LU Jianduo

Professor

Department of Applied Physics

E-MAIL: l_j316@163.com

Educational Background

2009--2012,        Huazhong        University        of        Science        and        Technology,

Physics, Doctor.

2003-2006,        Huazhong        University        of        Science        and        Technology, Physics, Master.

1999-2003, Ludong University, Physics, Bachelor.

Work Experience

2016--Present, professor, Department of Applied Physics, Wuhan University of Science and Technology, China.

2010--2016, Associate Professor, Department of Applied Physics, Wuhan University of Science and Technology, China.

2007--2010,        Lecturer,        Department        of Applied        Physics,        Wuhan University of Science and Technology, China.

2006--2007, Teaching Assistant, Department of Applied Physics, Wuhan University of Science and Technology, China.

Research Field

1.Nano electronic devices and quantum devices

2.Electrical and thermal transport in nanostructure

3.Electronic transport in graphene devices

4.First-principles calculations

5.Spintronics and valleytronics 

Partial Academic Achievements 1 Main Papers:

01.The study of spin- and valley-dependent electron transport properties in silicene modulated by metallic gates, Indian J Phys 2024, https://doi.org/10.1007/s12648-024-03169-5

02.Ultraviolet Photoemission Spectra of Aqueous Thymidine by Liquid-Microjet Photoelectron Spectroscopy: A Combined Experimental Error Assessment, Chinese Journal of Chemical Physics, 2024, 37, 439-448

03.Effect of Ferromagnetic Metal Stripe and Strained Barrier on Electron Transport Characteristics in a Graphene, Journal of

Superconductivity and Novel Magnetism (2022) 35:3363–3369

04.Valley-dependent electronic transport in a graphene-based magnetic-strained superlattice, Journal of Superconductivity and Novel Magnetism(2022) 35:1629-1634

05.Effect of the electrostatic barrier on the valley polarization in a graphene, Arabian Journal for Science and Engineering (2022) 47:903-908

06.Strain-controlled valley polarization in a graphene under the

modulation of a realistic magnetic field, Journal of Superconductivity and Novel Magnetism (2021) 34:2545-2550

07.Enhanced valley polarization in a magnetic-strained graphene under the modulation of the applied bias, Journal of Superconductivity and Novel Magnetism (2021) 34:443-449

08.High-lying Rydberg atoms surviving intense laser fields, PHYSICAL REVIEW A 104, 043115 (2021)

09.The  effect  of  two  ferromagnetic  metal  stripes  on  valley

polarization of electrons in a graphene，Physics Letters A，384 (2020) 126402

10.Dependence of valley polarization on Schottky metal stripe in magnetic-strain graphene, Physics Letters A, 383 (2019) 3001-3004

11.Valley-dependent transport properties of electrons in a graphene with magnetic field and strained barrier, Journal of Magnetism and Magnetic Materials 489 (2019) 165478

12.Effect of strained barrier on valley polarization in magnetic-modulated graphene, International Journal of Modern Physics B Vol. 33, No. 14 (2019) 1950144

13.Effect of the delta-doping on the magnetoresistance effect in a magnetically modulated nanostructure. International Journal of Modern Physics B, Vol. 32 (2018) 1850260

14.Spin-polarized transport of the electron in a device with a Schottky metal stripe and a delta-doping. International Journal of Modern Physics B, Vol. 32 (2018) 1850186

15.Effect of an in-plane magnetic field and a delta-doping on the electron transport in a nonmagnetic heterostructure, Physics Letters A 380 (2016) 1668-1671.

16.Electron transport in a non-magnetic nanostructure with spin-orbit interactions and delta-doping, Materials Science in Semiconductor Processing 27 (2014) 785-789.

17.Transport properties in a grapheme-based magnetic nanostructure modulated by a Schottky metal stripe, Materials Science in Semiconductor Processing 22 (2014) 59-63.

18.Transport in a realistic magnetic field modulated nanostructure

with the delta-doping，Physics Letters A 378 (2014) 286-289.

19.The electron transport properties in a three-barrier heterostructure modulated by the in-plane magnetic field, Superlattices and Microstructures 54 (2013) 54-60.

20.The electron transport properties in a three-barrier structure based on monolayer graphene, Materials Science in Semiconductor Processing, 16 (2013) 1008-1013.

21.Electron transport in a monolayer graphene modulated by ferromagneti-Schottky   metal   stripes,   Superlattices   and

Microstructures 60 (2013) 217-223.

22.Effects of a ferromagnetic metal stripe and a Schottky metal stripe on the electron transport in a nanostructure, Vacuum 86 (2012) 1041-1044.

23.Spin-dependent electron transport in a nonmagnetic nanostructure with both Dresselhaus and Rashba spin-orbit terms, Superlattices and Microstructures, 51 ( 2012) 1-8.

24.Spin polarization in a two-dimensional electron gas modulated by ferromagnetic and Schottky metal stripes, Microelectronics Reliability, 51 (2011) 1123-1126.

25.Ballistic electron transport in a magnetic nanostructure periodically modulated by the delta-doping, Physica E 43 (2011) 901-904.

26.Spin-dependent electron transport in a magnetic nanostructure

with the δ-doping, Physics Letters A 374 (2010) 2270-2273.

27.The effect of the periodic bias on the electron transport in a magnetic quantum structure, Microelectronic Engineering 87 (2010) 216-220.

28.Spin-dependent resonant tunneling in a periodic non-magnetic

heterostructure with spin – orbit effects, Physics Letters A 374 (2010) 3341-3345.

29.The bias- and temperature-dependent electron transport in a

magnetic nanostructure, Applied Surface Science 255 (2009) 3829-3832.

30.Effect of the delta-doping on the electron transport in an antiparalleldouble delta-magnetic-barrier nanostructure, Applied Surface Science 255 (2009) 7348-7350.

31.Electron-spin polarization in a nanostructure modulated by the periodic bias, Physica E 41 (2009) 1315-1318.

32.Bias-tunable electron transport properties in a nanostructure with two parallel-magnetic barriers, Solid State Communications 145 (2008) 271-274.

33.The effect of the bias on the electron transport properties in a magnetic double-barrier nanostructure, Solid State Communications 147 (2008) 242-245.

34.The conductance and magnetoresistance effect in a periodically magnetically modulated nanostructure, Microelectronics Journal 39 (2008) 1576-1579.

35.Phonon transport and thermal conductivity in a dielectric quantum waveguide, Solid-State Electronics 52 (2008) 37-43.

36.The magnetoresistance effect in a nanostructure with the periodic magnetic barriers, Applied Surface Science 254 (2008) 3939-3942.

37.The electron transport characters in a nanostructurewith the

periodic magnetic-electric barriers, Chinese Physics 16 (10) (2007)

3080-3087.

38.The effect of periodic magnetic – electric barriers on electron transport in a nanostructure, Solid State Communications 141

(2007) 61-64.

39.Phonon Transport and Thermal Conductivity in a Four-Terminal Structure, Commun. Theor. Phys. 46 (2006) 568-572.

Main Project:

1.        National Natural Science Foundation of China (Grant No. 11304236)

2.        Hubei Province Key Laboratory of Systems Science in Metallurgical Process, (Grant Nos. Y201308, C201018, Y201513)

3.        Program for Outstanding Young Science and Technology Innovation Teams in Higher Education Institutions of Hubei Province, China (Grant No. T201502)

4.        Wuhan University of Science and Technology (Grant Nos. 2009xz18, 1ZRA3102)