https://techxplore.com/news/2025-10-chinese-lantern-shifts-dozen-applications.html

logotype
Topics

  * Week's top
  * Latest news
  * Unread news
  * Subscribe

[                    ]
 

Science X Account

[                    ]
[                    ]
Sign In

Sign in with    

Forget Password?

Not a member? Sign up

Learn more

  * Automotive
  * Business
  * Computer Sciences
  * Consumer & Gadgets
  * Electronics & Semiconductors
  * Energy & Green Tech
  * Engineering
  * Hardware
  * Hi Tech & Innovation
  * Internet
  * Machine learning & AI
  * Other
  * Robotics
  * Security
  * Software
  * Telecom

[INS::INS]

  * 
  * share this!

  *  

    30

  *  

    Tweet

  *  

    Share

  *  

    Email

 1. Home
 2. Engineering

 1. Home
 2. Hi Tech & Innovation

  *  
  *  
  *  

---------------------------------------------------------------------
 

October 10, 2025

The GIST

'Chinese lantern' structure shifts into more than a dozen shapes for
various applications

by North Carolina State University

edited by Stephanie Baum, reviewed by Robert Egan

[stephanie]

Stephanie Baum

scientific editor

Meet our editorial team
Behind our editorial process
[Robert]

Robert Egan

associate editor

Meet our editorial team
Behind our editorial process
Editors' notes

This article has been reviewed according to Science X's editorial
process and policies. Editors have highlighted the following
attributes while ensuring the content's credibility:

fact-checked

peer-reviewed publication

trusted source

proofread

'Chinese lantern' structure shifts into more than a dozen shapes for
various applications Researchers have created a polymer "Chinese
lantern" that can snap into more than a dozen curved,
three-dimensional shapes by compressing or twisting the original
structure. This rapid shape-shifting behavior can be controlled
remotely using a magnetic field, allowing the structure to be used
for a variety of applications. Credit: Yaoye Hong, NC State
University

Researchers have created a polymer "Chinese lantern" that can snap
into more than a dozen curved, three-dimensional shapes by
compressing or twisting the original structure. This rapid
shape-shifting behavior can be controlled remotely using a magnetic
field, allowing the structure to be used for a variety of
applications.

The corresponding research paper, "Reprogrammable snapping
morphogenesis in freestanding ribbon-cluster meta-units via stored
elastic energy," is published in Nature Materials.

The paper was co-authored by Caizhi Zhou and Haitao Qing, both Ph.D.
students at NC State; and by Yinding Chi, a former Ph.D. student at
NC State who is now a postdoctoral researcher at Penn.

The basic lantern object is made by cutting a polymer sheet into a
diamond-like parallelogram shape, then cutting a row of parallel
lines across the center of each sheet. This creates a row of
identical ribbons connected by a solid strip of material at the top
and bottom of the sheet. By connecting the left and right ends of the
solid strips at top and bottom, the polymer sheet forms a
three-dimensional shape resembling a roughly spherical Chinese
lantern.

Credit: Yin Lab at NCSU

"This basic shape is, by itself, bistable," says Jie Yin,
corresponding author of a paper on the work and a professor of
mechanical and aerospace engineering at North Carolina State
University. "In other words, it has two stable forms. It is stable in
its lantern shape, of course. But if you compress the structure,
pushing down from the top, it will slowly begin to deform until it
reaches a critical point, at which point it snaps into a second
stable shape that resembles a spinning top.

[INS::INS]

"In the spinning-top shape, the structure has stored all of the
energy you used to compress it. So, once you begin to pull up on the
structure, you will reach a point where all of that energy is
released at once, causing it to snap back into the lantern shape very
quickly."

"We found that we could create many additional shapes by applying a
twist to the shape, by folding the solid strips at the top or bottom
of the lantern in or out, or any combination of those things," says
Yaoye Hong, first author of the paper and a former Ph.D. student at
NC State who is now a postdoctoral researcher at the University of
Pennsylvania.

"Each of these variations is also multistable. Some can snap back and
forth between two stable states. One has four stable states,
depending on whether you're compressing the structure, twisting the
structure, or compressing and twisting the structure simultaneously."

'Chinese lantern' structure shifts into more than a dozen shapes for
various applications The basic lantern object is made by cutting a
polymer sheet into a diamond-like parallelogram shape, then cutting a
row of parallel lines across the center of each sheet. This creates a
row of identical ribbons that is connected by a solid strip of
material at the top and bottom of the sheet. By connecting the left
and right ends of the solid strips at top and bottom, the polymer
sheet forms a three-dimensional shape resembling a roughly spherical
Chinese lantern. Credit: Yaoye Hong, NC State University

By attaching a thin magnetic film to the solid strip at the bottom of
the structure, the researchers were able to compress or twist the
structures remotely, using a magnetic field. They then demonstrated
several applications that made use of snapping between two stable
shapes. These applications included a noninvasive gripper for
grasping fish; a filter that opened and closed to control the flow of
water; and a compact shape that rapidly expanded into a tall shape to
open a collapsed tube.

The researchers also developed a mathematical model that captures the
way in which different angles in the structure control both the shape
of each variation and the amount of energy that is stored in each
stable state.

"This model allows us to program the shape we want to create, how
stable it is, and how powerful it can be when stored potential energy
is allowed to snap into kinetic energy," says Hong. "And all of those
things are critical for creating shapes that can perform desired
applications."

"Moving forward, these lantern units can be assembled into 2D and 3D
architectures for broad applications in shape-morphing mechanical
metamaterials and robotics," says Yin. "We will be exploring that."

More information: Reprogrammable snapping morphogenesis in
ribbon-cluster meta-units using stored elastic energy, Nature
Materials (2025). DOI: 10.1038/s41563-025-02370-z.
Journal information: Nature Materials  
Provided by North Carolina State University  
Citation: 'Chinese lantern' structure shifts into more than a dozen
shapes for various applications (2025, October 10) retrieved 1
November 2025 from https://techxplore.com/news/
2025-10-chinese-lantern-shifts-dozen-applications.html
This document is subject to copyright. Apart from any fair dealing
for the purpose of private study or research, no part may be
reproduced without the written permission. The content is provided
for information purposes only.
---------------------------------------------------------------------

Explore further

Set it and forget it: Autonomous structures can be programmed to
jump, days in advance
---------------------------------------------------------------------
30 shares

  *  

    Facebook

  *  

    Twitter

  *  

    Email

 

Feedback to editors

  * Featured
  * Last Comments
  * Popular

New diode chain could be used to develop high-power terahertz
technologies

Oct 31, 2025

0

RRAM-based analog computing system rapidly solves matrix equations
with high precision

Oct 30, 2025

0

The great search divide: How AI and traditional web searches differ

Oct 29, 2025

0

AI efficiency advances with spintronic memory chip that combines
storage and processing

Oct 29, 2025

0

Beneath the waves: Floating solar panels are stressing the seafloor

Oct 29, 2025

0

---------------------------------------------------------------------
[gif]

Concentration-controlled doping turns a p-type polymer semiconductor
into its n-type counterpart

Oct 31, 2025

[gif]

Sunlight split in two: Organic layer promises leap in solar power
efficiency

Oct 31, 2025

[gif]

3D porous structure promises safer, longer-lasting lithium-metal
batteries for electric vehicles

Oct 31, 2025

[gif]

Unlocking next-generation battery performance: Fluoride-based solid
electrolyte surpasses voltage limits

Oct 31, 2025

[gif]

Empowering consumers, not algorithms, can boost sales, reduce returns
and redefine the future of AI

Oct 31, 2025

[gif]

Electronic fiber with liquid metal droplets enables stretchable
sensing

Oct 31, 2025

[gif]

Iron-based battery material achieves higher energy state, promising
improved storage and voltage

Oct 31, 2025

[gif]

Ubiquitous polymer forms self-healing, flexible conductor for
wearable electronics

Oct 31, 2025

[gif]

New diode chain could be used to develop high-power terahertz
technologies

Oct 31, 2025

[gif]

NASA takes one step closer to launching quiet supersonic jets

Oct 31, 2025

[INS::INS]

  * Related Stories

    [gif]

    Set it and forget it: Autonomous structures can be programmed to
    jump, days in advance

    Jun 2, 2025

    [gif]

    Fidget-controlled robots show the power of metastability

    Sep 30, 2025

    [gif]

    Technique speeds up thermal actuation for soft robotics

    Dec 13, 2021

    [gif]

    Engineers design origami structures that change shape and
    stiffness on demand

    Sep 6, 2025

    [gif]

    Shape-shifting materials with infinite possibilities

    Oct 22, 2021

    [gif]

    Shape-shifting 'transformer bots' inspired by origami

    Jul 29, 2024

  * Recommended for you

    [gif]

    New diode chain could be used to develop high-power terahertz
    technologies

    Oct 31, 2025

    [gif]

    Sunlight split in two: Organic layer promises leap in solar power
    efficiency

    Oct 31, 2025

    [gif]

    Unlocking next-generation battery performance: Fluoride-based
    solid electrolyte surpasses voltage limits

    Oct 31, 2025

    [gif]

    Concentration-controlled doping turns a p-type polymer
    semiconductor into its n-type counterpart

    Oct 31, 2025

    [gif]

    Electronic fiber with liquid metal droplets enables stretchable
    sensing

    Oct 31, 2025

    [gif]

    Ubiquitous polymer forms self-healing, flexible conductor for
    wearable electronics

    Oct 31, 2025

Load comments (0)

Get Instant Summarized Text (Gist)

A polymer structure inspired by the Chinese lantern can rapidly shift
into over a dozen distinct, multistable 3D shapes through compression
or twisting, with transitions controlled remotely via a magnetic
field. A mathematical model enables precise programming of shape,
stability, and energy storage, supporting applications in soft
robotics, adaptive filters, and noninvasive gripping devices.

This summary was automatically generated using LLM. Full disclaimer

Let us know if there is a problem with our content

Use this form if you have come across a typo, inaccuracy or would
like to send an edit request for the content on this page. For
general inquiries, please use our contact form. For general feedback,
use the public comments section below (please adhere to guidelines).

Please select the most appropriate category to facilitate processing
of your request

[-- please select one --      ]
                            [                    ]
                            [                    ]
                            [                    ]
                            [                    ]
                            [                    ]
Your message to the editors [                    ]
Your email (optional, only if you'd like a response)
[                    ]
Send Feedback

Thank you for taking time to provide your feedback to the editors.

Your feedback is important to us. However, we do not guarantee
individual replies due to the high volume of messages.

E-mail the story

'Chinese lantern' structure shifts into more than a dozen shapes for
various applications

Your friend's email [                    ]
Your email [                    ]
[ ] I would like to subscribe to Science X Newsletter. Learn more
Your name [                    ]

Note

Your email address is used only to let the recipient know who sent
the email. Neither your address nor the recipient's address will be
used for any other purpose. The information you enter will appear in
your e-mail message and is not retained by Tech Xplore in any form.

             [                    ]
             [                    ]
             [                    ]
             [                    ]
             [                    ]
             [                    ]
             [                    ]
Your message [                    ]
Send
Phys.org logotype

Phys.org

Daily science news on research developments and the latest scientific
innovations

MedicalXpress logotype

Medical Xpress

Medical research advances and health news

ScienceX logotype

Science X

The most comprehensive sci-tech news coverage on the web

Newsletters

[                    ]
Subscribe
Science X Daily and the Weekly Email Newsletter are free features
that allow you to receive your favorite sci-tech news updates in your
email inbox
Follow us

  *  
  *  
  *  
  *  
  *  
  *  
  *  

  * Top
  * Home
  * Search
  * Mobile version

  * Help
  * FAQ
  * About
  * Contact

  * Support us
  * Science X Account
  * Newsletter
  * Archive

  * Android app
  * iOS app
  * RSS feeds
  * Push notification

(c) Tech Xplore 2014 - 2025 powered by Science X Network
Privacy policy Terms of use

Your Privacy

This site uses cookies to assist with navigation, analyse your use of
our services, collect data for ads personalisation and provide
content from third parties. By using our site, you acknowledge that
you have read and understand our Privacy Policy and Terms of Use.

I'm OK with that Cookie options

E-mail newsletter

[                    ]
Subscribe
Follow us

  *  
  *  
  *  
  *  

It appears that you are currently using Ad Blocking software. What
are the consequences? x
Quantcast