Abstract
Bismuth (Bi) has undergone researches for dozens of years on account of its abundant physics including the remarkably high mobility, exceptional large positive magnetoresistance and the coexistence of an insulating interior as well as metallic surfaces. Very recently, two-dimensional topologically-protected surface states immune to nonmagnetic perturbation such as surface oxidation and impurity scattering were experimentally demonstrated through systematic magnetotransport measurements, e.g. weak antilocalization effect and angular dependent Shubnikov-de Haas oscillations. Such robust metallic surface states, which are efficient in carrier transportation, along with its small bulk gap (14 meV) make Bi favored for high-responsive broadband photodetection. Here, we for the first time demonstrate the stable ultra-broadband photoresponse from 370 nm to 1550 nm with good reproducibility at room temperature based on a Bi photodetector. The fabricated device’s responsivity approaches 250 mA/W, accompanied with a rise time of 0.9 s and a decay time of 1.9 s. The photocurrent is linear dependent on the voltage and incident power, offering good tunability for multi-purpose applications. Thickness-dependent conductance and photocurrent reveal that the bulk is the optically active layer while the surface channel is responsible for carrier transportation. These findings pave an avenue to develop ultra-broadband Bi photodetectors for the next-generation multifunctional optoelectronic devices.
Highlights
In device implementation[21,22,23,24]
Systematic magnetotransport measurements, e.g. weak antilocalization effect (WAL) and angular dependent Shubnikov-de Haas (SdH) oscillations, have demonstrated Bi to be a topological insulator (TI) with 2D surface states immune to nonmagnetic perturbation such as surface oxidation and impurity scattering, like the most common TI Bi2(Te, Se)[,25,26]
This is an indicative of little metastable charge trapping centers or local potential fluctuations caused by the material inhomogeneity, benefit from the high quality nature of the PLD-grown Bi film
Summary
In device implementation[21,22,23,24]. mass production, an essential requirement for device fabrication, appears to be unattainable due to the uncontrollable and nonrepeatability of the scotch-tape based micromechanical cleavage method, the most popular way to prepare 2D materials[13,14]. Systematic magnetotransport measurements, e.g. weak antilocalization effect (WAL) and angular dependent Shubnikov-de Haas (SdH) oscillations, have demonstrated Bi to be a topological insulator (TI) with 2D surface states immune to nonmagnetic perturbation such as surface oxidation and impurity scattering, like the most common TI Bi2(Te, Se)[,25,26] Such findings reasonably explain the above mentioned novel properties of Bi and result in the resurgence of extensive scientific and engineering interest. Thickness-dependent conductance and photocurrent indicate that the bulk of Bi is the optically actively layer while the surface channel is responsible for carrier transportation. These results stress that Bi opens up opportunities for developing the generation ultra-broadband high performance photodetectors
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