graphene, however, is problematic for many optoelectronic applications. Semiconducting layered metal dichalcogenides (LMDs) have generated an immense amount of interest, owing to their specific bandgaps in the ≈1-2.4 eV range. [2] Most LMDs undergo a transition from an indirect bandgap material in the multilayer form to a direct bandgap material in the monolayer form and exhibit strong lightmatter interaction at the 2D limit. [3,4] All of these features make 2D LMDs promising materials for several applications, such as transistors [5] and optoelectronic [6] and valleytronic [7] devices. Nonetheless, the finite bandgap of such reported LMDs largely restricts their applications in IR and ultraviolet (UV) photodetection. [8] UV photodetection, particularly in the solar blind range (200 to 280 nm), has great potential in the missile detection, flame alarms, and so forth. However, the lack of wide bandgap LMD materials makes realizing 2D UV photodetectors a challenge.As a new important member of the LMD family, germanium diselenide (GeSe 2 ), with a direct wide bandgap, has many potential applications in UV detection and IR waveguides. [9] Moreover, GeSe 2 exhibits a monoclinic crystal structure, [10] within two crystallographically different types of GeSe 4/2 tetrahedra centered on the Ge1 and Ge2 atoms, as shown in As an important 2D layered metal dichalcogenide, germanium diselenide (GeSe 2 ) with a direct wide bandgap is attracting increasing attention for its potential applications in ultraviolet (UV) detection. However, only few-layer GeSe 2 has been reported to date. Here, a joint theoretical-experimental study on the optical and electronic properties of monolayer GeSe 2 is presented, and monolayer GeSe 2 is shown to have a direct wide bandgap of 2.96 eV. Consequently, monolayer GeSe 2 does not respond to a major fraction of the visible spectrum. Notably, the photofield effect transistors based on the GeSe 2 monolayer show p-type behavior, high responsivity, superior detectivity, and a fast response time, competitive with state-of-the-art UV detectors. In addition to the excellent photoresponse properties, 2D GeSe 2 crystals also exhibit perpendicular optical reversal of the linear dichroism and polarized photodetection under wavelength modulation. Theoretical calculations of the band structure are used to shed light on these experimental results. The findings suggest that 2D GeSe 2 is a promising candidate for highly selective polarization-sensitive UV detection.
