Type and Degree of Covalence: Empirical Derivation and Implications

TL;DR

This paper introduces an experimental method to determine both the type and degree of covalence in chemical bonds, revealing insights into semiconductor properties and explaining phenomena like anti-bonding interactions in materials such as halide perovskites.

Contribution

The authors developed a novel, simple experimental approach to fully characterize covalent bonds, including their type and degree, which was previously unachievable.

Findings

Validated method with classical models and theoretical predictions.

Applied to ~40 semiconductors, revealing bond nature impacts properties.

Identified anti-bonding covalent interactions in certain materials.

Abstract

The way atoms attach to each other defines the function(s), e.g., mechanical, optical, electronic, of a given material. The nature of the chemical bond is, therefore, one of the most fundamental issues in materials. Both ionic interactions, i.e., resulting from electrical charges associated with the atoms, and covalent ones, i.e., the sharing of electrons between nuclei of different atoms, are usually viewed as forces that attract between atoms to form a rigid structure. Although less common for solid materials, it was shown theoretically to be possible for covalent interactions at the chemically-active electronic shell (or valence-band maximum) of semiconductors to reverse their more common nature and become repulsive, i.e., act against bonding. Some semiconductors with such predicted anti-bonding valence-band maximum levels (such as halide perovskites) show experimentally some amazing (opto-) electronic properties. Predictions that anti-bonding character can allow tolerance for existing defects, at least in part, can explain the superior properties of such semiconductors. Although there are known experimental ways to estimate the degree of the covalent nature (e.g., electronegativity), this was not possible hitherto for the type, i.e., distinguishing whether a material exhibits bonding or anti-bonding covalent interactions. We have developed a simple way to reveal the complete nature (both type and degree) of chemical bonds, using experimental data. After confirming our development with classical models and theoretical predictions, with a set of ~40 different functional semi-conductors, we show how knowledge of the complete nature of covalent bonding is of critical importance for fundamental properties of semiconductors.