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黄毅课题组 | ADVANCED MATERIALS

发布人:    发布时间:2024/02/20   浏览次数:

Negative Photoconductivity of Fe3GeTe2 Crystal with Native Heterostructure for Ultraviolet to Terahertz Ultra-Broadband Photodetection


By

Ma, SP (Ma, Suping) [1] ; Li, GH (Li, Guanghao) [1] ; Li, Z (Li, Zhuo) [1] ; Wang, TY (Wang, Tingyuan) [2] ; Zhang, YW (Zhang, Yawen) [1] ; Li, NN (Li, Ningning) [2] ; Chen, HS (Chen, Haisheng) [2] ; Zhang, N (Zhang, Nan) [2] ; Liu, WW (Liu, Weiwei) [2] ; Huang, Y (Huang, Yi) [1]

Source

ADVANCED MATERIALS

DOI

10.1002/adma.202305709

Early Access

JAN 2024

Indexed

2024-01-26

Document Type

Article; Early Access

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Abstract

Gaining insight into the photoelectric behavior of ferromagnetic materials is significant for comprehensively grasping their intrinsic properties and broadening future application fields. Here, through a specially designed Fe3GeTe2/O-Fe3GeTe2 heterostructure, first, the broad-spectrum negative photoconductivity phenomenon of ferromagnetic nodal line semimetal Fe3GeTe2 is reported that covers UV-vis-infrared-terahertz bands (355 nm to 3000 mu m), promising to compensate for the inadequacies of traditional optoelectronic devices. The significant suppression of photoexcitation conductivity is revealed to arise from the semimetal/oxidation (sMO) interface-assisted dual-response mechanism, in which the electron excitation origins from the semiconductor photoconductivity effect in high-energy photon region, and semimetal topological band-transition in low-energy photon region. High responsivities ranging from 10(3) to 10(0) mA W-1 are acquired within ultraviolet-terahertz bands under +/- 0.1 V bias voltage at room temperature. Notably, the responsivity of 2.572 A W-1 at 3000 mu m (0.1 THz) and the low noise equivalent power of 26 pW Hz(-1/2) surpass most state-of-the-art mainstream terahertz detectors. This research provides a new perspective for revealing the photoelectric conversion properties of Fe3GeTe2 crystal and paves the way for the development of spin-optoelectronic devices.