Ice-templated porous tungsten and tungsten carbide inspired by natural wood

Zhou, Yuan; Tan, Guoqi; Jiao, Dan; Zhang, Jian; Wang, S.G.; Liu, Feng; Liu, Zengqian; Zhuo, Longchao; Zhang, Zhefeng; Deville, Sylvain; Ritchie, Robert O.

doi:10.1016/j.jmst.2019.10.021

Cited by 35 publications

(4 citation statements)

References 59 publications

(146 reference statements)

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“…Although freeze-casting has been widely applied to construct oriented thermal conductive pathways, conductive fillers were aligned in only one direction due to the lamellar ice template. − By contrast, the current work successfully developed a dendritic ice template, aligning conductive fillers in both through-plane and in-plane directions. It is noteworthy that BN is used here as a proof of concept.…”

Section: Resultsmentioning

confidence: 84%

Isotropically Ultrahigh Thermal Conductive Polymer Composites by Assembling Anisotropic Boron Nitride Nanosheets into a Biaxially Oriented Network

Zhao

Wang

et al. 2022

ACS Nano

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The demand for thermally conductive but electrically insulating materials has increased greatly in advanced electronic packaging. To this end, polymer-based composites filled with boron nitride (BN) nanosheets have been intensively studied as thermal interface material (TIM). However, it remains a great challenge to achieve isotropically ultrahigh thermal conductivity in BN/polymer composites due to the inherent thermal property anisotropy of BN nanosheets and/or the insufficient construction of the 3D thermal conductive network. Herein, we present a high-performance BN/polymer composite with a biaxially oriented thermal conductive network by a dendritic ice template. The composite exhibits both ultrahigh in-plane (∼39.0 W m–1 K–1) and through-plane thermal conductivity (∼11.5 W m–1 K–1) at 80 vol % BN loading, largely exceeding those of reported BN/polymer composites. In addition, our composite as a TIM shows higher cooling efficiency than that of commercial TIM with up to 15 °C reduction of the chip temperature and retains good thermal stability even after 1000 heating/cooling cycles. Our strategy represents an effective approach for developing advanced thermal interface materials, which are greatly demanded for advanced electronics and emerging areas like wearable electronics.

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Section: Resultsmentioning

confidence: 84%

Isotropically Ultrahigh Thermal Conductive Polymer Composites by Assembling Anisotropic Boron Nitride Nanosheets into a Biaxially Oriented Network

Zhao

Wang

et al. 2022

ACS Nano

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“…Then, the dispersion is frozen to form ice crystals with regular shapes. The shape is adjusted by controlling the interaction between the crystal facets and the raw materials [ 23 , 24 ]. After removing the ordered array of ice crystal, the orientation of porous structures usually appears via freeze-dry technologies, and the bioactivity of low thermal stability polymer is reserved.…”

Section: Design and Fabrication Of The Bionic Porous Structurementioning

confidence: 99%

Design, Manufacturing and Functions of Pore-Structured Materials: From Biomimetics to Artificial

2023

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Porous structures with light weight and high mechanical performance exist widely in the tissues of animals and plants. Biomimetic materials with those porous structures have been well-developed, and their highly specific surfaces can be further used in functional integration. However, most porous structures in those tissues can hardly be entirely duplicated, and their complex structure-performance relationship may still be not fully understood. The key challenges in promoting the applications of biomimetic porous materials are to figure out the essential factors in hierarchical porous structures and to develop matched preparation methods to control those factors precisely. Hence, this article reviews the existing methods to prepare biomimetic porous structures. Then, the well-proved effects of micropores, mesopores, and macropores on their various properties are introduced, including mechanical, electric, magnetic, thermotics, acoustic, and chemical properties. The advantages and disadvantages of hierarchical porous structures and their preparation methods are deeply evaluated. Focusing on those disadvantages and aiming to improve the performance and functions, we summarize several modification strategies and discuss the possibility of replacing biomimetic porous structures with meta-structures.

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“…Therefore, tungsten materials are suitable alternatives to overcome the limitations of porous ceramics because of its brittleness for high temperature environments and other special requirements; thus, porous tungsten or porous tungsten matrix components has wide ranging applications in aerospace, power electronics, and metallurgical industries [3,4]. Porous tungsten has a high melting point, low vapor pressure, excellent electrical and thermal conductivities [5], as well as excellent corrosion resistance, and its internal porosity facilitates special applications. The conventional route for porous tungsten is powder metallurgy, rather than casting or pressure processing, owing to the high melting point and low temperature brittleness.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional porous tungsten via DLP 3D printing from transparent ink

Zan¹,

Wang²,

Shi³

et al. 2022

J. Phys. D: Appl. Phys.

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Tungsten, an essential refractory metal material, has the characteristics of high melting and boiling points, high hardness, low expansion coefficient, and low vapor pressure. An indirect strategy to print three-dimensional (3D) refractory metal materials via digital light processing (DLP) followed by a post-treatment process was proposed. To analyze this strategy, a transparent ink with tungsten salts was developed, printed into a 3D precursor via DLP, and subsequently transited into 3D porous tungsten. The ultraviolet rheological properties and stability of the ink, transition process from the precursor to a 3D article, and the properties of the obtained 3D porous tungsten were investigated. This ink was preferable for DLP 3D printing, possessing consistency, stability and favorable absorbance at the wavelength of 385 nm. With increasing temperature, the weight of the tungsten salt in the 3D precursor decreased by 8.97% and was transited to tungsten oxide below 460 ℃, reduced to pure nano-sized tungsten at approximately 700 ℃, and finally sintered into porous articles. The organics initially contributed to polymerization during printing as well as reduction as a carbon reducer after pyrolysis. The pore size distribution of porous tungsten is nonlinear or multimodal, depending on the final sintering temperature. At 1200 ℃, two distinct peaks are observed in the pore distribution curves of the products. At 1400 ℃, the small pore as a whole decreases from approximately 100 to 1000 nm. Correspondingly, the relative density of the samples increased with temperature.

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Ice-templated porous tungsten and tungsten carbide inspired by natural wood

Cited by 35 publications

References 59 publications

Isotropically Ultrahigh Thermal Conductive Polymer Composites by Assembling Anisotropic Boron Nitride Nanosheets into a Biaxially Oriented Network

Isotropically Ultrahigh Thermal Conductive Polymer Composites by Assembling Anisotropic Boron Nitride Nanosheets into a Biaxially Oriented Network

Design, Manufacturing and Functions of Pore-Structured Materials: From Biomimetics to Artificial

Three-dimensional porous tungsten via DLP 3D printing from transparent ink

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