Nematic Design for Shape Morphing

Daniel Duffy; John S. Biggins; Itay Griniasty; Xudong Yang; Mingchao Liu; K. Jimmy Hsia; Timothy J. White; Cyrus Mostajeran

doi:10.1146/annurev-control-030624-011240

Nematic Design for Shape Morphing

Daniel Duffy
, John S. Biggins
, Itay Griniasty
, Xudong Yang
, Mingchao Liu
, K. Jimmy Hsia
, Timothy J. White
, Cyrus Mostajeran^*

^*Corresponding author for this work

Mechanical Engineering

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

Abstract

The ability to induce desired shape and topographical changes in matter on demand is key to future advances in materials science and robotics. An important class of shape-morphing solids is characterized by spatially programmable anisotropic deformations that can be activated through a variety of stimuli, including light, heat, and pressure. We use the word nematic to describe such solids, borrowing a term from liquid crystal theory. We highlight the diversity of nematics that have been developed in recent years and review their distinguishing geometric and mechanical features, with a focus on thin shape-morphing sheets. We showcase how shape-morphing nematic systems can be designed to execute mechanical tasks. We end with an exploration of the challenges and opportunities involving the control of shape-morphing systems, which will be necessary for more advanced applications in robotics and is thus a key frontier in the field.

Original language	English
Number of pages	24
Journal	Annual Review of Control, Robotics, and Autonomous Systems
Volume	9
Issue number	13
Early online date	5 Dec 2025
DOIs	https://doi.org/10.1146/annurev-control-030624-011240
Publication status	E-pub ahead of print - 5 Dec 2025

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title = "Nematic Design for Shape Morphing",

abstract = "The ability to induce desired shape and topographical changes in matter on demand is key to future advances in materials science and robotics. An important class of shape-morphing solids is characterized by spatially programmable anisotropic deformations that can be activated through a variety of stimuli, including light, heat, and pressure. We use the word nematic to describe such solids, borrowing a term from liquid crystal theory. We highlight the diversity of nematics that have been developed in recent years and review their distinguishing geometric and mechanical features, with a focus on thin shape-morphing sheets. We showcase how shape-morphing nematic systems can be designed to execute mechanical tasks. We end with an exploration of the challenges and opportunities involving the control of shape-morphing systems, which will be necessary for more advanced applications in robotics and is thus a key frontier in the field.",

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AU - Duffy, Daniel

AU - Biggins, John S.

AU - Griniasty, Itay

AU - Yang, Xudong

AU - Liu, Mingchao

AU - Hsia, K. Jimmy

AU - White, Timothy J.

AU - Mostajeran, Cyrus

PY - 2025/12/5

Y1 - 2025/12/5

N2 - The ability to induce desired shape and topographical changes in matter on demand is key to future advances in materials science and robotics. An important class of shape-morphing solids is characterized by spatially programmable anisotropic deformations that can be activated through a variety of stimuli, including light, heat, and pressure. We use the word nematic to describe such solids, borrowing a term from liquid crystal theory. We highlight the diversity of nematics that have been developed in recent years and review their distinguishing geometric and mechanical features, with a focus on thin shape-morphing sheets. We showcase how shape-morphing nematic systems can be designed to execute mechanical tasks. We end with an exploration of the challenges and opportunities involving the control of shape-morphing systems, which will be necessary for more advanced applications in robotics and is thus a key frontier in the field.

AB - The ability to induce desired shape and topographical changes in matter on demand is key to future advances in materials science and robotics. An important class of shape-morphing solids is characterized by spatially programmable anisotropic deformations that can be activated through a variety of stimuli, including light, heat, and pressure. We use the word nematic to describe such solids, borrowing a term from liquid crystal theory. We highlight the diversity of nematics that have been developed in recent years and review their distinguishing geometric and mechanical features, with a focus on thin shape-morphing sheets. We showcase how shape-morphing nematic systems can be designed to execute mechanical tasks. We end with an exploration of the challenges and opportunities involving the control of shape-morphing systems, which will be necessary for more advanced applications in robotics and is thus a key frontier in the field.

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DO - 10.1146/annurev-control-030624-011240

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JO - Annual Review of Control, Robotics, and Autonomous Systems

JF - Annual Review of Control, Robotics, and Autonomous Systems

IS - 13

ER -

Nematic Design for Shape Morphing

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