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Abstract

Mechanical metamaterials exhibit special properties that cannot be realized in traditional materials. To enable a metamaterial with a sequential Poisson’s ratio and controllable expansion, a 2D-graded hybrid re-entrant honeycomb is designed in this work by coupling graded re-entrant unit cells with negative and positive Poisson’s ratios. The correlation between Poisson’s ratio and structural location under tension is studied by finite element analysis and experiments. The influence of microstructural parameters, including base angle, height ratio, and internal angle, on the relationship between the Poisson’s ratio and structural location is systematically analyzed. The theoretical analysis shows that the 2D-graded hybrid metastructures exhibit auxetic behavior with a linearly declined Poisson’s ratio along the tensile direction due to the introduction of a height ratio, resulting in gradual expansion and elongation. Furthermore, adjusting the variation of internal angles at a small height ratio can enhance the negative Poisson’s ratio of the 2D-graded hybrid re-entrant honeycomb. Finally, a 3D-graded conical metastructure exhibiting linear auxeticity is constructed based on the 2D-graded lattice. Considering their designed linearity of deformation under tension, the 2D- and 3D-graded metastructures can facilitate the design of conical profiles for an extendable rocket nozzle and other deployable devices.

Keywords

Graded metastructure hybrid honeycomb re-entrant unit cell Poisson’s ratio auxetic behavior elastic deformation under tension

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References

Wang

Zhao

, et al. Structure design and multi-objective optimization of a novel NPR bumper system. Compos Part B-Eng 2018; 153: 78–96.

Liao

, et al. A novel ultra‐wideband electromagnetic‐wave‐absorbing metastructure inspired by bionic gyroid structures. Adv Mater 2023; 35: 2300659.

Contreras

Zhang

Hao

, et al. Application of elastic metamaterials/meta-structures in civil engineering: a review. Compos Struct 2024; 327: 117663.

Jiang

Shi

Zhou

, et al. 3D-printed auxetic-structured intervertebral disc implant for potential treatment of lumbar herniated disc. Bioact Mater 2023; 20: 528–538.

Lakes

. Advances in negative Poisson’s ratio materials. Adv Mater 1993; 5: 293–296.

Huang

Chen

. Negative Poisson’s ratio in modern functional materials. Adv Mater 2016; 28: 8079–8096.

Zhang

You

. Large deformation and energy absorption of additively manufactured auxetic materials and structures: a review. Compos Part B-Eng 2020; 201: 108340.

Esmaeili

Karimi

Heidari-Rarani

, et al. A new design of star auxetic metastructure with enhanced energy-absorption under various loading rates: experimental and numerical study. Structures 2024; 63: 106457.

Liu

Wang

. Enhancing indentation and impact resistance in auxetic composite materials. Compos Part B-Eng 2020; 198: 108229.

10.

Summers

. Compliant hexagonal periodic lattice structures having both high shear strength and high shear strain. Mater Des 2011; 32: 512–524.

11.

Jiang

Yang

Zhang

, et al. Fabrication and crushing response of graded re-entrant circular auxetic honeycomb. Int J Mech Sci 2023; 242: 107999.

12.

Nian

Wan

Avcar

, et al. 3D printing functionally graded metamaterial structure: design, fabrication, reinforcement, optimization. Int J Mech Sci 2023; 258: 108580.

13.

Jiang

Yang

. Advanced honeycomb designs for improving mechanical properties: a review. Compos Part B-Eng 2021; 227: 109393.

14.

Chen

, et al. Enhanced mechanical properties of re-entrant auxetic honeycomb with self-similar inclusion. Compos Struct 2024; 331: 117921.

15.

Fang

Yuan

Meng

, et al. Graded negative Poisson’s ratio honeycomb structure design and application. J Sandw Struct Mater 2018; 21: 2527–2547.

16.

Dudek

Mizzi

Iglesias Martínez

, et al. Micro-scale graded mechanical metamaterials exhibiting versatile Poisson’s ratio. Compos Struct 2023; 319: 117151.

17.

Iniguez-Rabago

Overvelde

JTB

. Exploring multistability in prismatic metamaterials through local actuation. Nat Commun 2019; 10: 5577.

18.

Lacoste

Lacombe

Joyez

, et al. Carbon/carbon extendible nozzles. Acta Astronaut 2002; 50: 357–367.

19.

Wang

Tian

. Study on separation characteristics of nozzles with large expansion ratio of solid rocket motors. Aerospace 2022; 10: 4.

20.

, et al. Impact energy absorption of functionally graded chiral honeycomb structures. Extreme Mech Lett 2019; 32: 100568.

21.

Shi

. In-plane impact resistance enhancement with a graded cell-wall angle design for auxetic metamaterials. Compos Struct 2020; 247: 112451.

22.

Zamani

Heidari-Rarani

Torabi

. A novel graded auxetic honeycomb core model for sandwich structures with increasing natural frequencies. J Sandw Struct Mater 2021; 24: 1313–1339.

23.

Hosseini

Mazaheri

. Experimental and simulation study of the crashworthiness behavior of thickness-graded auxetic structures of ductile and brittle materials. J Sandw Struct Mater 2024; 26: 849–868.

24.

Xiao

Dong

, et al. Compression behavior of the graded metallic auxetic reentrant honeycomb: experiment and finite element analysis. Mater Sci Eng A 2019; 758: 163–171.

25.

Luo

Zhang

, et al. Mechanical properties of aluminum foam filled re-entrant honeycomb with uniform and gradient designs. Int J Mech Sci 2023; 244: 108075.

26.

Bian

Sun

, et al. Functionally-graded NPR (negative Poisson’s ratio) material for a blast-protective deflector. In: NDIA ground vehicle systems engineering and Technology symposium, Testing and Validation Mini-Symposium , Dearborn, MI, USA, Aug 18, 2010.

27.

Yao

Sun

Scarpa

, et al. Two-dimensional graded metamaterials with auxetic rectangular perforations. Compos Struct 2021; 261: 113313.

28.

Han

. Evolutionary design of nonuniform cellular structures with optimized Poisson's ratio distribution. Mater Des 2018; 141: 384–394.

29.

Pei

L-Z

Remennikov

, et al. Numerical and theoretical analysis of crushing strength of 3D re-entrant honeycomb. Thin-Walled Struct 2023; 182: 110140.

30.

Yang

, et al. Directions dependence of the elastic properties of a 3D augmented re-entrant cellular structure. Mater Des 2017; 134: 151–162.

31.

Zhang

Hao

Tian

, et al. Quasi-static compression and dynamic crushing behaviors of novel hybrid re-entrant auxetic metamaterials with enhanced energy-absorption. Compos Struct 2022; 288: 115399.

32.

Hou

Dong

, et al. An optimized lozenge-chiral auxetic metamaterial with tunable auxeticity and stiffness. Mater Des 2024; 237: 112530.

33.

Mercer

Speck

Lee

, et al. Effects of geometry and boundary constraint on the stiffness and negative Poisson’s ratio behaviour of auxetic metamaterials under quasi-static and impact loading. Int J Impact Eng 2022; 169: 104315.

34.

Zhang

X-C

L-Q

Ding

H-M

, et al. The influence of cell micro-structure on the in-plane dynamic crushing of honeycombs with negative Poisson’s ratio. J Sandw Struct Mater 2014; 17: 26–55.

35.

Sadegh Ebrahimi

Noruzi

Hamzehei

, et al. Revolutionary auxetic intravascular medical stents for angioplasty applications. Mater Des 2023; 235: 112393.

36.

Ali

Rehman

. Auxetic polyurethane stents and stent-grafts for the palliative treatment of squamous cell carcinomas of the proximal and mid oesophagus: a novel fabrication route. J Manuf Syst 2015; 37: 375–395.

37.

Wang

Dai

Zhao

, et al. Reliability-based optimization of a novel negative Poisson’s ratio door anti-collision beam under side impact. Thin-Walled Struct 2020; 154: 106863.

38.

Ren

Shen

Tran

, et al. Auxetic nail: design and experimental study. Compos Struct 2018; 184: 288–298.

39.

Ling

Wei

, et al. Design and analysis for large magnitudes of programmable Poisson's ratio in a series of lightweight cylindrical metastructures. Int J Mech Sci 2021; 195: 106220.

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Graded metastructure design for linearly auxetic deformation under tension: From 2D honeycombs to 3D truncated cones

Abstract

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