Closure to “Contact Unloading Behaviors of Elastic-Power-Law Strain Hardening Material Considering Indenter Elasticity Effect” (Chen, C., Wang, Q., Wang, H., Ding, H., Hu, W., Xie, W., Weng, P., Jiang, L., and Yin, X., 2022, ASME J. Tribol., 144(12), p. 121501)

Chen, Chuanqing; Yin, Xiaochun

doi:10.1115/1.4056193

Cited by 32 publications

(50 citation statements)

References 3 publications

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“…The porous and heterojunction structure contributes to the structural advantage of electrolyte permeation. 29,30 In addition, the morphology of TS (18) -P (50) -V 2 C and TS (30) -P (50) -V 2 C has been confirmed in Figure 1c,d, respectively. Moreover, the energydispersive spectrometry (EDS) mapping (Figure 1g−j) of the elements V, O, and C from a selected area suggests that those elements are distributed on the entire area, which provides further evidence that the material is V 2 O 3 /V 2 C. A transmission electron microscope (TEM) was used to study the morphology evolution of V 2 C-MXene, P (50) -V 2 C, and TS (24) -P (50) -V 2 C (Figure 2a−c, respectively).…”

Section: Resultsmentioning

confidence: 98%

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Zhou

Guo

et al. 2023

ACS Appl. Mater. Interfaces

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Transition metal carbon/nitride (MXene) holds immense potential as an innovative electrocatalyst for enhancing the overall water splitting properties. Nevertheless, the re-stacking nature induced by van der Waals force remains a significant challenge. In this work, the lattice tensile-strained porous V 2 C-MXene (named as TS (24) -P (50) -V 2 C) is successfully constructed via the rapid spray freezing method and the following hydrothermal treatment. Besides, the influence of lattice strain degree and microscopic pores on the catalytic ability is reviewed and explored systematically. The lattice tensile strain within V 2 C-MXene could widen the interlayer spacing and accelerate the ion transfer. The microscopic pores could change the ion transmission path and shorten the migration distance. As a consequence, the obtained TS (24) -P (50) -V 2 C shows extraordinary hydrogen evolution reaction and oxygen evolution reaction activity with the overpotential of 154 and 269 mV, respectively, at the current density of 10 mA/cm 2 , which is quite remarkable compared to the MXene-based electrocatalysts. Moreover, the overall water splitting device assembled using TS (24) -P (50) -V 2 C as both anode and cathode demonstrates a low cell voltage requirement of 1.57 V to obtain 10 mA/cm 2 . Overall, the implementation of this work could offer an exciting avenue to overcome the re-stacking issue of V 2 C-MXene, affording a highefficiency electrocatalyst with superior catalytic activity and desirable reaction kinetics.

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Section: Resultsmentioning

confidence: 98%

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Zhou

Guo

et al. 2023

ACS Appl. Mater. Interfaces

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“…Low‐density polyethylene (LDPE) as a common thermoplastic material, has been widely used in various fields such as cables, building materials, electronic industries, battery boxes, and underground mining because of its lightweight, excellent dielectric properties, corrosion resistance, recyclability, large output and so on 1–3 . Nevertheless, LDPE is flammable, which greatly limits its application 4,5 .…”

Section: Introductionmentioning

confidence: 99%

Improving the flame retardancy efficiency and mechanical properties of the intumescent flame retarded low‐density polyethylene by the dual actions of polyurea microencapsulation and aluminum hypophosphite

Lan

Gao

Xiao

et al. 2023

J of Applied Polymer Sci

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The use of intumescent flame retardants to retard polyethylene usually had the disadvantages of low flame retardancy efficiency and poor compatibility between intumescent flame retardants and low-density polyethylene (LDPE), which led to the reduction of mechanical properties of materials. In order to solve these issues, the microencapsulated ammonium polyphosphate (MAPP) and microencapsulated aluminum hypophosphite (MAHP) with polyurea were prepared through the interfacial polymerization of water-in-oil (W/O) microemulsions. The flame retarded polyethylene composites with MAPP and MAHP were manufactured. The LDPE composites with 17.3 wt% of MAPP and 3.9 wt% of MAHP possessed a LOI value of 27.3% and achieved the V-0 standard. The PHRR and THR were remarkably decreased by 30.3% and 31.1% compared with that of the LDPE. Furthermore, the tensile strength of LDPE/MAPP-MAHP was 19.1% higher than that of LDPE/APP-AHP because of good dispersion and compatibility of MAPP and MAHP with LDPE. This work provides a new method to prepare flame-retardant LDPE with high performance and the related mechanisms were discussed in detail.

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“…Atomic doping has the ability to improve the electrical conductivity and diffusion dynamics of electrode materials. [83] Through the first principles calculation, the doped atoms replace the atoms in the raw material. It can be found that the diffusion energy barriers near the doped atoms are significantly reduced, effectively regulating the diffusion kinetics and improving the electrical conductivity, which is an effective means of material modification.…”

Section: Atomic Dopingmentioning

confidence: 99%

Research Progress of Cathode Materials for Rechargeable Aluminum Batteries in AlCl₃/[EMIm]Cl and Other Electrolyte Systems

Zhang

Jin

et al. 2023

ChemistrySelect

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The development of safe, cheap, and environmentally friendly advanced rechargeable batteries with high energy density are one of the most pressing tasks for today's energy crisis. With the advantages of low cost, abundant reserves, and high-level safety, rechargeable aluminum ion batteries are considered ideal candidates for next-generation energy storage batteries in the context of large-scale energy applications. Relevant knowledge of energy storage materials and electrolytes, which possess close connection in between, is undeniably crucial for such research, while ironically, most attention is attracted to merely one element alone, especially the energy storage materials involving micro/nanomaterials. In this review, we focus on cathode materials matching with various electrolyte systems for rechargeable aluminum batteries and manage to provide new ideas for the preparation methods of highefficiency electrochemical energy storage materials, with future outlooks in this field.

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Closure to “Contact Unloading Behaviors of Elastic-Power-Law Strain Hardening Material Considering Indenter Elasticity Effect” (Chen, C., Wang, Q., Wang, H., Ding, H., Hu, W., Xie, W., Weng, P., Jiang, L., and Yin, X., 2022, ASME J. Tribol., 144(12), p. 121501)

Cited by 32 publications

References 3 publications

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Improving the flame retardancy efficiency and mechanical properties of the intumescent flame retarded low‐density polyethylene by the dual actions of polyurea microencapsulation and aluminum hypophosphite

Research Progress of Cathode Materials for Rechargeable Aluminum Batteries in AlCl₃/[EMIm]Cl and Other Electrolyte Systems

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Closure to “Contact Unloading Behaviors of Elastic-Power-Law Strain Hardening Material Considering Indenter Elasticity Effect” (Chen, C., Wang, Q., Wang, H., Ding, H., Hu, W., Xie, W., Weng, P., Jiang, L., and Yin, X., 2022, ASME J. Tribol., 144(12), p. 121501)

Cited by 32 publications

References 3 publications

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V2C-MXene for High-Performance Overall Water Splitting

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V2C-MXene for High-Performance Overall Water Splitting

Improving the flame retardancy efficiency and mechanical properties of the intumescent flame retarded low‐density polyethylene by the dual actions of polyurea microencapsulation and aluminum hypophosphite

Research Progress of Cathode Materials for Rechargeable Aluminum Batteries in AlCl3/[EMIm]Cl and Other Electrolyte Systems

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Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Novel Strain Engineering Combined with a Microscopic Pore Synergistic Modulated Strategy for Designing Lattice Tensile-Strained Porous V₂C-MXene for High-Performance Overall Water Splitting

Research Progress of Cathode Materials for Rechargeable Aluminum Batteries in AlCl₃/[EMIm]Cl and Other Electrolyte Systems