# Density Functional Theory Insights into Polypyrrole-Based Functional Composites for Advanced Energy Storage, Sensing, and Environmental Applications

**Authors:** Oluwaseye Samson Adedoja, Rendani Wilson Maladzhi, Oludolapo Akanni Olanrewaju, Samson Oluropo Adeosun, Oluwatoyin Joseph Gbadeyan

PMC · DOI: 10.3390/nano16050285 · 2026-02-24

## TL;DR

This review explores how Density Functional Theory helps understand and optimize polypyrrole composites for energy, sensing, and environmental uses.

## Contribution

The paper provides the first systematic quantification of dopant steric effects in polypyrrole composites.

## Key findings

- DFT and TD-DFT studies reveal electronic, mechanical, and chemical behaviors of polypyrrole composites.
- Structure–property relationships are established through descriptors like charge transfer and interfacial binding energies.
- Dopant steric effects are linked to improved functional properties in next-generation applications.

## Abstract

Polypyrrole-based functional composites are increasingly explored and extensively adopted for energy storage, sensing, and environmental applications due to their tunable electronic properties, chemical versatility, and mechanical stability. However, rational optimization of these composites requires a unified understanding of electronic, mechanical, thermal, and chemical behavior at the atomic scale, which underlies their multifunctional behavior, and remains fragmented. Notably, Density Functional Theory (DFT) provides indispensable atomistic insight into the electronic, mechanical, thermal, and chemical interactions that govern the performance of multifunctional materials. To bridge these gaps, this review presents a comprehensive assessment of recent DFT and time-dependent DFT (TD-DFT) studies that elucidate the electronic, mechanical, thermal, and chemical characteristics of polypyrrole and its hybrid composites. Key theoretical descriptors, including electronic structure modulation, charge transfer behavior, adsorption energetics, interfacial binding energies, hydrogen bond formation, and charge redistribution, are critically assessed to establish structure–property relationships across diverse functional systems. Considerable attention is given to interfacial interactions, doping strategies, and composite architectures that govern durability, conductivity, and chemical stability. By consolidating current atomistic insights and identifying existing limitations, this review provides a coherent framework for rational material design. Notably, it presents the first systematic quantification of dopant steric effects in PPy multifunctional composites, linking atomistic-scale modifications to the optimization of functional properties in next-generation applications.

## Full-text entities

- **Chemicals:** hydrogen (MESH:D006859), Polypyrrole (MESH:C067635)

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12986536/full.md

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Source: https://tomesphere.com/paper/PMC12986536