电工理论与新技术

学术身份

中国电机工程学会电工理论与新技术专业委员会委员，中国计算物理学会蒙特卡罗专业委员会委员，中国电源学会电磁兼容专业委员会委员，山东电机工程学会电工理论与新技术专业委员会主任委员。

工作经历

个人信息

姓名：谭震宇

性别：男

出生日期：1957.11

籍贯:贵州黔西

职称：教授

职务

电话：

0531-88392806

Email：

tzy@sdu.edu.cn

1982.1毕业于贵州工学院工业自动化专业，获学士学位；1987.7毕业于山东工业大学工业自动化专业，获硕士学位；2004.6山东大学信息科学与技术学院光学工程专业博士研究生毕业，获博士学位；1987.7~，在山东大学电气工程学院从事教学和科研工作，1992年晋升为副教授，1995年晋升为教授，2004年聘为博士生导师。

研究方向

电磁辐射与生物材料相互作用及辐射生物效应，放电等离子体机理及应用，电磁兼容

学术著作

近年来发表的研究论文：

1.Xiaotong Li, Zhenyu Tan, Xiaolong Wang et al., Evolution of the Discharge Mode from Chaos to an Inverse Period-doubling Bifurcation in an Atmospheric-pressure He/N₂ Dielectric Barrier Discharge in Increasing Nitrogen Content. IEEE Transactions on plasma science 2022, 50(3): 619–634.

2.Zihan Diao, Zhenyu Tan, Changqing Lu et al., Behavior of electrons in the bullet in the Ar/O₂ plasma jet in changing oxygen concentration and the applied voltage. IEEE Transactions on plasma science 2021, 49(9): 2642–2652.

3.Yufan Shi, Zhenyu Tan, Xinxian Chen et al., Investigation on the behavior of electrons in the bullet as well as its dependence on applied voltage and H₂O concentration in the atmospheric-pressure Ar/H₂O plasma jets. IEEE Transactions on plasma science 2021, 49(4): 1311–1322.

4.Xiaotong Li, Zhenyu Tan, Xiaolong Wang et al., Mechanism governing the dependence of temporal nonlinear behavior on the gap width in atmospheric-pressure helium dielectric barrier discharge—role of residual charged particles. IEEE Transactions on plasma science 2021, 49(4): 1278–1292.

5.Xiaolong Wang, Zhenyu Tan, Wei Lin et al., A comparative investigation on the behaviors of electrons in the plasma bullets in atmospheric-pressure argon and helium plasma jets. IEEE Transactions on plasma science 2020, 48(11): 3768–3775.

6.Xiaolong Wang, Zhenyu Tan, Jiaqi Han, et al., Numerical investigation on electron effects in the mass transfer of the plasma species in aqueous solution. Plasma Science and Technology 2020, 22(11): 115504.

7.Changqing Lu, Zhenyu Tan, Xinxian Chen, et al., A numerical investigation on the behavior of electrons in the bullet in the atmospheric pressure argon plasma jet. IEEE Transactions on plasma science 2020, 48(9): 2987–2995.

8.Xiaotong Li, Zhenyu Tan, Xiaolong Wang et al., Investigation on the frequency dependence of the correlation between discharge current and gap voltage in helium dielectric barrier discharges at atmospheric pressure. IEEE Transactions on plasma science 2020, 48(6): 2060–2074.

9.Yadi Liu, Zhenyu Tan, Xiaolong Wang et al., A numerical investigation on the reactive species generation and its correlation with electron energy in atmospheric-pressure helium/humid air plasma jets. IEEE Transactions on plasma science 2020, 48(4): 1001–1007.

10.Wei Lin, Zhenyu Tan, Xinxian Chen et al., Energy spectrum of electrons in the plasma bullet and its applied voltage effect in atmospheric pressure argon plasma jets. IEEE Transactions on plasma science 2020, 48(4): 991–1000.

11.Yadi Liu, Zhenyu Tan, Xiaolong Wang et al., Investigation on the effects of the operating conditions on electron energy in the atmospheric-pressure helium plasma jet. Physics of Plasmas 2019, 26: 043506–1–11.

12.Yun Qi, Zhenyu Tan, Qiang Huang et al., An implementation of complete flux scheme in 1-D fluid model for the pulsed DBD at atmospheric pressure. IEEE Transactions on plasma science 2019, 47(3): 1553–1561.

13.Yadi Liu, Zhenyu Tan, Xinxian Chen et al., A numerical investigation on the effects of water vapor on electron energy and OH production in atmospheric-pressure He/H2O and Ar/H2O plasma jets. IEEE Transactions on plasma science 2019, 47(3): 1593–1604.

14.Xinxian Chen, Zhenyu Tan, Yadi Liu et al., Effects of oxygen concentration on the electron energy distribution function in atmospheric pressure helium/oxygen and argon/oxygen needle electrode plasmas. J Phys. D: Appl. Phys. 2018, 51(37): 375202–1–9.

15.Yadi Liu, Zhenyu Tan, Xinxian Chen et al., An investigation of the control of electron energy in the atmospheric-pressure helium plasma jet. IEEE Transactions on plasma science 2018, 46(8): 2865–2880.

16.Wei Liu, Zhenyu Tan, Liming Zhang et al., Investigation on the correlation between energy deposition and clustered DNA damage induced by low-energy electrons. Radiat. Environ. Biophys. 2018, 57(2): 179–187.

17.Xinxian Chen, Zhenyu Tan, Yadi Liu et al., Effects of gap distance and working gas on energy spectra of electrons in atmospheric pressure plasma jets. Physics of Plasmas 2018, 25, 033517–1–7.

18.Yadi Liu, Zhenyu Tan, Xinxian Chen et al., An investigation on the effects of air on electron energy in atmospheric pressure helium plasma jets. Physics of Plasmas 2018, 25, 033514–1–11.

19.Xinxian Chen, Zhenyu Tan, Yadi Liu et al., Investigation on the energy spectrums of electrons in atmospheric pressure argon plasma jets and their dependences on the applied voltage. Physics of Plasmas 2017, 24: 083509–1–7.

20.Wei Liu, Zhenyu Tan, Liming Zhang et al., Calculation on spectrum of direct DNA damage induced by low-energy electrons including dissociative electron attachment. Radiat. Environ. Biophys. 2017, 56(1): 99–110.

21.Jixiang Jiang, Zhenyu Tan, Chunhong Shan et al., A new study on the penetration of reactive species in their mass transfer processes in water by increasing the electron energy in plasmas. Physics of Plasmas 2016, 23: 103503–1–10.

22.Liu Wei, Tan Zhenyu, Christophe Champion, A new simulation of track structure of low-energy electrons in liquid water: considering the condensed-phase effect on electron elastic scattering. Chin. Phys. Lett. 2016, 33(9): 093401–1–4.

23.Jie Pan, Zhenyu Tan, Guangsheng Pan et al., Investigation on the Reaction Mechanisms of Generation and Loss of Oxygen-Related Species in Atmospheric-Pressure Pulsed Dielectric Barrier Discharge in Argon/Oxygen Mixture. Physics of Plasmas 2016, 23: 073520–1–6.

24.Wang Xiaolong, Tan Zhenyu, Pan Jie et al., Effects of oxygen concentration on pulsed dielectric barrier discharge in Helium–Oxygen mixture at atmospheric pressure. Plasma Science and Technology 2016, 18(8): 839–843.

25.Guangsheng Pan, Zhenyu Tan, Jie Pan et al., A Comparative Study on the Frequency Effects of the Electrical Characteristics of the Pulsed Dielectric Barrier Discharge in He/O2 and in Ar/O2 at Atmospheric Pressure. Physics of Plasmas 2016, 23:043508–1–10.

26.Jie Pan, Zhenyu Tan, Yadi Liu et al., Effects of Oxygen Concentration on Atmospheric-Pressure Pulsed Dielectric Barrier Discharges in Argon/Oxygen Mixture. Physics of Plasmas 2015, 22: 093515–1–8.

27.Lei Dong, Zhenyu Tan, Fule Tang et al., Study of the effects of SiC filler on the internal charging of LDPE in space environment. Advances in Space Research 2015, 55(9): 2346–2351.

28.Jie Pan, Zhenyu Tan, Xiaolong Wang et al., Comparative study of pulsed dielectric barrier discharges in argon and nitrogen at atmospheric pressure. IEEE Transactions on plasma science 2015, 43(2): 557–566.

29.Jie Pan, Zhenyu Tan, Xiaolong Wang et al., Effects of pulse parameters on the atmospheric-pressure dielectric barrier discharges driven by the high-voltage pulses in Ar and N2. Plasma Sources Science and Technology 2014, 23(9): 065019–1–11.

30.Xiaolong Wang, Zhenyu Tan, Lanlan Nie et al., Study on modes of the pulsed dielectric barrier discharges at atmospheric pressure in helium. IEEE Transactions on plasma science 2014, 42(9): 2245–2252.

31.Mingming Xu, Zhenyu Tan, Calculation of Townsend second ionization coefficient for photoemission at different humidities. IEEE Transactions on Dielectrics and Electrical Insulation 2014, 21(4): 1764–1767.

32.Zhenyu Tan, Wei Liu, Monte Carlo calculations of energy deposition distributions of electrons below 20 keV in protein. Radiat. Environ. Biophys. 2014, 53(2):427–435.

33.Zhenyu Tan, Wei Liu, Calculations of stopping powers and inelastic mean free paths for 20 eV–20 keV electrons in 11 types of human tissue. Appl. Radiat. and Isotopes 2013, 82: 325–331.

34.Song Xinxin, Tan Zhenyu, Bo Chen et al., A Computational Study on the Discharge Characteristics of Atmospheric Dielectric Barrier Discharges at a Constant Power. Plasma Science and Technology 2013, 15(10): 1025–1030.

35.Lanlan Nie, Zhenyu Tan, Bo Chen et al., Effects of Frequency on the Electrical Characteristic of Pulse Discharges in Atmospheric Pressure Pure Helium. IEEE Transaction on plasma science 2013, 41(6): 1648–1657.

36.Song Xinxin, Tan Zhenyu, Bo Chen et al., Study on the Characteristics of Atmospheric Dielectric Barrier Discharges in He−N2 Admixture. IEEE Transaction on plasma science 2012, 40(12): 3471 –3475.

37.Song Xinxin, Tan Zhenyu, Bo Chen et al., Evolution of the Pulse Width in Dielectric Barrier Atmospheric Pressure Discharge. Plasma Science and Technology 2012, 14(9): 808–811.

38.Mingming Xu, Zhenyu Tan, Kejun Li et al., Modified Peek formula for calculating positive DC corona inception electric field under variable humidity. IEEE Transactions on Dielectrics and Electrical Insulation 2012, 19(4): 1377–1382.

39.Zhenyu Tan, Lei Dong, Fule Tang, Monte Carlo calculations of characteristic quantities of low-energy electron irradiation to spacecraft dielectrics. Nucl. Instr. and Meth. B 2012, 285: 86–93.

40.Bo Chen, Zhenyu Tan, Xinxin Song, Study on multi-peak behavior of pulsed dielectric barrier discharges in atmospheric-pressure helium. Vacuum 2012, 86(12): 1992–1997.

41.Bo Chen, Zhenyu Tan, Xinxin Song et al., Effects of the Operating Conditions on the Electrical Characteristics of Pulse Discharges in Atmospheric-Pressure Pure Helium. IEEE Transaction on plasma science 2012, 40(4): 1003 –1009.

42.Zhenyu Tan, Yueyuan Xia, Stopping power and mean free path for low energy electrons in ten scintillators over energy range of 20-20 000 eV. Appl. Radiat. and Isotopes 2012, 70(1): 296–300.

43.Bo Chen, Zhenyu Tan, Xinxin Song et al., Characteristics of atmospheric-pressure helium barrier pulse discharges. IEEE Transaction on plasma science 2011, 39(10): 1949 –1957.

44.Zhenyu Tan, Yueyuan Xia, Evaluations of proton inelastic mean free paths for 12 elemental solids over the energy range from 0.05 to 10 MeV. Nucl. Instr. and Meth. B 2011, 269(3): 328–335.

45.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Proton inelastic mean free path in a group of organic materials in 0.05–10 MeV range. Chin. Phys. Lett. 2010, 27(11): 113403–1–4.

46.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al., Proton inelastic mean free path in amino acids and protein over the energy range of 0.05-10 MeV. Nucl. Instr. and Meth. B 2010, 268(17-18): 2606–2610.

47.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Proton inelastic mean free path in a group of bioorganic compounds and water in 0.05-10 MeV range ¾ Including higher-order corrections. Nucl. Instr. and Meth. B 2010, 268(14): 2337–2342.

48.Dingju Jiang, Zhenyu Tan, A Monte Carlo study of low-energy electron transport in liquid water: the influence of the Rutherford formula and the Mott model. Chin. Phys. Lett. 2010, 27(3): 033401–1–4.

49.Liming Zhang, Zhenyu Tan, A new calculation on spectrum of direct DNA damage induced by low-energy electrons. Radiat. Environ. Biophys. 2010, 49(1): 15–26.

50.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al., A new calculation on the stopping power and mean free path for low energy electrons in toluene over energy range of 20-10 000 eV. Appl. Radiat. and Isotopes 2009, 67(4): 625-629.

51.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Electronic stopping power for proton in amino acids and protein in 0.05-10 MeV range. Nucl. Instr. and Meth. B, 2008, 266(9): 1938-1942.

52.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al., Electronic stopping power for proton in a group of organic materials in 0.05-10 MeV range. Chin. Phys. Lett. 2008, 25(6): 2023-2026.

53.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Electron stopping power and inelastic mean free path in amino acids and protein over the energy range of 20-20000 eV. Radiat. Environ. Biophys. 2006, 45(2): 135-143.

54.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Proton stopping power in a group of bioorganic compounds over the energy range of 0.05-10 MeV. Nucl. Instr. and Meth. B 2006, 248(1):1-6.

55.Tan Zhen-Yu, Xia Yue-Yuan, Zhao Ming-Wen et al., Monte Carlo simulation on energy deposition of low-energy electrons in liquid water. Chin. Phys. Lett. 2005, 22(1): 91-94.

56.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al, Electron inelastic interactions in bioorganic compounds in the energy range of 20-10000 eV. Appl. Phys. A 2005, 81(4):779-786.

57.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Monte Carlo simulation of interactions between energetic electron and cellulose film. Applied Surface Science 2005, 246(1-3): 117-125.

58.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al., Monte Carlo simulation of low-energy electron scattering in PMMA - using stopping powers from dielectric formalism. Microelectronic Engineering 2005, 77(3-4): 285-291.

59.Zhenyu Tan, Yueyuan Xia, Xiangdong Liu et al., Cross sections of electron inelastic interactions in DNA. Radiat. Environ. Biophys. 2004, 43(3): 173-182.

60.Zhenyu Tan, Yueyuan Xia, Mingwen Zhao et al., Electron stopping power and mean free path in organic compounds over the energy range of 20-10000 eV. Nucl. Instr. and Meth. B 2004, 222(1-2): 27-43.

61.Tan Zhen-Yu, Xia Yue-Yuan, Stopping powers of energetic electrons penetrating condensed matter-theory and application. Nuclear Science and Techniques 2004, 15: 200-212.

承担科研项目

先后承担国家自然科学基金、博士点基金、省部级基金等多项研究项目

学术类型