Mechanical Properties of Diamond‐Structured Polymer Microlattices Coated with the Silicon Nitride Film

Zhou, Yong; Yao, Chang Zhuang; Yang, Qi; Guo, Lin; Jiang, Lei

doi:10.1002/adem.201500424

Cited by 15 publications

(16 citation statements)

References 46 publications

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“…[43] It is worth mentioning that the composite nanolattices exhibit superior compressive strain, which possibly due to the polymeric core supporting. Finally, through these data, it can be calculated that the specific compressive strength of the presented composite nanolattices is 0.032 MPa kg À1 m 3 , which is comparable even higher than that of the micro/nano lattice reported before, for instance, polymer/NiB (0.017 MPa kg À1 m 3 ), [41] polymer/Si 3 N 4 (0.012 MPa kg À1 m 3 ), [42] and SiC microlattices (%0.023 MPa kg À1 m 3 ) [44] and a detailed comparison can be found in Table S1, demonstrating the superior mechanical properties of the composite nanolattices based on the synergistic effect between polymer and HEA film. Thin films, both amorphous and crystalline films, have been extensively reported to be capable of enhancing the performance of many types of materials through coating, especially the mechanical performance of substrate materials.…”

Section: Hea Filmsupporting

confidence: 59%

“…However, when the core is not still enough to increase the compressive capability and the buckling stress is dominated by the buckling stress of the shell. [42] Meanwhile, the HEA is in the ductile-to brittle transition due to the size effects. [41] Therefore, a brittle behavior would be observed at a certain point, which is in good agreement with other reports.…”

Section: Hea Filmmentioning

confidence: 99%

“…[41] Therefore, a brittle behavior would be observed at a certain point, which is in good agreement with other reports. [12,41,42] To demonstrate the important role of the polymer core in the composite nanolattices, a loading-unloading compression test was employed ( Figure S4). As shown in the exhibited mechanical behaviors, nearly the same Young's modulus (74.5 AE 3.5 MPa) was observed, indicating the superior recoverability of the composite nanolattices under an applied strain of nearly 8%.…”

Section: Hea Filmmentioning

confidence: 99%

“…[1][2][3][4][5][6][7][8][9] The strength of lattices is determined not only by the order and periodicity of its structure, but also by the constituent materials. [10,11] Recently, numerous engineering materials such as Al 2 O 3, [12][13][14] Ni-P alloy, [4,15] glassy carbon, [16] copper, [17] gold, [18] and metallic glass [19,20] have been employed as constituent materials to significantly enhance the mechanical properties of pristine polymer scaffolds with respect to its strength and stiffness. Nevertheless, exploring a kind of lightweight, low-cost, and easily fabricated material with promising mechanical features that are easily to be coupled with pristine lattice structure is still a challenge.…”

Section: Introductionmentioning

confidence: 99%

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High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

et al. 2017

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Nanolattice structure fabricated by two-photon lithography (TPL) is a coupling of size-dependent mechanical properties at micro/nano-scale with structural geometry responses in wide applications of scalable micro/nano-manufacturing. In this work, three-dimensional (3D) polymeric nanolattices are initially fabricated using TPL, then conformably coated with an 80 nm thick high-entropy alloy (HEA) thin film (CoCrFeNiAl 0.3 ) via physical vapor deposition (PVD). 3D atomic-probe tomography (APT) reveals the homogeneous element distribution in the synthesized HEA film deposited on the substrate. Mechanical properties of the obtained composite architectures are investigated via in situ scanning electron microscope (SEM) compression test, as well as finite element method (FEM) at the relevant length scales. The presented HEA-coated nanolattice encouragingly not only exhibits superior compressive specific strength of %0.032 MPa kg À1 m 3 with density well below 1000 kg m À3 , but also shows good compression ductility due to its composite nature. This concept of combining HEA with polymer lattice structures demonstrates the potential of fabricating novel architected metamaterials with tunable mechanical properties.

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Section: Hea Filmsupporting

confidence: 59%

Section: Hea Filmmentioning

confidence: 99%

Section: Hea Filmmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

et al. 2017

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“…However, the structures typically exhibit stable cyclic behavior subsequently . This mechanism is also responsible for the layer‐by‐layer deformation in a lot of lattice materials, which allows controlled dissipation of energy …”

Section: Utilizing Architecture Size Effect and Mechanismmentioning

confidence: 99%

Mechanical Metamaterials and Their Engineering Applications

et al. 2019

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In the past decade, mechanical metamaterials have garnered increasing attention owing to its novel design principles which combine the concept of hierarchical architecture with material size effects at micro/nanoscale. This strategy is demonstrated to exhibit superior mechanical performance that allows us to colonize unexplored regions in the material property space, including ultrahigh strength-to-density ratios, extraordinary resilience, and energy absorption capabilities with brittle constituents. In the recent years, metamaterials with unprecedented mechanical behaviors such as negative Poisson's ratio, twisting under uniaxial forces, and negative thermal expansion are also realized. This paves a new pathway for a wide variety of multifunctional applications, for example, in energy storage, biomedical, acoustics, photonics, and thermal management. Herein, the fundamental scientific theories behind this class of novel metamaterials, along with their fabrication techniques and potential engineering applications beyond mechanics are reviewed. Explored examples include the recent progresses for both mechanical and functional applications. Finally, the current challenges and future developments in this emerging field is discussed as well.

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Coatings for Core–Shell Composite Micro‐Lattice Structures: Varying Sputtering Parameters

et al. 2021

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Magnetron sputtering has garnered increased attention as a versatile deposition method for generating novel core–shell composite nano‐ and micro‐lattice materials spanning a wide range of properties and functionalities. Sputtering offers an expansive material workspace consisting of a wide range of ceramics, single‐element metals, and alloy systems. However, achieving uniform coatings on such fine‐featured structures remains a challenge. Thus, herein, a foundational assessment of various sputtering configurations, cathode geometries, and deposition parameters is carried out to investigate their implications on the coating thickness and uniformity of 3D micro‐lattice scaffolds. Specifically, tetrahedral‐truss structures fabricated via direct laser writing are coated by leveraging planar and inverted cylindrical magnetron cathodes at select deposition rates, sputtering powers, and Ar working pressures. Both plasma focused ion beam and microtome sectioning techniques are employed to evaluate the cross section of individual struts and assess overall uniformity. Overall, the influence of key sputtering factors on the design and development of core–shell composite nano‐ and micro‐lattice materials is highlighted and a pathway for future sputter coating optimization on these complex structures is provided.

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Mechanical Properties of Diamond‐Structured Polymer Microlattices Coated with the Silicon Nitride Film

Cited by 15 publications

References 46 publications

High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

High‐Entropy Alloy (HEA)‐Coated Nanolattice Structures and Their Mechanical Properties

Mechanical Metamaterials and Their Engineering Applications

Coatings for Core–Shell Composite Micro‐Lattice Structures: Varying Sputtering Parameters

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