TY - JOUR
T1 - Monolayer Vanadium-Doped Tungsten Disulfide
T2 - A Room-Temperature Dilute Magnetic Semiconductor
AU - Zhang, Fu
AU - Zheng, Boyang
AU - Sebastian, Amritanand
AU - Olson, David H.
AU - Liu, Mingzu
AU - Fujisawa, Kazunori
AU - Pham, Yen Thi Hai
AU - Jimenez, Valery Ortiz
AU - Kalappattil, Vijaysankar
AU - Miao, Leixin
AU - Zhang, Tianyi
AU - Pendurthi, Rahul
AU - Lei, Yu
AU - Elías, Ana Laura
AU - Wang, Yuanxi
AU - Alem, Nasim
AU - Hopkins, Patrick E.
AU - Das, Saptarshi
AU - Crespi, Vincent H.
AU - Phan, Manh Huong
AU - Terrones, Mauricio
N1 - Publisher Copyright:
© 2020 The Authors. Published by Wiley-VCH GmbH
PY - 2020/12/16
Y1 - 2020/12/16
N2 - Dilute magnetic semiconductors (DMS), achieved through substitutional doping of spin-polarized transition metals into semiconducting systems, enable experimental modulation of spin dynamics in ways that hold great promise for novel magneto–electric or magneto–optical devices, especially for two-dimensional (2D) systems such as transition metal dichalcogenides that accentuate interactions and activate valley degrees of freedom. Practical applications of 2D magnetism will likely require room-temperature operation, air stability, and (for magnetic semiconductors) the ability to achieve optimal doping levels without dopant aggregation. Here, room-temperature ferromagnetic order obtained in semiconducting vanadium-doped tungsten disulfide monolayers produced by a reliable single-step film sulfidation method across an exceptionally wide range of vanadium concentrations, up to 12 at% with minimal dopant aggregation, is described. These monolayers develop p-type transport as a function of vanadium incorporation and rapidly reach ambipolarity. Ferromagnetism peaks at an intermediate vanadium concentration of ~2 at% and decreases for higher concentrations, which is consistent with quenching due to orbital hybridization at closer vanadium–vanadium spacings, as supported by transmission electron microscopy, magnetometry, and first-principles calculations. Room-temperature 2D-DMS provide a new component to expand the functional scope of van der Waals heterostructures and bring semiconducting magnetic 2D heterostructures into the realm of practical application.
AB - Dilute magnetic semiconductors (DMS), achieved through substitutional doping of spin-polarized transition metals into semiconducting systems, enable experimental modulation of spin dynamics in ways that hold great promise for novel magneto–electric or magneto–optical devices, especially for two-dimensional (2D) systems such as transition metal dichalcogenides that accentuate interactions and activate valley degrees of freedom. Practical applications of 2D magnetism will likely require room-temperature operation, air stability, and (for magnetic semiconductors) the ability to achieve optimal doping levels without dopant aggregation. Here, room-temperature ferromagnetic order obtained in semiconducting vanadium-doped tungsten disulfide monolayers produced by a reliable single-step film sulfidation method across an exceptionally wide range of vanadium concentrations, up to 12 at% with minimal dopant aggregation, is described. These monolayers develop p-type transport as a function of vanadium incorporation and rapidly reach ambipolarity. Ferromagnetism peaks at an intermediate vanadium concentration of ~2 at% and decreases for higher concentrations, which is consistent with quenching due to orbital hybridization at closer vanadium–vanadium spacings, as supported by transmission electron microscopy, magnetometry, and first-principles calculations. Room-temperature 2D-DMS provide a new component to expand the functional scope of van der Waals heterostructures and bring semiconducting magnetic 2D heterostructures into the realm of practical application.
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U2 - 10.1002/advs.202001174
DO - 10.1002/advs.202001174
M3 - Article
C2 - 33344114
AN - SCOPUS:85096652275
SN - 2198-3844
VL - 7
JO - Advanced Science
JF - Advanced Science
IS - 24
M1 - 2001174
ER -