High-performance n-type flexible inorganic thermoelectric aerogel for energy harvesting

Xiaodong Wang; Wenbo Zhu; Yijie Liu; Shuaihang Hou; Li Yin; Jinxuan Cheng; Peng Zhao; Feng Jiang; Sichen Duan; Wenhua Xue; Yumei Wang; Xuesong Leng; Feng Cao; Jun Mao; Mingyu Li; Qian Zhang

doi:10.1126/sciadv.ady7679

High-performance n-type flexible inorganic thermoelectric aerogel for energy harvesting

Xiaodong Wang
, Wenbo Zhu
, Yijie Liu
, Shuaihang Hou
, Li Yin
, Jinxuan Cheng
, Peng Zhao
, Feng Jiang
, Sichen Duan
, Wenhua Xue
, Yumei Wang
, Xuesong Leng
, Feng Cao^*
, Jun Mao
, Mingyu Li
, Qian Zhang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Despite their promise as lightweight, ultralow–thermal-conductivity thermoelectric (TE) materials, aerogels have been largely limited to p-type organic or carbon-based systems with modest zT < 0.1 at 300 kelvin. Here, we propose a stepwise synthesis strategy that yields the first inorganic aerogel exhibiting state-of- the- art n-type TE performance. Optimized aerogels with 95% porosity exhibit a high power factor of 34.8 microwatts per meter per square kelvin and an ultralow thermal conductivity of 0.061 microwatts per meter per kelvin, resulting in zT values of 0.17 at 300 kelvin and 0.24 at 383 kelvin. A vertical TE generator prototype with six TE-aerogel legs achieves a gravimetric output power of 76 microwatts per gram under a ΔT of ~60 kelvin. To address brittleness, a polyimide-encapsulated aerogel with bioinspired architecture was developed, achieving a high compressive strength to 1.4 kilopascals while maintaining excellent TE performance. This work establishes a generalizable method for designing high-performance flexible inorganic aerogels, opening more possibilities for lightweight wearable energy harvesting technologies.

Original language	English
Journal	Science Advances
Volume	12
Issue number	2
DOIs	https://doi.org/10.1126/sciadv.ady7679
State	Published - 2026

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@article{a23bf088f75b4c1185286a62590f256d,

title = "High-performance n-type flexible inorganic thermoelectric aerogel for energy harvesting",

abstract = "Despite their promise as lightweight, ultralow–thermal-conductivity thermoelectric (TE) materials, aerogels have been largely limited to p-type organic or carbon-based systems with modest zT < 0.1 at 300 kelvin. Here, we propose a stepwise synthesis strategy that yields the first inorganic aerogel exhibiting state-of- the- art n-type TE performance. Optimized aerogels with 95\% porosity exhibit a high power factor of 34.8 microwatts per meter per square kelvin and an ultralow thermal conductivity of 0.061 microwatts per meter per kelvin, resulting in zT values of 0.17 at 300 kelvin and 0.24 at 383 kelvin. A vertical TE generator prototype with six TE-aerogel legs achieves a gravimetric output power of 76 microwatts per gram under a ΔT of \textasciitilde{}60 kelvin. To address brittleness, a polyimide-encapsulated aerogel with bioinspired architecture was developed, achieving a high compressive strength to 1.4 kilopascals while maintaining excellent TE performance. This work establishes a generalizable method for designing high-performance flexible inorganic aerogels, opening more possibilities for lightweight wearable energy harvesting technologies.",

author = "Xiaodong Wang and Wenbo Zhu and Yijie Liu and Shuaihang Hou and Li Yin and Jinxuan Cheng and Peng Zhao and Feng Jiang and Sichen Duan and Wenhua Xue and Yumei Wang and Xuesong Leng and Feng Cao and Jun Mao and Mingyu Li and Qian Zhang",

year = "2026",

doi = "10.1126/sciadv.ady7679",

language = "英语",

volume = "12",

journal = "Science Advances",

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publisher = "American Association for the Advancement of Science",

number = "2",

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TY - JOUR

T1 - High-performance n-type flexible inorganic thermoelectric aerogel for energy harvesting

AU - Wang, Xiaodong

AU - Zhu, Wenbo

AU - Liu, Yijie

AU - Hou, Shuaihang

AU - Yin, Li

AU - Cheng, Jinxuan

AU - Zhao, Peng

AU - Jiang, Feng

AU - Duan, Sichen

AU - Xue, Wenhua

AU - Wang, Yumei

AU - Leng, Xuesong

AU - Cao, Feng

AU - Mao, Jun

AU - Li, Mingyu

AU - Zhang, Qian

PY - 2026

Y1 - 2026

N2 - Despite their promise as lightweight, ultralow–thermal-conductivity thermoelectric (TE) materials, aerogels have been largely limited to p-type organic or carbon-based systems with modest zT < 0.1 at 300 kelvin. Here, we propose a stepwise synthesis strategy that yields the first inorganic aerogel exhibiting state-of- the- art n-type TE performance. Optimized aerogels with 95% porosity exhibit a high power factor of 34.8 microwatts per meter per square kelvin and an ultralow thermal conductivity of 0.061 microwatts per meter per kelvin, resulting in zT values of 0.17 at 300 kelvin and 0.24 at 383 kelvin. A vertical TE generator prototype with six TE-aerogel legs achieves a gravimetric output power of 76 microwatts per gram under a ΔT of ~60 kelvin. To address brittleness, a polyimide-encapsulated aerogel with bioinspired architecture was developed, achieving a high compressive strength to 1.4 kilopascals while maintaining excellent TE performance. This work establishes a generalizable method for designing high-performance flexible inorganic aerogels, opening more possibilities for lightweight wearable energy harvesting technologies.

AB - Despite their promise as lightweight, ultralow–thermal-conductivity thermoelectric (TE) materials, aerogels have been largely limited to p-type organic or carbon-based systems with modest zT < 0.1 at 300 kelvin. Here, we propose a stepwise synthesis strategy that yields the first inorganic aerogel exhibiting state-of- the- art n-type TE performance. Optimized aerogels with 95% porosity exhibit a high power factor of 34.8 microwatts per meter per square kelvin and an ultralow thermal conductivity of 0.061 microwatts per meter per kelvin, resulting in zT values of 0.17 at 300 kelvin and 0.24 at 383 kelvin. A vertical TE generator prototype with six TE-aerogel legs achieves a gravimetric output power of 76 microwatts per gram under a ΔT of ~60 kelvin. To address brittleness, a polyimide-encapsulated aerogel with bioinspired architecture was developed, achieving a high compressive strength to 1.4 kilopascals while maintaining excellent TE performance. This work establishes a generalizable method for designing high-performance flexible inorganic aerogels, opening more possibilities for lightweight wearable energy harvesting technologies.

UR - https://www.scopus.com/pages/publications/105027100002

U2 - 10.1126/sciadv.ady7679

DO - 10.1126/sciadv.ady7679

M3 - 文章

C2 - 41512076

AN - SCOPUS:105027100002

SN - 2375-2548

VL - 12

JO - Science Advances

JF - Science Advances

IS - 2

ER -

High-performance n-type flexible inorganic thermoelectric aerogel for energy harvesting

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