# Unveiling Hidden Intramolecular Non‐Covalent Interactions in a Neutral Serine, Its Zwitterion, Cluster, and Crystal by Features of Electron Density

**Authors:** Vasilii Korotenko, Anna Egorova, Vladimir Tsirelson

PMC · DOI: 10.1002/jcc.70134 · 2025-06-30

## TL;DR

This paper identifies a new type of non-covalent interaction in serine and its forms, which contribute to molecular stability and change with molecular environment.

## Contribution

The study introduces 'latent' non-covalent interactions, classified as dynamic or static, and uses electronic pressure to analyze their behavior.

## Key findings

- Latent interactions are classified into dynamic and static types based on their electronic pressure signatures.
- Dynamic interactions show off-axis minima in exchange pressure, while static ones do not.
- Crystallization can eliminate latent interactions due to electron density redistribution and intermolecular hydrogen bonding.

## Abstract

We investigate intramolecular non‐covalent interactions (NCIs) in neutral serine, its zwitterion, molecular clusters, and crystal using electron density‐based approaches, including QTAIM, RDG, IQA, and electronic pressure analysis. In addition to completed NCIs (hydrogen bonds with bond paths), we identify latent interactions—attractive, bond‐path‐free atomic pair interactions with negative interaction energies. These are classified into dynamic (vibration‐induced and transient) and static (secondary, persistent but structurally passive) types. Analysis of the internal pressure in electronic continuum reveals that latent NCIs exhibit distinct signatures in the kinetic and exchange components, which evolve across the molecular, cluster, and crystalline states. Dynamic interactions are characterized by off‐axis minima in the exchange part of the pressure, whereas static interactions lack such features. Upon crystallization, intramolecular latent NCIs may disappear due to electron density redistribution and the formation of intermolecular hydrogen bonds. These intermolecular contacts may also spatially constrain atoms, suppressing vibrational flexibility and effectively converting dynamic NCIs into static ones. The kinetic pressure highlights regions of electron localization, while the exchange pressure offers a physical criterion for distinguishing different types of NCIs. Our findings demonstrate the structural and stabilizing roles of latent interactions and establish electronic pressure as a sensitive and informative descriptor for their analysis.

We reveal a new class of intramolecular noncovalent interactions called “latent” that lack bond paths yet stabilize molecules through subtle electronic effects. Using electron density and electronic pressure analysis, we classify them as “dynamic” or “static” and track their evolution across isolated molecules, molecular clusters, and crystals.

## Linked entities

- **Chemicals:** serine (PubChem CID 5951)

## Full-text entities

- **Chemicals:** Serine (MESH:D012694), hydrogen (MESH:D006859)

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12207953/full.md

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Source: https://tomesphere.com/paper/PMC12207953