various energies under ground-based irradiation simulators. Based on the experimenal results and the calculated non-ionization energy losses (NIELs) of the electrons and protons in GaAs, the equivalent exponent n is obtained to be 1.7 for various electron energies,while the equivalent coefficient Rep for electron displacement damage converted into that of protons is 5.2. Furthermore, a degradation formula of the electrical property of the domestic SJ solar cell is established as a function of displacement damage dose during the particle irradiation. Using the displacement damage technique, the orbital evolution of the electric property degradation of the domestic SJ cell is predicted in this paper. In the meantime, the shielding effects of the cover glass with different thicknesses are also evaluated.

Published

2011

5. Degradation mechanisms of current gain in NPN transistors

Author

He Shi-Yu, Yang Dezhuang, Lan Mu-Jie, Geng Hong-bin, Liu Chao-Ming, and Li Xing-Ji

Subjects

Materials science, business.industry, Transistor, General Physics and Astronomy, Electron, Charged particle, Ion, Ionizing radiation, law.invention, law, Ionization, Radiation damage, Optoelectronics, Irradiation, Atomic physics, business

Abstract

An investigation of ionization and displacement damage in silicon NPN bipolar junction transistors (BJTs) is presented. The transistors were irradiated separately with 90-keV electrons, 3-MeV protons and 40-MeV Br ions. Key parameters were measured in-situ and the change in current gain of the NPN BJTS was obtained at a fixed collector current (Ic = 1 mA). To characterise the radiation damage of NPN BJTs, the ionizing dose Di and displacement dose Dd as functions of chip depth in the NPN BJTs were calculated using the SRIM and Geant4 code for protons, electrons and Br ions, respectively. Based on the discussion of the radiation damage equation for current gain, it is clear that the current gain degradation of the NPN BJTs is sensitive to both ionization and displacement damage. The degradation mechanism of the current gain is related to the ratio of Dd/(Dd + Di) in the sensitive region given by charged particles. The irradiation particles leading to lower Dd/(Dd + Di) within the same chip depth at a given total dose would mainly produce ionization damage to the NPN BJTs. On the other hand, the charged particles causing larger Dd/(Dd + Di) at a given total dose would tend to generate displacement damage to the NPN BJTs. The Messenger–Spratt equation could be used to describe the experimental data for the latter case.

Published

2010

6. Degradation mechanisms of current gain in NPN transistors.

Author

Li Xing-Ji, Geng Hong-Bin, Lan Mu-Jie, Yang De-Zhuang, He Shi-Yu, and Liu Chao-Ming

Subjects

TRANSISTORS, BIPOLAR transistors, ELECTRONS, PARAMETER estimation, PHYSICS experiments, IONIZATION (Atomic physics), PROTONS, PARTICLES

Abstract

An investigation of ionization and displacement damage in silicon NPN bipolar junction transistors (BJTs) is presented. The transistors were irradiated separately with 90-keV electrons, 3-MeV protons and 40-MeV Br ions. Key parameters were measured in-situ and the change in current gain of the NPN BJTS was obtained at a fixed collector current (Ic = 1 mA). To characterise the radiation damage of NPN BJTs, the ionizing dose Di and displacement dose Dd as functions of chip depth in the NPN BJTs were calculated using the SRIM and Geant4 code for protons, electrons and Br ions, respectively. Based on the discussion of the radiation damage equation for current gain, it is clear that the current gain degradation of the NPN BJTs is sensitive to both ionization and displacement damage. The degradation mechanism of the current gain is related to the ratio of Dd/(Dd +Di) in the sensitive region given by charged particles. The irraDiation particles leaDing to lower Dd/(Dd +Di) within the same chip depth at a given total dose would mainly produce ionization damage to the NPN BJTs. On the other hand, the charged particles causing larger Dd/(Dd + Di) at a given total dose would tend to generate Displacement damage to the NPN BJTs. The Messenger-Spratt equation could be used to describe the experimental data for the latter case. [ABSTRACT FROM AUTHOR]

Published

2010