Ashley Shin1,Azmain Hossain2,Stephanie Tenney1,Xuanheng Tan1,Lauren Tan1,Jonathan Foley IV3,Timothy Atallah4,Justin Caram1
University of California Los Angeles1,California Institute of Technology2,William Paterson University of New Jersey3,Denison University4
Ashley Shin1,Azmain Hossain2,Stephanie Tenney1,Xuanheng Tan1,Lauren Tan1,Jonathan Foley IV3,Timothy Atallah4,Justin Caram1
University of California Los Angeles1,California Institute of Technology2,William Paterson University of New Jersey3,Denison University4
The influence of external dielectric environments is well understood for 2D semiconductor materials but overlooked for colloidally grown II–VI nanoplatelets (NPLs). In this work, we synthesize MX (M = Cd, Hg; X = Se, Te) NPLs of varying thicknesses and apply the Elliott model to extract exciton binding energies—reporting values in good agreement with prior methods and extending to less studied cadmium telluride and mercury chalcogenide NPLs. We find that the exciton binding energy is modulated both by the relative effect of internal vs external dielectric and by the thickness of the semiconductor material. An analytical model shows dielectric screening increases the exciton binding energy relative to the bulk by distorting the Coulombic potential across the NPL surface. We further confirm this effect by decreasing and recovering the exciton binding energy of HgTe NPLs through washing in polarizable solvents. Our results illustrate NPLs are colloidal analogues of van der Waals 2D semiconductors and point to surface modification as an approach to control photophysics and device properties.