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Abstract

The locally resonant metamaterial beam incorporating light-induced shape memory polymer (SMP) membranes as springs is proposed to achieve tunable bandgap properties in this work. The designed adaptive metamaterial can obtain variable bandgap in low-frequency range through non-contact control via ultraviolet light illumination. First, the Young’s modulus of light-induced SMP is experimentally investigated. Subsequently, a membrane-type locally resonant metamaterial beam with light-induced SMP is proposed, and an analytical model is established by treating the SMP membrane as a spring. The transmission spectra of certain resonator are compared with finite element method to validate the accuracy of the model. Based on this model, the effects of various parameters, such as the membrane radius, mass, and mass ratio of the substrate and vibrator, on the transmission characteristics are systematically examined. A base-excited metamaterial beam prototype with five resonators is designed and fabricated. Experimental results confirm that the bandgap can be tuned with different light exposure time, achieving a maximum 63% shift in the lower bound of the bandgap. Given that the bandgap shift is governed by the square root of Young’s modulus, different kinds of light-induced SMPs reported in the literatures are suggested to further expand the tunable bandgap range.

Keywords

light-induced shape memory polymer metamaterial beam tunable bandgap vibration control adaptive metamaterial

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References

Bandarab

Burdette

(2012) Photoisomerization in different classes of azobenzene. Chemical Society Reviews 41: 1809–1825.

Bayat

Gordaninejad

(2015) Dynamic response of a tunable phononic crystal under applied mechanical and magnetic loadings. Smart Materials and Structures 24: 065027.

Baz

(2009) The structure of an active acoustic metamaterial with tunable effective density. New Journal of Physics 11: 123010.

Beblo

Weiland

(2008) Strain induced anisotropic properties of shape memory polymer. Smart Materials and Structures 17: 055021.

Beblo

Weiland

(2009) Light activated shape memory polymer characterization. Journal of Applied Mechanics 76: 011008.

Beblo

Weiland

(2011) Light activated shape memory polymer characterization part II. Journal of Applied Mechanics 78: 061016.

Casadei

Delpero

Bergamini

, et al. (2012) Piezoelectric resonator arrays for tunable acoustic waveguides and metamaterials. Journal of Applied Physics 112(6): 141–143.

Chen

Fan

, et al. (2018) A review of tunable acoustic metamaterials. Applied Sciences 8(9): 1480.

Chen

Sun

Deng

, et al. (2022a) Investigation of a new metamaterial magnetorheological elastomer isolator with tunable vibration bandgaps. Mechanical Systems and Signal Processing 170: 108806.

10.

Chen

Wang

Mao

, et al. (2022b) New metamaterial mathematical modeling of acoustic topological insulators via tunable underwater local resonance. Applied Mathematical Modelling 108: 258–274.

11.

Chuang

Wang

(2019) A tunable elastic metamaterial beam with flat-curved shape memory alloy resonators. Applied Physics Letters 114: 051903.

12.

Danawe

Tol

(2023) Electro-momentum coupling tailored in piezoelectric metamaterials with resonant shunts. APL Materials 11: 091118.

13.

Fan

Zhang

, et al. (2022) Multi-bandgaps metamaterial plate design using complex mass-beam resonator. International Journal of Mechanical Sciences 236(15): 107742.

14.

Fang

Wen

Bonello

, et al. (2017) Ultra-low and ultra-broad-band nonlinear acoustic metamaterials. Nature Communications 8: 1–11.

15.

Fregoni

Granucci

Coccia

, et al. (2018) Manipulating azobenzene photoisomerization through strong light–molecule coupling. Nature Communications 9: 4688.

16.

Gliozzi

Miniaci

Chiappone

, et al. (2020) Tunable photo-responsive elastic metamaterials. Nature Communications 11: 2576.

17.

Jian

Tang

, et al. (2023) Adaptive piezoelectric metamaterial beam: autonomous attenuation zone adjustment in complex vibration environments. Smart Materials and Structures 32: 105023.

18.

Lee

Koerner

Vaia

, et al. (2011) Light activated shape memory of glassy, azobenzene liquid crystalline polymer networks. Soft Matter 7: 4318–4324.

19.

Lendlein

Jiang

Jünger

, et al. (2005) Light-induced shape-memory polymers. Nature 434: 879–882.

20.

Zhang

Peng

, et al. (2021) 4D printed shape memory metamaterial for vibration bandgap switching and active elastic-wave guiding. Journal of Materials Chemistry C 9: 1164–1173.

21.

Liu

, et al. (2022) Theoretical and experimental investigations on the ultra-low-frequency broadband of quasi-static metamaterials. Applied Sciences 12(18): 8981.

22.

Miranda

Nobrega

Ferreira

, et al. (2019) Flexural wave bandgaps in a multi-resonator elastic metamaterial plate using Kirchhoff–Love theory. Mechanical Systems and Signal Processing 11: 480–504.

23.

Wang

Shu

, et al. (2022) Low frequency broadband bandgaps in elastic metamaterials with two-stage inertial amplification and elastic foundations. Journal of Physics D: Applied Physics 55: 345302.

24.

Nanda

Karami

(2018) One-way sound propagation via spatio-temporal modulation of magnetorheological fluid. Journal of the Acoustical Society of America 144: 412.

25.

Nimmagadda

Matlack

(2019) Thermally tunable band gaps in architected metamaterial structures. Journal of Sound and Vibration 439: 29–42.

26.

Noroozi

Bodaghi

Jafari

, et al. (2020) Shape-adaptive metastructures with variable bandgap regions by 4D printing. Polymers 12(3): 519.

27.

Patel

Chen

, et al. (2022) Photo-responsive hydrogel-based re-programmable metamaterials. Scientific Reports 12: 13033.

28.

Pires

Sangiuliano

Denayer

, et al. (2022) The use of locally resonant metamaterials to reduce flow-induced noise and vibration. Journal of Sound and Vibration 535: 117106.

29.

Poggetto

Urban

Nistri

, et al. (2024) Selective dynamic band gap tuning in metamaterials using graded photoresponsive resonator arrays. Philosophical Transactions. Series A, Mathematical, Physical, and Engineering Sciences 23(382): 2279.

30.

Sheng

Fang

Wen

, et al. (2021) Vibration properties and optimized design of a nonlinear acoustic metamaterial beam. Journal of Sound and Vibration 492(1): 115739.

31.

Sousa

Sugino

Junior

, et al. (2018) Adaptive locally resonant metamaterials leveraging shape memory alloys. Journal of Applied Physics 124: 064505.

32.

Sugino

Leadenham

Ruzzene

, et al. (2016) On the mechanism of bandgap formation in locally resonant finite elastic metamaterials. Journal of Applied Physics 120: 134501.

33.

Sugino

Ruzzene

Erturk

(2020) An analytical framework for locally resonant piezoelectric metamaterial plates. International Journal of Solids and Structures 182: 281–294.

34.

Takada

(2023) Synthesis of biobased functional materials using photoactive cinnamate derivatives. Polymer Journal 55: 1023–1033.

35.

Thomes

Mosquera-Sánchez

Marqui

(2021) Bandgap widening by optimized disorder in one-dimensional locally resonant piezoelectric metamaterials. Journal of Sound and Vibration 512(10): 116369.

36.

Wang

Fan

, et al. (2019a) Frequency control of thin plates with light-activated shape-memory polymers. AIAA Journal 57: 3579–3585.

37.

Wang

Zhou

Cai

, et al. (2019b) Mathematical modeling and analysis of a meta-plate for very low-frequency band gap. Applied Mathematical Modelling 73: 581–597.

38.

Wang

Fan

, et al. (2020) Microscopic control actions of LaSMP actuators on hemispherical shells. Mechanical Systems and Signal Processing 142: 106744.

39.

Wang

Zhang

, et al. (2021) Bandgap properties in metamaterial sandwich plate with periodically embedded plate-type resonators. Mechanical Systems and Signal Processing 151: 107375.

40.

Wang

Liu

Yang

, et al. (2022a) A novel programmable composite metamaterial with tunable Poisson’s ratio and bandgap based on multi-stable switching. Composites Science and Technology 219: 109245.

41.

Wang

Chen

, et al. (2022b) Design of low-frequency and broadband acoustic metamaterials with I-shaped antichiral units. Applied Acoustics 197: 108946.

42.

Jin

Sun

(2011) Synthesis, properties, and light-induced shape memory effect of multiblock polyesterurethanes containing biodegradable segments and pendant cinnamamide groups. Biomacromolecules 12: 235–241.

43.

Yang

Zhou

Wang

(2022) Tunable band gap and wave guiding in periodic grid structures with thermal sensitive materials. Composite Structures 290: 115536.

44.

Yang

Huang

Nouh

, et al. (2023) Active and passive smart structures and integrated systems XVII, SPIE Proceedings, 12483.

45.

Zhao

Shi

Liu

, et al. (2020) Theoretical and experimental investigation on wave propagation in the periodic impedance layered structure modulated by magnetorheological fluid. Journal of Intelligent Material Systems and Structures 31: 882–896.

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Light-induced membrane-type locally resonant metamaterial beam with tunable bandgap

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