Premium
Energy Dissipation in Black Phosphorus Heterostructured Devices
Author(s) -
Ali Fida,
Ahmed Faisal,
Yang Zheng,
Moon Inyong,
Lee Myeongjin,
Hassan Yasir,
Lee Changgu,
Yoo Won Jong
Publication year - 2019
Publication title -
advanced materials interfaces
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.671
H-Index - 65
ISSN - 2196-7350
DOI - 10.1002/admi.201801528
Subject(s) - materials science , joule heating , electric field , raman spectroscopy , dissipation , black phosphorus , van der waals force , joule (programming language) , optoelectronics , condensed matter physics , engineering physics , composite material , power (physics) , optics , thermodynamics , chemistry , physics , quantum mechanics , engineering , organic chemistry , molecule
Two‐dimensional (2D) black phosphorus (BP) has attracted increasing interest for next‐generation solid‐state device applications due to its unique blend of versatile properties. The ultrathin physique and low thermal conductivity (40–20 Wm −1 K −1 ) of BP make it susceptible to premature Joule breakdown under moderate electric field induced by inefficient and nonhomogeneous energy dissipation. Here, it is reported that the back‐gate BP device suffers Joule breakdown merely under 4 MV m −1 electric field value with the centrally localized fracture. The spatial micro‐Raman spectroscopy confirms uneven thermal spreading in BP channel with the center being 20% hotter than the lateral ends. Furthermore, to mitigate the early breakdown and uneven spreading, vertical van der Waals structure is assembled. The results show that the vertical BP device exhibits 230 times higher field strength and one order enhancement in power sustainability than those of lateral devices due to the integration of thermally favorable constituent materials and formation of the optimal path for self‐heat removal.