Publications

PREPRINTS 2020 2019 2018 2017 2016 2015 2014 2013 2012 2011 2009 2008 2007 2006 2005 2004 2002 2001 THESES
Preprints
2020

[59] Improved Contacts and Device Performance in MoS2 Transistors Using a 2D Semiconductor Interlayer
Kraig Andrews, Arthur Bowman, Upendra Rijal, Pai-Yen Chen, and Zhixian Zhou.
ACS Nano, XX(xx): XXXXX-XXXXY.

2019

[58] Near-infrared optical transitions in PdSe2 phototransistors
Thayer S. Walmsley, Kraig Andrews, Tianjiao Wang, Amanda Haglund, Upendra Rijal, Arthur Bowman, David Mandrus, Zhixian Zhou, and Ya-Qiong Xu.
Nanoscale, 11(30): 14410-14416.

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[57] Degenerately Doped Transition Metal Dichalcogenides as Ohmic Homojunction Contacts to Transition Metal Dichalcogenides Semiconductors
Zhibin Gao, Zhixian Zhou, and David Tománek.
ACS Nano, 13(5): 5103-5111.

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[56] Reversible Photo-induced Doping in WSe2 Field Effect Transistors
Xuyi Luo, Kraig Andrews, Tianjiao Wang, Arthur Bowman, Zhixian Zhou, and Ya-Qiong Xu.
Nanoscale, 11(15):7358-7363.

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2018

[55] Gate-Tunable Photoresponse Time in Black Phosphorus-MoS2 Heterojunctions
Thayer Walmsley, Bhim Chamlagain, Upendra Rijal, Tianjiao Wang, Zhixian Zhou, and Ya-Qiong Xu.
Advanced Optical Materials, 7(5).

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[54] High Performance WSe2 Phototransistors with 2D/2D Ohmic Contacts
Tianjiao Wang, Kraig Andrews, Arthur Bowman, Tu Hong, Michael Koehler, Jiaqiang Yan, David Mandrus, Zhixian Zhou, and Ya-Qiong Xu.
Nano Letters, 18(5):2766-2771.

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2017

[53] Substitutional electron and hole doping of wse2: Synthesis, electrical characterization, and observation of band-to-band tunneling
R Mukherjee, HJ Chuang, MR Koehler, N Combs, A Patchen, ZX Zhou, and D Mandrus.
Physical Review Applied, 7(3):034011.

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[52] Vertically stacked and self-encapsulated van der waals heterojunction diodes using two-dimensional layered semiconductors
Jinshui Miao, Zhihao Xu, Qing Li, Arthur Bowman, Suoming Zhang, Weida Hu, Zhixian Zhou, and Chuan Wang.
ACS nano, 11(10):10472–10479.

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[51] Thermally oxidized 2d tas2 as a high-κ gate dielectric for mos2 field-effect transistors
Bhim Chamlagain, Qingsong Cui, Sagar Paudel, Mark Ming-Cheng Cheng, Pai-Yen Chen, and Zhixian Zhou.
2D Materials, 4(3):031002.

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[50] Optimizing charge injection across transition metal dichalcogenide heterojunctions: Theory and experiment
Jie Guan, Hsun-Jen Chuang, Zhixian Zhou, and David Tománek.
ACS Nano, 11(4):3904–3910.

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[49] Toward individually tunable compound eyes with transparent graphene electrode
Ali Shahini, Hai Jin, Zhixian Zhou, Yang Zhao, Pai-Yen Chen, Jing Hua, Mark Ming-Cheng Cheng.
Bioinspiration & Biomimetics12(4): 046002.

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[48] Optimization of electrochemical performance of LiFePO4/C by indium doping and high temperature annealing
Ratna Naik Ajay Kumar, Parisa Bashiri, Balaji Mandal, Kulwinder Dhindsa, Khadije Bazzi, Ambesh Dixit, Maryam Nazri, Zhixian Zhou, Vijayendra Garg, Aderbal Oliveira, Prem Vaishnava, Vaman M Naik, and Gholam-Abbas Nazri
Inorganics

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[47] Two-Dimensional Electronics and Optoelectronics: Present and Future
Zhixian Zhou, Yoke Khin Yap
Electronics

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2016

[46] Ultrathin and atomically flat transition-metal oxide: Promising building blocks for metal–insulator electronics
Qingsong Cui, Maryam Sakhdari, Bhim Chamlagain, Hsun-Jen Chuang, Yi Liu, Mark Ming-Cheng Cheng, Zhixian Zhou, Pai-Yen Chen
ACS Applied Materials & Interfaces, 8(50): 34552-34558.

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[45] Electromagnetic shielding effectiveness of a hybrid carbon nanotube/glass fiber reinforced polymer composite
Ayoub Y Boroujeni, Mehran Tehrani, Majid Manteghi, Zhixian Zhou, Marwan Al-Haik
Journal of Engineering Materials and Technology, 138(4): 041001.

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[44] Visualizing light scattering in silicon waveguides with black phosphorus photodetectors
Tianjiao Wang, Shuren Hu, Bhim Chamlagain, Tu Hong, Zhixian Zhou, Sharon M Weiss, Ya‐Qiong Xu
Advanced Materials, 28(33): 7162-7166.

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[43] Enhanced electrochemical performance of LiFePO4/C nanocomposites due to in situ formation of Fe2P impurities
KS Dhindsa, A Kumar, GA Nazri, VM Naik, VK Garg, AC Oliveira, PP Vaishnava, ZX Zhou, and R Naik
Journal of Solid State Electrochemistry, 20(8): 2275-2282.

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[42] Low-Resistance 2D/2D Ohmic Contacts: A Universal Approach to High-Performance WSe2, MoS2, and MoSe2 Transistors
Hsun-Jen Chuang, Bhim Chamlagain, Michael Koehler, Meeghage Madusanka Perera, Jiaqiang Yan, David Mandrus, David Tománek, and Zhixian Zhou
Nano Letters, 16(3): 1896-1902.

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[41] Versatile miniature tunable liquid lenses using transparent graphene electrodes
Ali Shahini, Jinjun Xia, Zhixian Zhou, Yang Zhao, and Mark Ming-Cheng Cheng
Langmuir, 32(6): 1658-1665.

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2015

[40] Microscopic Studies of Black Phosphorus and Its Field-Effect Transistors
Minghu Pan, Hui Yuan, Ya-Qiong Xu, Zhixian Zhou, and Vincent Meunier
ECS Transactions, 69(12): 93-104

[39] Plasmonic hot electron induced photocurrent response at MoS2–metal junctions
Tu Hong, Bhim Chamlagain, Shuren Hu, Sharon M Weiss, Zhixian Zhou, and Ya-Qiong Xu
ACS Nano, 9(5):5357-5363

[38] Anisotropic photocurrent response at black phosphorus–MoS 2 p–n heterojunctions
Tu Hong, Bhim Chamlagain, Tianjiao Wang, Hsun-Jen Chuang, Zhixian Zhou, and Ya-Qiong Xu
Nanoscale, 7(44):18537–18541

2014

[37] The Mechanisms of Rectification in Au| Molecule| Au Devices Based on Langmuir–Blodgett Monolayers of Iron (III) and Copper (II) Surfactants
Lanka D Wickramasinghe, Shivnath Mazumder, Sunalee Gonawala, Meeghage Madusanka Perera, Habib Baydoun, Bishnu Thapa, Li Li, Lingxiao Xie, Guangzhao Mao, Zhixian Zhou, H Bernhard Schlegel, and Cláudio N Verani
Angewandte Chemie, 53(52):14462-14467

[36] High Mobility WSe2 p- and n-Type Field-Effect Transistors Contacted by Highly Doped Graphene for Low-Resistance Contacts
Hsun-Jen Chuang, Xuebin Tan, Nirmal Jeevi Ghimire, Meeghage Madusanka Perera, Bhim Chamlagain, Mark Ming-Cheng Cheng, Jiaqiang Yan, David Mandrus, David Tománek, and Zhixian Zhou
Nano Letters, 14(6): 3594-3601

[35] Polarized photocurrent response in black phosphorus field-effect transistors
Tu Hong, Bhim Chamlagain, Wenzhi Lin, Hsun-Jen Chuang, Minghu Pan, Zhixian Zhou, and Ya-Qiong Xu
Nanoscale, 6(15): 8978-8983

[34] Mobility Improvement and Temperature Dependence in MoSe2 Field-Effect Transistors on Parylene-C Substrate
Bhim Chamlagain, Qing Li, Nirmal Jeevi Ghimire, Hsun-Jen Chuang, Meeghage Madusanka Perera, Hong Tu, Yong Xu, Minghu Pan, Di Xaio, Jiaqiang Yan, David Mandrus, and Zhixian Zhou
ACS Nano, 8(5): 5079-5088

2013

[33] Edge effects on the pH response of graphene nanoribbon field effect transistors
Xuebin Tan, Hsun-Jen Chuang, Ming-Wei Lin, Zhixian Zhou, and Mark Ming-Cheng
The Journal of Physical Chemistry C, 117(51): 27155-27160

[32] Enhanced electrochemical performance of graphene modified LiFePO4 cathode material for lithium ion batteries
Kulwinder Singh Dhindsa, Balaji Prasad Mandal, K Bazzi, MW Lin, M Nazri, GA Nazri, VM Naik, VK Garg, AC Oliveira, P Vaishnava, R Naik, and ZX Zhou
Solid State Ionics, 253: 94-100

[31] Rectification in Nanoscale Devices Based on an Asymmetric Five‐Coordinate Iron (III) Phenolate Complex
Lanka D Wickramasinghe, Meeghage Madusanka Perera, Li Li, Guangzhao Mao, Zhixian Zhou, and Cláudio N Verani
Angewandte Chemie International Edition, 52(50): 13346-13350

[30] Improved Carrier Mobility in Few-Layer MoS2 Field-Effect Transistors with Ionic-Liquid Gating
Meeghage Madusanka Perera, Ming-Wei Lin, Hsun-Jen Chuang, Bhim Prasad Chamlagain, Chongyu Wang, Xuebin Tan, Mark Ming-Cheng Cheng, David Tománek, and Zhixian Zhou
ACS Nano, 7(5): 4449-4458

2012

[29] Control and enhancement of graphene sensitivity by engineering edge defects
Xuebin Tan, Chad Huard, Hsun-Jen Chuang, Ming-Wei Lin, Zhixian Zhou, and Mark Ming-Cheng Cheng
Sensors, IEEE

[28] Electrowetting on dielectric experiments using graphene
Xuebin Tan, Zhixian Zhou, and Mark Ming-Cheng Cheng
Nanotechnology, 23(37):375501

[27] Mobility enhancement and highly efficient gating of monolayer MoS2 transistors with polymer electrolyte
Ming-Wei Lin, Lezhang Liu, Qing Lan, Xuebin Tan, Kulwinder S Dhindsa, Peng Zeng, Vaman M Naik, Mark Ming-Cheng Cheng, and Zhixian Zhou
Journal of Physics D: Applied Physics, 45(34): 345102

[26] Nanostructured high specific capacity C-LiFePO4 cathode material for lithium-ion batteries
Khadije Bazzi, Kulwinder S Dhindsa, Ambesh Dixit, Moodakere B Sahana, Chandran Sudakar, Mariam Nazri, Zhixian Zhou, Prem Vaishnava, Vaman M Naik, Gholam A Nazri, and Ratna Naik
Journal of Materials Research, 27(2): 424-430

2011

[25] Carbon dioxide gas sensor using a graphene sheet
Hyeun Joong Yoon, Jin Ho Yang, Zhixian Zhou, Sang Sik Yang, and Mark Ming-Cheng Cheng.
Sensors and Actuators B: Chemical, 157(1): 310-313

[24] Approaching the intrinsic band gap in suspended high-mobility graphene nanoribbons
Ming-Wei Lin, Cheng Ling, Luis A Agapito, Nicholas Kioussis, Yiyang Zhang, Mark Ming-Cheng Cheng, Wei L Wang, Efthimios Kaxiras, and Zhixian Zhou.
Physical Review B, 84(12): 125411

[23] Electrical transport properties of graphene nanoribbons produced from sonicating graphite in solution
Cheng Ling, Gabriel Setzler, Ming-Wei Lin, Kulwinder Singh Dhindsa, Jin Jin, Hyeun Joong Yoon, Seung Soo Kim, Mark Ming-Cheng Cheng, Noppi Widjaja, and Zhixian Zhou.
Nanotechnology, 22(32): 325201

[22] Room-temperature high on/off ratio in suspended graphene nanoribbon field-effect transistors
Ming-Wei Lin, Cheng Ling, Yiyang Zhang, Hyeun Joong Yoon, Mark Ming-Cheng Cheng, Luis A Agapito, Nicholas Kioussis, Noppi Widjaja, and Zhixian Zhou.
Nanotechnology, 22(26): 265201

2009

[21] The performance of in situ grown Schottky-barrier single wall carbon nanotube field-effect transistors
Zhixian Zhou, Gyula Eres, Rongying Jin, Alaska Subedi, David Mandrus, and Eugene H Kim.
Nanotechnology, 20(8): 085709 .

2008

[20] Magnetic properties of the Haldane-gap material [Ni (C2H8N2) 2NO2](BF4)
E Čižmár, M Ozerov, O Ignatchik, TP Papageorgiou, J Wosnitza, SA Zvyagin, J Krzystek, Z Zhou, CP Landee, BR Landry, MM Turnbull, and JL Wikaira.
New Journal of Physics, 10(3): 033008.

2007

[19] Resistance and current-voltage characteristics of individual superconducting NbSe2 nanowires
Zhixian Zhou, Rongying Jin, Gyula Eres, David Mandrus, Victor Barzykin, Pedro Schlottmann, Yew-San Hor, Zhili Xiao, and John F Mitchell.
Physical Review B, 76(10: 104511.

[18] One-dimensional electron transport in Cu-tetracyanoquinodimethane organic nanowires
Zhixian Zhou, Kai Xiao, Rongying Jin, David Mandrus, Jing Tao, David B Geohegan, and Stephen Pennycook.
Applied Physics Letters, 90(19): 193115.

[17] Epitaxial Ca2RuO4+ δ thin films grown on (001) LaAlO3 by pulsed laser deposition
Y Xin, X Wang, ZX Zhou, and JP Zheng.
Thin Solid Films, 515(7): 3946-3951 (2007).

[16] The effect of annealing on the electrical and thermal transport properties of macroscopic bundles of long multi-wall carbon nanotubes
Rongying Jin, ZX Zhou, David Mandrus, Ilia N Ivanov, Gyula Eres, Jane Y Howe, Alexander A Puretzky, David B Geohegan.
Physica B: Condensed Matter, 388(1): 326-330.

[15] Very high field magnetization and AC susceptibility of native horse spleen ferritin
RP Guertin, N Harrison, ZX Zhou, S McCall, and F Drymiotis.
Journal of Magnetism and Magnetic Materials, 308(1): 97-100.

2006

[14] Control of electron transport related defects in in situ fabricated single wall carbon nanotube devices
Zhixian Zhou, Rongying Jin, Gyula Eres, Alaska Subedi, and David Mandrus.
Applied Physics Letters, 89(13): 133124.

[13] Crystal growth and giant magnetoresistance of rare earth layered cobaltites
SN Barilo, SV Shiryaev, GL Bychkov, AS Shestak, ZX Zhou, V Hinkov, VP Plakhty, Yu P Chernenkov, SV Gavrilov, M Baran, R Szymczak, D Sheptyakov, and H Szymczak.
Rev. Adv. Mater. Sci, 12:33-45.

[12] Observation of oscillatory magnetoresistance periodic in 1∕B and B in Ca3Ru2O7
V Durairaj, XN Lin, ZX Zhou, S Chikara, E Ehami, A Douglass, P Schlottmann, and G Cao.
Physical Review B, 73(5): 054434.

[11] Magnetodielectric effect in the S= 1∕ 2 quasi-two-dimensional antiferromagnet K2V3O8
RC Rai, J Cao, JL Musfeldt, David J Singh, X Wei, Rongying Jin, ZX Zhou, Brian C Sales, and David Mandrus.
Physical Review B, 73(7): 075112.

2005

[10] Colossal Magnetoresistance by Avoiding a Ferromagnetic State in the Mott System Ca3Ru2O7
XN Lin, ZX Zhou, V Durairaj, P Schlottmann, and G Cao.
Physical Review Letters, 95(1): 017203.

[9] Orbital order and uniaxial spin anisotropy in EuBaCo2O5.5 single crystals
ZX Zhou and P Schlottmann.
Physical Review B, 71(17):
174401.

2004

[8] Magnetization and magnetotransport of LBaCo2 O5.5(L= Gd, Eu) single crystals
ZX Zhou, S McCall, CS Alexander, JE Crow, P Schlottmann, SN Barilo, SV Shiryaev, GL Bychkov, and RP Guertin.
Physical Review B, 70(2): 024425.

[7] Magnetic properties of GdBaCo2O5+ δ single crystals
ZX Zhou, S McCall, CS Alexander, JE Crow, P Schlottmann, SN Barilo, SV Shiryaev, and GL Bychkov.
Journal of Alloys and Compounds, 369(1): 105-107.

[6] Transport and thermodynamic properties of Sr 3 Ru 2 O 7 near the quantum critical point
ZX Zhou, S McCall, CS Alexander, JE Crow, P Schlottmann, A Bianchi, C Capan, R Movshovich, KH Kim, M Jaime, N Harrison, MK Haas, RJ Cava, and G Cao.
Physical Review B, 69(14): 140409.

[5] Ferromagnetism and magnetoresistance of Co–ZnO inhomogeneous magnetic semiconductors
S. Yan, C. Ren, X. Wang, Y. Xin, Z.X. Zhou, L.M. Mei, M.J. Ren, Y.X. Chen, H Liu, Y.H. and Garmestani.
App. Phys. Lett., 84: 2376.

2002

[4] Magnetic interactions in (Pr, La) 3RuO7 and Pr3 (Ru, Nb) O7
ZX Zhou, G Cao, S McCall, JE Crow, RP Guertin, CH Mielke, and DG Rickel.
Philosophical Magazine B, 82(13): 1401-1412.

[3] Oberservation of Quantum Oscillations in Four-Layer BaRuO3
CS Alexander, Y Xin, ZX Zhou, S McCall, G Cao, and JE Crow.
Physical Phenomena At High Magnetic Fields IV, 393-396.

2001

[2] Thermodynamic properties of RE2RuO5 (RE= Pr, Nd, Sm, Gd and Tb)
G Cao, S McCall, ZX Zhou, CS Alexander, JE Crow, and RP Guertin.
Journal of Magnetism and Magnetic Materials, 226: 218-220.

[1] Magnetic ordering and enhanced electronic heat capacity in insulating L2RuO5 (L= Pr, Nd, Sm, Gd, and Tb)
G Cao, S McCall, ZX Zhou, CS Alexander, JE Crow, RP Guertin, and CH Mielke.
Physical Review B, 63(14): 144427.