# Triboelectric Nanogenerators for Thermal Management Application: Current Progress and Future Prospects

**Authors:** Jia-Qi Lang, Lei Chen, Xing-Xiang Ji, Qi Liu, Ming-Guo Ma

PMC · DOI: 10.1007/s40820-026-02110-1 · Nano-Micro Letters · 2026-03-05

## TL;DR

This paper reviews how triboelectric nanogenerators can be used for thermal management, focusing on materials and integration with energy systems.

## Contribution

A systematic review of triboelectric nanogenerators for thermal management, highlighting bidirectional coupling mechanisms and material innovations.

## Key findings

- Triboelectric materials like graphene and MXene are key for thermal management in nanogenerators.
- Bidirectional coupling between charge generation and thermal management is critical for device performance.
- Integration of TM-TENGs offers potential in thermal conversion, energy harvesting, and storage.

## Abstract

A systematic review of recent advances of the process of friction nanogenerator participates in the different thermal management of materials through contact and non-contact thermal sensing.Triboelectric materials participated in the application of the whole process of thermal management are reviewed based on the up-to-date works.Prospects and challenges for future need for advanced and thermoelectric device designs and integration with existing energy technologies are discussed.

A systematic review of recent advances of the process of friction nanogenerator participates in the different thermal management of materials through contact and non-contact thermal sensing.

Triboelectric materials participated in the application of the whole process of thermal management are reviewed based on the up-to-date works.

Prospects and challenges for future need for advanced and thermoelectric device designs and integration with existing energy technologies are discussed.

The rapid development of wearable electronics, self-powered systems, and the Internet of Things urgently requires efficient thermal management (TM) technologies and sustainable energy solutions. However, triboelectric nanogenerator (TENG) and their integrated electronic components inevitably generate or accumulate Joule thermal. It led to performance degradation or even device failure. This review focuses on the research progress in integrating advanced TM technologies into TENGs, aiming to provide comprehensive insights for constructing high-performance and highly stable self-powered systems. The scope of this review encompasses: (i) systematically summarizing the design and development of TM-TENG systems based on key materials, such as graphene, carbon nanotubes, MXene, cellulose, and phase change materials, (ii) elucidating the bidirectional coupling mechanism between triboelectric charge generation and thermal management, along with a critical analysis of existing theoretical models, and (iii) detailing the multifunctional integration and applications potential of TM-TENGs in the fields including thermal conversion, thermal energy harvesting, storage, actuation, and conduction. The bidirectional coupling mechanisms between triboelectric charge generation and thermal management are thoroughly dissected at a theoretical level. The predominant physical models explaining the interaction phenomena between frictional heating and thermal management are reviewed, with critical analysis of their applicability and limitations. Furthermore, this work discusses the current challenges and future directions in this field and proposes strategic recommendations for realizing more advanced TM-TENG systems. The primary objectives of this review are to synthesize existing knowledge, clarify interaction mechanisms, and promote interdisciplinary development at the intersection of thermal management and energy harvesting.

## Full-text entities

- **Genes:** PCDHA7 (protocadherin alpha 7) [NCBI Gene 56141] {aka CNR4, CNRN4, CNRS4, CRNR4, PCDH-ALPHA7}
- **Diseases:** PCM (MESH:D000210), autism (MESH:D001321), TEMS (MESH:D020886), skin irritation (MESH:D012871), LM (MESH:D013651), NC-TENG (MESH:D003877), SE- (MESH:C537734), cytotoxicity (MESH:D064420), fire (MESH:D000092422)
- **Chemicals:** PCMs (MESH:C045667), barium titanate (MESH:C024547), nitric oxide (MESH:D009569), polyethylene (MESH:D020959), poly(3,4-ethylenedioxythiophene) (MESH:C121383), boron nitride (MESH:C017282), Silver (MESH:D012834), fluorinated ethylene propylene (MESH:C096305), CaCl2 (MESH:D002122), PDA (MESH:C568283), aluminum nitride (MESH:C052045), hydroxypropyl cellulose (MESH:C008079), iron (MESH:D007501), aluminum oxide (MESH:D000537), ZnO (MESH:D015034), polyaniline (MESH:C416807), water (MESH:D014867), fluorine (MESH:D005461), SMP (MESH:C063925), Carbon (MESH:D002244), Ecoflex (MESH:C472388), polyacrylamide (MESH:C016679), Polymer (MESH:D011108), cellulose diacetate (MESH:C026170), nitrogen dioxide (MESH:D009585), COF (MESH:D000073396), PPy (MESH:C067635), nickel (MESH:D009532), GO (MESH:C000628730), hc- (MESH:D006854), PEG (MESH:D011092), carboxylic acid (MESH:D002264), nitrogen (MESH:D009584), chitosan (MESH:D048271), salt (MESH:D012492), poly(styrene sulfonate) (MESH:C003321), black phosphorus (MESH:D010758), oxygen (MESH:D010100), PTFE (MESH:D011138), Metal (MESH:D008670), MoS2 (MESH:C082964), PU (MESH:D011005), nylon (MESH:D009757), phytic acid (MESH:D010833), PW (MESH:D010232), PRS (MESH:D011221), AA (MESH:C036658), BN (MESH:C072598), NR (MESH:C018613), PPS (MESH:C041325), indium (MESH:D007204), gallium (MESH:D005708), MnCO3 (MESH:C045327), PVDF (MESH:C024865), alcohols (MESH:D000438), Zylon (MESH:C450140), lithium chloride (MESH:D018021), 3-chloropropyltrimethoxysilane (MESH:C548971), Cellulose (MESH:D002482), MXene (MESH:C000723374)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12963624/full.md

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Source: https://tomesphere.com/paper/PMC12963624