Issue 45, 2020

The role of ligands in electron transport in nanocrystal solids

Abstract

We investigate theoretically the transport of electrons and holes in crystalline solids consisting of three-dimensional arrays of semiconductor nanocrystals passivated by two types of organic ligands—linear chain carboxylates and functionalized aromatic cinnamates. We focus on a critical quantity in transport: the quantum-mechanical overlap of the strongly confined electron and hole wavefunctions on neighboring nanocrystals. Using results from density-functional-theory (DFT) calculations, we construct a one-dimensional model system whose analytic wavefunctions reproduce the full DFT numerical overlap values. By investigating the analytic behavior of this model, we reveal several important features of electron transport. The most significant is that the wavefunction overlap decays exponentially with ligand length, with a characteristic decay length that depends primarily on properties of the ligand and is almost independent of the size and type of nanocrystal. Functionalization of the ligands can also affect the overlap by changing the height of the tunneling barrier. The physically transparent analytic expressions we obtain for the wavefunction overlap and its decay length should be useful for future efforts to control transport in nanocrystal solids.

Graphical abstract: The role of ligands in electron transport in nanocrystal solids

Supplementary files

Article information

Article type
Paper
Submitted
25 sept. 2020
Accepted
09 nov. 2020
First published
10 nov. 2020

Nanoscale, 2020,12, 23028-23035

Author version available

The role of ligands in electron transport in nanocrystal solids

A. R. Khabibullin, A. L. Efros and S. C. Erwin, Nanoscale, 2020, 12, 23028 DOI: 10.1039/D0NR06892F

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