Surface Functionalization of Black Phosphorus via
Potassium toward High-Performance Complementary Devices
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Abstract
Two-dimensional
black phosphorus configured field-effect transistor
devices generally show a hole-dominated ambipolar transport characteristic,
thereby limiting its applications in complementary electronics. Herein,
we demonstrate an effective surface functionalization scheme on few-layer
black phosphorus, through in situ surface modification with potassium,
with a view toward high performance complementary device applications.
Potassium induces a giant electron doping effect on black phosphorus
along with a clear bandgap reduction, which is further corroborated
by in situ photoelectron spectroscopy characterizations. The electron
mobility of black phosphorus is significantly enhanced to 262 (377)
cm<sup>2</sup> V<sup>–1</sup> s<sup>–1</sup> by over
1 order of magnitude after potassium modification for two-terminal
(four-terminal) measurements. Using lithography technique, a spatially
controlled potassium doping technique is developed to establish high-performance
complementary devices on a single black phosphorus nanosheet, for
example, the p–n homojunction-based diode achieves a near-unity
ideality factor of 1.007 with an on/off ratio of ∼10<sup>4</sup>. Our findings coupled with the tunable nature of in situ modification
scheme enable black phosphorus as a promising candidate for further
complementary electronics