Publications by Dr Xinwei Li - ePrints

Browsing publications by Dr Xinwei Li.

Newcastle Authors	Title	Year
Dr Xinwei Li	3D-Printed Lattice Structures for Sound Absorption: Current Progress, Mechanisms and Models, Structural-Property Relationships, and Future Outlook	2024
Dr Xinwei Li	A ribbed strategy disrupts conventional metamaterial deformation mechanisms for superior energy absorption	2024
Dr Xinwei Li	Superior Strength, Toughness, and Damage-Tolerance Observed in Microlattices of Aperiodic Unit Cells	2024
Dr Xinwei Li	A novel class of bioinspired composite via ultrasound-assisted directed self-assembly digital light 3D printing	2023
Dr Xinwei Li	Additive Manufacturing of Lattice Structures	2023
Dr Xinwei Li	Customizable plateau in face-centered cubic hierarchical lattices achieved by self-similar embedded design	2023
Dr Xinwei Li	Enhanced energy-absorbing and sound-absorbing capability of functionally graded and helicoidal lattice structures with triply periodic minimal surfaces	2023
Dr Xinwei Li	Harnessing cavity dissipation for enhanced sound absorption in Helmholtz resonance metamaterials	2023
Professor Zhenhong Li Dr Xinwei Li	Interpenetrating Hollow Microlattice Metamaterial Enables Efficient Sound-Absorptive and Deformation-Recoverable Capabilities	2023
Dr Xinwei Li	Less Is More: Hollow-Truss Microlattice Metamaterials with Dual Sound Dissipation Mechanisms and Enhanced Broadband Sound Absorption	2023
Dr Xinwei Li	Multifunctional and customizable lattice structures for simultaneous sound insulation and structural applications	2023
Dr Xinwei Li	Multifunctional sound-absorbing and mechanical metamaterials via a decoupled mechanism design approach	2023
Dr Xinwei Li	Multi-Level Bioinspired Microlattice with Broadband Sound-Absorption Capabilities and Deformation-Tolerant Compressive Response	2023
Professor Zhenhong Li Dr Xinwei Li	New Class of Multifunctional Bioinspired Microlattice with Excellent Sound Absorption, Damage Tolerance, and High Specific Strength	2023
Dr Xinwei Li	Additively Manufactured Deformation-Recoverable and Broadband Sound-Absorbing Microlattice Inspired by the Concept of Traditional Perforated Panels	2021
Dr Xinwei Li	Microlattice metamaterials with simultaneous superior acoustic and mechanical energy absorption	2021