Sayantan Ghosh1, Abin Varghese1,2,3, Kartikey Thakar1, Sushovan Dhara1, Saurabh Lodha4. 1. Department of Electrical Engineering, IIT Bombay, Mumbai, India. 2. Department of Materials Science and Engineering, Monash University, Clayton, VIC, Australia. 3. IITB-Monash Research Academy, IIT Bombay, Mumbai, India. 4. Department of Electrical Engineering, IIT Bombay, Mumbai, India. slodha@ee.iitb.ac.in.
Abstract
Layered transition metal dichalcogenides have shown tremendous potential for photodetection due to their non-zero direct bandgaps, high light absorption coefficients and carrier mobilities, and ability to form atomically sharp and defect-free heterointerfaces. A critical and fundamental bottleneck in the realization of high performance detectors is their trap-dependent photoresponse that trades off responsivity with speed. This work demonstrates a facile method of attenuating this trade-off by nearly 2x through integration of a lateral, in-plane, electrostatically tunable p-n homojunction with a conventional WSe2 phototransistor. The tunable p-n junction allows modulation of the photocarrier population and width of the conducting channel independently from the phototransistor. Increased illumination current with the lateral p-n junction helps achieve responsivity enhancement upto 2.4x at nearly the same switching speed (14-16 µs) over a wide range of laser power (300 pW-33 nW). The added benefit of reduced dark current enhances specific detectivity (D*) by nearly 25x to yield a maximum measured flicker noise-limited D* of 1.1×1012 Jones. High responsivity of 170 A/W at 300 pW laser power along with the ability to detect sub-1 pW laser switching are demonstrated.
Layered tranpan class="Chemical">sition pan class="Chemical">metal dichalcogenides have shown tremendous potential for photodetection due to their non-zero direct bandgaps, high light absorption coefficients and carrier mobilities, and ability to form atomically sharp and defect-free heterointerfaces. A critical and fundamental bottleneck in the realization of high performance detectors is their trap-dependent photoresponse that trades off responsivity with speed. This work demonstrates a facile method of attenuating this trade-off by nearly 2x through integration of a lateral, in-plane, electrostatically tunable p-n homojunction with a conventional WSe2 phototransistor. The tunable p-n junction allows modulation of the photocarrier population and width of the conducting channel independently from the phototransistor. Increased illumination current with the lateral p-n junction helps achieve responsivity enhancement upto 2.4x at nearly the same switching speed (14-16 µs) over a wide range of laser power (300 pW-33 nW). The added benefit of reduced dark current enhances specific detectivity (D*) by nearly 25x to yield a maximum measured flicker noise-limited D* of 1.1×1012 Jones. High responsivity of 170 A/W at 300 pW laser power along with the ability to detect sub-1 pW laser switching are demonstrated.
Authors: Michele Buscema; Joshua O Island; Dirk J Groenendijk; Sofya I Blanter; Gary A Steele; Herre S J van der Zant; Andres Castellanos-Gomez Journal: Chem Soc Rev Date: 2015-06-07 Impact factor: 54.564
Authors: Riccardo Frisenda; Aday J Molina-Mendoza; Thomas Mueller; Andres Castellanos-Gomez; Herre S J van der Zant Journal: Chem Soc Rev Date: 2018-05-08 Impact factor: 54.564