TY - JOUR
T1 - Digital transfer growth of patterned 2D metal chalcogenides by confined nanoparticle evaporation
AU - Mahjouri-Samani, Masoud
AU - Tian, Mengkun
AU - Wang, Kai
AU - Boulesbaa, Abdelaziz
AU - Rouleau, Christopher M.
AU - Puretzky, Alexander A.
AU - McGuire, Michael A.
AU - Srijanto, Bernadeta R.
AU - Xiao, Kai
AU - Eres, Gyula
AU - Duscher, Gerd
AU - Geohegan, David B.
N1 - Publisher Copyright:
© 2014 American Chemical Society.
PY - 2014/11/25
Y1 - 2014/11/25
N2 - Developing methods for the facile synthesis of two-dimensional (2D) metal chalcogenides and other layered materials is crucial for emerging applications in functional devices. Controlling the stoichiometry, number of the layers, crystallite size, growth location, and areal uniformity is challenging in conventional vapor-phase synthesis. Here, we demonstrate a method to control these parameters in the growth of metal chalcogenide (GaSe) and dichalcogenide (MoSe2) 2D crystals by precisely defining the mass and location of the source materials in a confined transfer growth system. A uniform and precise amount of stoichiometric nanoparticles are first synthesized and deposited onto a substrate by pulsed laser deposition (PLD) at room temperature. This source substrate is then covered with a receiver substrate to form a confined vapor transport growth (VTG) system. By simply heating the source substrate in an inert background gas, a natural temperature gradient is formed that evaporates the confined nanoparticles to grow large, crystalline 2D nanosheets on the cooler receiver substrate, the temperature of which is controlled by the background gas pressure. Large monolayer crystalline domains (∼100 μm lateral sizes) of GaSe and MoSe2 are demonstrated, as well as continuous monolayer films through the deposition of additional precursor materials. This PLD-VTG synthesis and processing method offers a unique approach for the controlled growth of large-area metal chalcogenides with a controlled number of layers in patterned growth locations for optoelectronics and energy related applications. (Figure Presented).
AB - Developing methods for the facile synthesis of two-dimensional (2D) metal chalcogenides and other layered materials is crucial for emerging applications in functional devices. Controlling the stoichiometry, number of the layers, crystallite size, growth location, and areal uniformity is challenging in conventional vapor-phase synthesis. Here, we demonstrate a method to control these parameters in the growth of metal chalcogenide (GaSe) and dichalcogenide (MoSe2) 2D crystals by precisely defining the mass and location of the source materials in a confined transfer growth system. A uniform and precise amount of stoichiometric nanoparticles are first synthesized and deposited onto a substrate by pulsed laser deposition (PLD) at room temperature. This source substrate is then covered with a receiver substrate to form a confined vapor transport growth (VTG) system. By simply heating the source substrate in an inert background gas, a natural temperature gradient is formed that evaporates the confined nanoparticles to grow large, crystalline 2D nanosheets on the cooler receiver substrate, the temperature of which is controlled by the background gas pressure. Large monolayer crystalline domains (∼100 μm lateral sizes) of GaSe and MoSe2 are demonstrated, as well as continuous monolayer films through the deposition of additional precursor materials. This PLD-VTG synthesis and processing method offers a unique approach for the controlled growth of large-area metal chalcogenides with a controlled number of layers in patterned growth locations for optoelectronics and energy related applications. (Figure Presented).
KW - 2D layered materials
KW - Gallium selenide
KW - Metal chalcogenides
KW - Molybdenum diselenide
KW - Pulsed laser deposition
KW - Vapor transport growth
UR - http://www.scopus.com/inward/record.url?scp=84912553596&partnerID=8YFLogxK
U2 - 10.1021/nn5048124
DO - 10.1021/nn5048124
M3 - Article
AN - SCOPUS:84912553596
SN - 1936-0851
VL - 8
SP - 11567
EP - 11575
JO - ACS Nano
JF - ACS Nano
IS - 11
ER -