Minggang Xia
- Professor
- Supervisor of Doctorate Candidates
- Supervisor of Master's Candidates
- Name (English):Minggang Xia
- E-Mail:
- Date of Employment:2002-04-09
- Education Level:With Certificate of Graduation for Doctorate Study
- Business Address:仲英楼B812
- Degree:Doctor
- Professional Title:Professor
- Status:Employed
- Alma Mater:西安交通大学
- College:School of Physics
- Discipline:Physics
- Papers
Plasma-induced symmetric ambipolar transport in MoS2/WSe2 p-n heterojunctions via stacking-order-mediation
Release Time:2026-03-23 Hits:
- Date:2026-03-23
- Impact Factor:3.6
- DOI Number:10.1063/5.0313734
- Title of Paper:Plasma-induced symmetric ambipolar transport in MoS2/WSe2 p-n heterojunctions via stacking-order-mediation
- Journal:APPLIED PHYSICS LETTERS
- Summary:Ambipolar semiconductors based on two-dimensional p-n junctions have attracted significant attention and are driving optoelectronic and logic circuit applications. However, their low carrier mobility and electron-hole mobility asymmetry (>10(1)) result in poor signal resolution, which limits its practical applications. This study demonstrates high-mobility and mobility-symmetric ambipolar transport in MoS2/WSe2 p-n heterojunctions through precise oxygen plasma-mediated interface engineering. The mild oxygen plasma treatment simultaneously passivates selenium vacancies in WSe2 and sulfur vacancies in MoS2, thereby reducing scattering centers and optimizing carrier concentrations. The elevated and balanced carrier concentrations on both sides of the junction effectively lower the tunneling barrier, facilitating efficient charge injection and enabling high-performance ambipolar conduction. Analysis of the charge transport mechanism reveals a direct tunneling mode at the heterointerface. By applying a 6 s low-power soft oxygen plasma treatment to MoS2 and a 30 s oxygen plasma to WSe2, the device exhibits a more than two orders of magnitude improvement in electrical performance, demonstrating symmetric ambipolar behavior with a hole mobility of 83 cm(2) V-1 s(-1) and an electron mobility of 42 cm(2) V-1 s(-1), respectively. This work establishes plasma-induced design principles for high-performance ambipolar transistors and provides critical insights for logic optoelectronic devices.
- Document Code:001715550300001
- Document Type:J
- Volume:128
- Issue:11
- Page Number:111601
- ISSN:0003-6951
- Translation or Not:No
- Date of Publication:2026-03-16
- Included Journals:SCI
- Links to Published Journals:https://pubs.aip.org/aip/apl/article/128/11/111601/3383685/