TY - JOUR
T1 - Adaptive Energy Dissipator with Compression-to-Tension Design
AU - Ye, Haitao
AU - Li, Chong
AU - Yu, Shouyi
AU - Li, Honggeng
AU - Lian, Yiling
AU - He, Xiangnan
AU - Chen, Juzheng
AU - Huang, Xingjian
AU - Jin, Liuchao
AU - Cheng, Jianxiang
AU - Wang, Rong
AU - Huang, Lixi
AU - Zhang, Biao
AU - Song, Xu
AU - Lu, Yang
AU - Ge, Qi
PY - 2025/10/15
Y1 - 2025/10/15
N2 - Energy-dissipating materials are vital for daily life and engineering applications. Among all the energy-dissipating materials, the polymer-based ones are reusable and loading rate-dependent, but suffer from two limitations: i) they cannot synchronously achieve high loss factor and high modulus; ii) their stretch-induced high energy dissipation capability cannot be fully used in compression-dominated applications. To address them, a high-energy-dissipating (HED) polymer is reported with two types of dynamic physical crosslinks (hydrogen bonds and dynamic coordination bonds) to obtain a high loss factor (tanδ up to 2), modulus (110.5 MPa), and dissipated energy density (26.8 J cm-3). To fully liberate its stretch-dominated dissipation under compression, HED-based compression-to-tension (C2T) structures are designed that convert compression into tension on the HED strips. Multimaterial 3D printing is utilized to fabricate such C2T structures whose energy dissipation capability is tunable and ≈100 times higher than that of HED-based octet lattices. Furthermore, the C2T structures are used to develop artificial intervertebral discs and low-frequency vibration isolators to demonstrate their adaptive capability of dissipating impact and vibration energies in bio-implants and precision instruments. The proposed HED polymers and their C2T structures offer a new way to design and develop high-performance energy-dissipating metadevices. © 2025 Wiley-VCH GmbH.
AB - Energy-dissipating materials are vital for daily life and engineering applications. Among all the energy-dissipating materials, the polymer-based ones are reusable and loading rate-dependent, but suffer from two limitations: i) they cannot synchronously achieve high loss factor and high modulus; ii) their stretch-induced high energy dissipation capability cannot be fully used in compression-dominated applications. To address them, a high-energy-dissipating (HED) polymer is reported with two types of dynamic physical crosslinks (hydrogen bonds and dynamic coordination bonds) to obtain a high loss factor (tanδ up to 2), modulus (110.5 MPa), and dissipated energy density (26.8 J cm-3). To fully liberate its stretch-dominated dissipation under compression, HED-based compression-to-tension (C2T) structures are designed that convert compression into tension on the HED strips. Multimaterial 3D printing is utilized to fabricate such C2T structures whose energy dissipation capability is tunable and ≈100 times higher than that of HED-based octet lattices. Furthermore, the C2T structures are used to develop artificial intervertebral discs and low-frequency vibration isolators to demonstrate their adaptive capability of dissipating impact and vibration energies in bio-implants and precision instruments. The proposed HED polymers and their C2T structures offer a new way to design and develop high-performance energy-dissipating metadevices. © 2025 Wiley-VCH GmbH.
KW - adaptive energy dissipation
KW - energy dissipating material
KW - mechanical design
KW - multimaterial 3D printing
KW - rate dependent
UR - https://www.webofscience.com/wos/woscc/full-record/WOS:001594599600001
UR - http://www.scopus.com/inward/record.url?scp=105019098398&partnerID=8YFLogxK
UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-105019098398&origin=recordpage
U2 - 10.1002/adfm.202521393
DO - 10.1002/adfm.202521393
M3 - RGC 21 - Publication in refereed journal
SN - 1616-301X
JO - Advanced Functional Materials
JF - Advanced Functional Materials
M1 - e21393
ER -