Three-dimensional shrinking electronics on freestanding and freeform curvilinear surfaces

Yangbo Yuan; Dongliang Chen; Jianyu Li; Bowen Li; Abu Musa Abdullah; Fatema Tuz Zohra; Wanqing Zhang; Xianzhe Zhang; Xin Xin; Mohammad Ali Amidian; Ankan Dutta; Feifei Shi; Huanyu Cheng

doi:10.1126/sciadv.aea8051

Three-dimensional shrinking electronics on freestanding and freeform curvilinear surfaces

Yangbo Yuan
, Dongliang Chen
, Jianyu Li
, Bowen Li
, Abu Musa Abdullah
, Fatema Tuz Zohra
, Wanqing Zhang
, Xianzhe Zhang
, Xin Xin
, Mohammad Ali Amidian
, Ankan Dutta
, Feifei Shi
, Huanyu Cheng

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

1 Scopus citations

Abstract

Wearable electronics that adapt to three-dimensional (3D) surfaces are essential for next-generation smart internet of things (IoT), yet existing strategies remain limited because of fabrication complexity, material incompatibility, or poor structural control. Here, this work introduces a scalable yet versatile approach to design and fabricate 3D electronic systems by printing liquid metal patterns onto heat-shrinkable polymer substrates. Upon controlled thermal actuation, the 2D circuits transform into target 3D geometries with enhanced electrical performance. The resulting 3D shrinking electronics enable conformal antenna integration for IoT devices and gesture-interactive wearable interfaces. This low-cost, versatile platform offers a paradigm for customizable, shape-adaptive electronics in intelligent real and virtual environments.

Original language	English (US)
Article number	eaea8051
Pages (from-to)	1-12
Number of pages	12
Journal	Science Advances
Volume	11
Issue number	41
DOIs	https://doi.org/10.1126/sciadv.aea8051
State	Published - Oct 8 2025

All Science Journal Classification (ASJC) codes

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10.1126/sciadv.aea8051

Cite this

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title = "Three-dimensional shrinking electronics on freestanding and freeform curvilinear surfaces",

abstract = "Wearable electronics that adapt to three-dimensional (3D) surfaces are essential for next-generation smart internet of things (IoT), yet existing strategies remain limited because of fabrication complexity, material incompatibility, or poor structural control. Here, this work introduces a scalable yet versatile approach to design and fabricate 3D electronic systems by printing liquid metal patterns onto heat-shrinkable polymer substrates. Upon controlled thermal actuation, the 2D circuits transform into target 3D geometries with enhanced electrical performance. The resulting 3D shrinking electronics enable conformal antenna integration for IoT devices and gesture-interactive wearable interfaces. This low-cost, versatile platform offers a paradigm for customizable, shape-adaptive electronics in intelligent real and virtual environments.",

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AU - Yuan, Yangbo

AU - Chen, Dongliang

AU - Li, Jianyu

AU - Li, Bowen

AU - Abdullah, Abu Musa

AU - Zohra, Fatema Tuz

AU - Zhang, Wanqing

AU - Zhang, Xianzhe

AU - Xin, Xin

AU - Amidian, Mohammad Ali

AU - Dutta, Ankan

AU - Shi, Feifei

AU - Cheng, Huanyu

PY - 2025/10/8

Y1 - 2025/10/8

N2 - Wearable electronics that adapt to three-dimensional (3D) surfaces are essential for next-generation smart internet of things (IoT), yet existing strategies remain limited because of fabrication complexity, material incompatibility, or poor structural control. Here, this work introduces a scalable yet versatile approach to design and fabricate 3D electronic systems by printing liquid metal patterns onto heat-shrinkable polymer substrates. Upon controlled thermal actuation, the 2D circuits transform into target 3D geometries with enhanced electrical performance. The resulting 3D shrinking electronics enable conformal antenna integration for IoT devices and gesture-interactive wearable interfaces. This low-cost, versatile platform offers a paradigm for customizable, shape-adaptive electronics in intelligent real and virtual environments.

AB - Wearable electronics that adapt to three-dimensional (3D) surfaces are essential for next-generation smart internet of things (IoT), yet existing strategies remain limited because of fabrication complexity, material incompatibility, or poor structural control. Here, this work introduces a scalable yet versatile approach to design and fabricate 3D electronic systems by printing liquid metal patterns onto heat-shrinkable polymer substrates. Upon controlled thermal actuation, the 2D circuits transform into target 3D geometries with enhanced electrical performance. The resulting 3D shrinking electronics enable conformal antenna integration for IoT devices and gesture-interactive wearable interfaces. This low-cost, versatile platform offers a paradigm for customizable, shape-adaptive electronics in intelligent real and virtual environments.

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JO - Science Advances

JF - Science Advances

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M1 - eaea8051

ER -

Three-dimensional shrinking electronics on freestanding and freeform curvilinear surfaces

Abstract

All Science Journal Classification (ASJC) codes

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