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W3006735203 abstract "Abstract The MoS 2 photodetector on different substrates stacked via van der Waals force has been explored extensively because of its great potential in optoelectronics. Here, we integrate multilayer MoS 2 on monocrystalline SiC substrate though direct chemical vapor deposition. The MoS 2 film on SiC substrate shows high quality and thermal stability, in which the full width at half-maximum and first-order temperature coefficient for the <m:math xmlns:m=http://www.w3.org/1998/Math/MathML> <m:mrow> <m:msubsup> <m:mi>E</m:mi> <m:mrow> <m:mn>2</m:mn> <m:mi>g</m:mi> </m:mrow> <m:mn>1</m:mn> </m:msubsup> </m:mrow> </m:math> $E_{2g}^1$ Raman mode are 4.6 cm −1 and −0.01382 cm −1 /K, respectively. The fabricated photodetector exhibits excellent performance in the UV and visible regions, including an extremely low dark current of ~1 nA at a bias of 20 V and a low noise equivalent of 10 −13 –10 −15 W/Hz 1/2 . The maximum responsivity of the MoS 2 /SiC photodetector is 5.7 A/W with the incident light power of 4.35 μW at 365 nm (UV light). Furthermore, the maximum photoconductive gain, noise equivalent power, and normalized detectivity for the fabricated detector under 365 nm illumination are 79.8, 7.08 × 10 −15 W/Hz 1/2 , and 3.07 × 10 10 Jonesat, respectively. We thus demonstrate the possibility for integrating high-performance photodetectors array based on MoS 2 /SiC via direct chemical vapor growth." @default.
W3006735203 created "2020-03-06" @default.
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W3006735203 date "2020-02-24" @default.
W3006735203 modified "2023-10-18" @default.
W3006735203 title "Facile integration of MoS<sub>2</sub>/SiC photodetector by direct chemical vapor deposition" @default.
W3006735203 cites W1600657134 @default.
W3006735203 cites W1850455154 @default.
W3006735203 cites W1869913168 @default.
W3006735203 cites W1963755685 @default.
W3006735203 cites W1966646840 @default.
W3006735203 cites W1969393825 @default.
W3006735203 cites W1970923500 @default.
W3006735203 cites W1982032999 @default.
W3006735203 cites W1982112708 @default.
W3006735203 cites W1997219463 @default.
W3006735203 cites W2000459404 @default.
W3006735203 cites W2004967694 @default.
W3006735203 cites W2005005640 @default.
W3006735203 cites W2010831213 @default.
W3006735203 cites W2017871657 @default.
W3006735203 cites W2018601513 @default.
W3006735203 cites W2033020116 @default.
W3006735203 cites W2034050716 @default.
W3006735203 cites W2035530307 @default.
W3006735203 cites W2037594814 @default.
W3006735203 cites W2037811931 @default.
W3006735203 cites W2059432259 @default.
W3006735203 cites W2062259781 @default.
W3006735203 cites W2071594837 @default.
W3006735203 cites W2078536002 @default.
W3006735203 cites W2082552554 @default.
W3006735203 cites W2090908091 @default.
W3006735203 cites W2096329902 @default.
W3006735203 cites W2098851025 @default.
W3006735203 cites W2100753771 @default.
W3006735203 cites W2127532041 @default.
W3006735203 cites W2141144356 @default.
W3006735203 cites W2144365122 @default.
W3006735203 cites W2147662109 @default.
W3006735203 cites W2149766517 @default.
W3006735203 cites W2162320078 @default.
W3006735203 cites W2162868393 @default.
W3006735203 cites W2171573561 @default.
W3006735203 cites W2215244826 @default.
W3006735203 cites W2220596051 @default.
W3006735203 cites W2259120121 @default.
W3006735203 cites W2320785156 @default.
W3006735203 cites W2321770094 @default.
W3006735203 cites W2322339301 @default.
W3006735203 cites W2337100196 @default.
W3006735203 cites W2482506383 @default.
W3006735203 cites W2509777341 @default.
W3006735203 cites W2542208665 @default.
W3006735203 cites W2578855570 @default.
W3006735203 cites W2605037749 @default.
W3006735203 cites W2733922649 @default.
W3006735203 cites W2755034173 @default.
W3006735203 cites W2755436963 @default.
W3006735203 cites W2758265978 @default.
W3006735203 cites W2759938919 @default.
W3006735203 cites W2763048613 @default.
W3006735203 cites W2790069941 @default.
W3006735203 cites W2900918826 @default.
W3006735203 cites W2904530759 @default.
W3006735203 cites W2909632161 @default.
W3006735203 cites W2912174688 @default.
W3006735203 cites W2913909332 @default.
W3006735203 cites W2914757185 @default.
W3006735203 cites W2915356732 @default.
W3006735203 cites W2921107936 @default.
W3006735203 cites W2945952437 @default.
W3006735203 cites W2947360361 @default.
W3006735203 cites W2969333645 @default.
W3006735203 cites W2972634230 @default.
W3006735203 cites W3101929953 @default.
W3006735203 cites W3105489360 @default.
W3006735203 cites W3124679368 @default.
W3006735203 doi "https://doi.org/10.1515/nanoph-2019-0562" @default.
W3006735203 hasPublicationYear "2020" @default.
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