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1. Stabilizing High-Nickel Cathodes via Interfacial Hydrogen Bonding Effects Using a Hydrofluoric Acid-Scavenging Separator

Author

Shijie Zhong, Liwei Dong, Botao Yuan, Yueyao Dong, Qun Li, Yuanpeng Ji, Yuanpeng Liu, Jiecai Han, and Weidong He

Subjects
Nickel-rich cathodes, Composite separator, HF scavenging, Transition metal dissolution, Long-term cyclability, Engineering (General). Civil engineering (General), TA1-2040
Abstract

Nickel-rich layered Li transition metal oxides are the most promising cathode materials for high-energy-density Li-ion batteries. However, they exhibit rapid capacity degradation induced by transition metal dissolution and structural reconstruction, which are associated with hydrofluoric acid (HF) generation from lithium hexafluorophosphate decomposition. The potential for thermal runaway during the working process poses another challenge. Separators are promising components to alleviate the aforementioned obstacles. Herein, an ultrathin double-layered separator with a 10 μm polyimide (PI) basement and a 2 μm polyvinylidene difluoride (PVDF) coating layer is designed and fabricated by combining a non-solvent induced phase inversion process and coating method. The PI skeleton provides good stability against potential thermal shrinkage, and the strong PI–PVDF bonding endows the composite separator with robust structural integrity; these characteristics jointly contribute to the extraordinary mechanical tolerance of the separator at elevated temperatures. Additionally, unique HF-scavenging effects are achieved with the formation of –CO···H–F hydrogen bonds for the abundant HF coordination sites provided by the imide ring; hence, the layered Ni-rich cathodes are protected from HF attack, which ultimately reduces transition metal dissolution and facilitates long-term cyclability of the Ni-rich cathodes. Li||NCM811 batteries (where “NCM” indicates LiNixCoyMn1−x−yO2) with the proposed composite separator exhibit a 90.6% capacity retention after 400 cycles at room temperature and remain sustainable at 60 °C with a 91.4% capacity retention after 200 cycles. By adopting a new perspective on separators, this study presents a feasible and promising strategy for suppressing capacity degradation and enabling the safe operation of Ni-rich cathode materials.

Published
2024
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2. Multispectral smart window: Dynamic light modulation and electromagnetic microwave shielding

Author

Ruicong Zhang, Zicheng Song, Wenxin Cao, Gang Gao, Lei Yang, Yurong He, Jiecai Han, Zhibo Zhang, Tianyu Wang, and Jiaqi Zhu

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Abstract A novel multispectral smart window has been proposed, which features dynamic modulation of light transmittance and effective shielding against electromagnetic microwave radiation. This design integrates liquid crystal dynamic scattering and dye doping techniques, enabling the dual regulation of transmittance and scattering within a single-layer smart window. Additionally, the precise control of conductive film thickness ensures the attainment of robust microwave signal shielding. We present a theoretical model for ion movement in the presence of an alternating electric field, along with a novel approach to manipulate negative dielectric constant. The proposed model successfully enables a rapid transition between light transparent, absorbing and haze states, with an optimum drive frequency adjustable to approximately 300 Hz. Furthermore, the resistive design of the conductive layer effectively mitigates microwave radiation within the 2−18 GHz range. These findings offer an innovative perspective for future advancements in environmental construction.

Published
2024
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3. Origami metamaterials for ultra-wideband and large-depth reflection modulation

Author

Zicheng Song, Juan-Feng Zhu, Xianchao Wang, Ruicong Zhang, Pingping Min, Wenxin Cao, Yurong He, Jiecai Han, Tianyu Wang, Jiaqi Zhu, Lin Wu, and Cheng-Wei Qiu

Subjects
Science
Abstract

Abstract The dynamic control of electromagnetic waves is a persistent pursuit in modern industrial development. The state-of-the-art dynamic devices suffer from limitations such as narrow bandwidth, limited modulation range, and expensive features. To address these issues, we fuse origami techniques with metamaterial design to achieve ultra-wideband and large-depth reflection modulation. Through a folding process, our proposed metamaterial achieves over 10-dB modulation depth over 4.96 – 38.8 GHz, with a fractional bandwidth of 155% and tolerance to incident angles and polarizations. Its ultra-wideband and large-depth reflection modulation performance is verified through experiments and analyzed through multipole decomposition theory. To enhance its practical applicability, transparent conductive films are introduced to the metamaterial, achieving high optical transparency (>87%) from visible to near-infrared light while maintaining cost-effectiveness. Benefiting from lightweight, foldability, and low-cost properties, our design shows promise for extensive satellite communication and optical window mobile communication management.

Published
2024
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4. Nanodiamond reinforced self-healing and transparent poly(urethane–urea) protective coating for scratch resistance

Author

Zhuochao Wang, Wenxin Cao, Chunqiang Sun, Dongchao Ji, Kunlong Zhao, Gang Gao, Xingchun Xu, Yingqi Liu, Tianyu Zhang, Jiaqi Zhu, and Jiecai Han

Subjects
Nanocomposite coatings, self-healing, scratch resistance, transparent poly(urethane–urea), Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

ABSTRACTWith increasing demand for scratch-resistant flexible electronics, the development of transparent coatings with good scratch resistance and self-healing properties has emerged as a key research topic. In this study, a high-strength self-healing poly(urethane – urea) (PUU)-based nanocomposite coating was prepared by introducing functionalized nanodiamond (ND) into a PUU matrix via solution blending. The PUU matrix had hard-segment repeating units and was constructed using isophorone diamine and isophorone isocyanate. The ND particles were modified using a silane coupling agent, 3-aminopropyltriethoxysilane, to obtain well-dispersed KH-ND nanoparticles. KH-ND promoted microphase separation in the PU matrix, inducing the formation of dense and homogeneous hard domains that dissipated stress, prevented further crack development, and improved the mechanical properties and scratch resistance of the coating. In addition, the coating exhibited excellent self-healing properties. Fourier-transform infrared spectroscopy, scanning electron microscopy, and atomic force microscopy were used to characterize the self-healing and hardening mechanisms of the coating. The environmentally friendly PUU/KH-ND coating is easy to prepare and has broad application prospects in transparent and anti-scratch coatings for flexible electronics, automobiles, and home appliances.

Published
2024
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5. Creation of shallow nitrogen vacancy centers in HPHT diamond surface via catalytic etching of transition metal

Author

Sen Zhang, Jiwen Zhao, Yicun Li, Xiaobin Hao, Xiaohui Zhang, Pengfei Qiao, Ying Liang, Bo Liang, Wenchao Zhang, Wenxin Cao, Lei Yang, Bing Dai, Kang Liu, Benjian Liu, Jiaqi Zhu, and Jiecai Han

Subjects
nitrogen vacancy color center, diamond, iron etching, quantum detection, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

The nitrogen vacancy (NV) color centers are a solid-state quantum system with the ability to maintain long coherence times at room temperatures. NV centers have potential applications in quantum detection, which necessitates their positioning at minimal distances from surfaces. However, the existing methods for fabricating NV centers are cumbersome, expensive, and difficult to control. This study investigates the etching mechanism of transition metals on diamond under plasma conditions and develops a method for producing shallow NV centers on the surface of high pressure and high temperature diamond. Our proposed method enables the production of shallow NV centers below the surface in the longitudinal direction, while simultaneously allowing precise control over the lateral distribution. Moreover, the operating costs associated with our technique are significantly lower than those of ion implantation and electron irradiation. This research contributes to the advancement of iron-etching diamond processing technology, and the proposed method facilitates the more portable preparation of shallow color centers in specific regions, enabling the realization of locally controllable and scalable coupled quantum systems.

Published
2023
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6. Development of lutetium oxide continuous fibers with excellent mechanical properties

Author

Yongshuai XIE, Ying PENG, Youmei WANG, Dehua MA, Yuan CHENG, Luyi ZHU, Jiecai HAN, and Xinghong ZHANG

Subjects
lutetium oxide (lu2o3), continuous fibers, tensile strength, flexible, temperature resistance, Clay industries. Ceramics. Glass, TP785-869
Abstract

The difficulty of reducing the diameter of lutetium oxide (Lu2O3) continuous fibers below 50 μm not only limits the flexibility of the sample but also seriously affects their application and development in high-energy lasers. In this work, a Lu-containing precursor with high ceramic yield was used as raw material, fiberized into precursor fibers by dry spinning. The pressure-assisted water vapor pretreatment (PAWVT) method was creatively proposed, and the effect of pretreatment temperature on the ceramization behavior of the precursor fibers was studied. By regulating the decomposition behavior of organic components in the precursor, the problem of fiber pulverization during heat treatment was effectively solved, and the Lu2O3 continuous fibers with a diameter of 40 μm were obtained. Compared with the current reported results, the diameter was reduced by about 50%, successfully breaking through the diameter limitation of Lu2O3 continuous fibers. In addition, the tensile strength, elastic modulus, flexibility, and temperature resistance of Lu2O3 continuous fibers were researched for the first time. The tensile strength and elastic modulus of Lu2O3 continuous fibers were 373.23 MPa and 31.55 GPa, respectively. The as-obtained flexible Lu2O3 continuous fibers with a limit radius of curvature of 3.5–4.5 mm had a temperature resistance of not lower than 1300 ℃, which established a solid foundation for the expansion of their application form in the field of high-energy lasers.

Published
2023
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7. Advanced liquid crystal-based switchable optical devices for light protection applications: principles and strategies

Author

Ruicong Zhang, Zhibo Zhang, Jiecai Han, Lei Yang, Jiajun li, Zicheng Song, Tianyu Wang, and Jiaqi Zhu

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

With the development of optical technology, LCs with intelligent light protection function become more and more important. This paper discusses the research progress and challenges of LCs for light protection.

Published
2023
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8. Heteroepitaxy of diamond semiconductor on iridium: a review

Author

Weihua Wang, Benjian Liu, Leining Zhang, Jiecai Han, Kang Liu, Bing Dai, and Jiaqi Zhu

Subjects
diamond wafer, heteroepitaxy, large size, bias enhanced nucleation, textured growth, electronic applications, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

As one of the representatives of carbon-based semiconductors, diamond is called the “Mount Everest” of electronic materials. To maximize its properties and realize its industrial applications, the fabrication of wafer-scale high-quality diamonds is critical. To date, heteroepitaxy is considered as a promising method for the growth of diamond wafers with considerable development. In this review, fundamentals of diamond heteroepitaxy is firstly introduced from several perspectives including nucleation thermodynamics and kinetic, nucleation process at the atomic level, as well as the interplay between the epitaxial film and substrate. Second, the bias enhanced nucleation (BEN) method is reviewed, including BEN setup, BEN process window, nucleation phenomenology (mainly on Iridium), nucleation mechanism by ion bombardment, and large-scale nucleation realization. Third, the following textured growth process is presented, as well as grain boundary annihilation, and dislocation and stress reduction technologies. Fourth, the applications of diamonds in electronic devices are studied, showing its excellent performances in the future power and electronic devices. Finally, prospects in this field are proposed from several aspects.

Published
2022
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9. Core‐shell nanocatalysts with reduced platinum content toward more cost‐effective proton exchange membrane fuel cells

Author

Qun Li, Guisheng Zhang, Botao Yuan, Shijie Zhong, Yuanpeng Ji, Yuanpeng Liu, Xiaoqiang Wu, Qingquan Kong, Jiecai Han, and Weidong He

Subjects
core‐shell coupling, core‐shell structure, cost‐effectiveness, platinum‐based catalysts, proton exchange membrane fuel cells, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract Proton exchange membrane fuel cells (PEMFCs) have become a major component of current clean energy technologies. Accounting for nearly half the cost of a commercial fuel cell stack, Pt‐based catalysts are the main choices for both anode and cathode in PEMFCs. However, catalytical activity and operating life of Pt‐based catalysts are still unsatisfactory. High cost and scarcity of Pt further hinder the development of PEMFCs. Constructing core‐shell structure for Pt‐based catalysts is a promising strategy to enhance the catalytic activity and reduce the cost. In this review, we overview recent advances in Pt‐based core‐shell catalysts according to catalytic reaction types involved in PEMFCs. Furthermore, we discuss the working principle of core‐shell catalysts from the perspective of coupling between core and shell. In the end, we conclude the recent progress and discuss the future developments and facing challenges.

Published
2022
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10. Pseudocapacitance and diffusion-controlled dual modes of MoS2 nano-particles enable high long-cycle anode capacity

Author

Jipeng Liu, Botao Yuan, Dongjiang Chen, Liwei Dong, Haodong Xie, Shijie Zhong, Yuanpeng Ji, Yuanpeng Liu, Jiecai Han, Chunhui Yang, and Weidong He

Subjects
MoS2 nano-structure, Pseudocapacitance, Diffusion-controlled effect, Solid electrolyte interphase, Lithium ion batteries, Chemical engineering, TP155-156
Abstract

Molybdenum disulfide (MoS2), which generally possesses a graphene-like two-dimensional layered structure and unique physicochemical and electrical properties, is an emerging material to next-generation high-energy-density storage beyond the reach of current anode technologies. However, pristine layered MoS2 suffers from low conductivity and poor cycle stability, thus hindering its development in lithium ion batteries (LIBs). Herein, we prepare a self-assembled MoS2 nano-particle structure induced by 1-dodecanethiol (DDT) through a bottom-up approach. The superior rate and high capacity of LIBs are attributed to the large specific surface area (64.29 m2 g−1) and short internal distance, giving rise to the pseudocapacitance and diffusion-controlled process in the electrochemical behavior, respectively. In situ Raman, Density Function Theory (DFT) calculation and X-ray photoelectron spectroscopy verify the conversion from MoS2 to Mo in the lithiation process, and the strong binding energy between Mo and LiF contributes to a stable solid electrolyte interphase during Li+ intercalation/de-intercalation reversible process. The cell using MoS2 nano-particles anode delivers a preferable discharge capacity of 600 mA h g−1 after 1000 cycles at the current density of 1.0 A g−1 than commercial and recently reported MoS2 anodes. This work inspires the development of nano-structure for resistance to large-volume expansion/shrinkage and high stability.

Published
2023
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11. Ultra-compact snapshot spectral light-field imaging

Author

Xia Hua, Yujie Wang, Shuming Wang, Xiujuan Zou, You Zhou, Lin Li, Feng Yan, Xun Cao, Shumin Xiao, Din Ping Tsai, Jiecai Han, Zhenlin Wang, and Shining Zhu

Subjects
Science
Abstract

The authors demonstrate compact spectral light-field imaging by using a transversely dispersive metalens array and a monochrome imaging sensor. They show that 4D images can be obtained in a single shot, and demonstrate discrimination of visually indistinguishable objects.

Published
2022
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12. Coessential-connection by microwave plasma chemical vapor deposition: a common process towards wafer scale single crystal diamond

Author

Guoyang Shu, Bing Dai, Andrey Bolshakov, Weihua Wang, Yang Wang, Kang Liu, Jiwen Zhao, Jiecai Han, and Jiaqi Zhu

Subjects
single crystal diamond, cvd, crystal growth, nucleation, coessential-connection, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Large size single crystal diamond (SCD) wafer has been strongly desired for various of advanced applications, while two major potential approaches, including mosaic growth and heteroepitaxy based on chemical vapor deposition method, are both stuck with respective technical barriers. This paper reveals and summarizes the essential commonality of the two schemes, and denominates the concept of “coessential-connection” (CC) growth. Such generalized concept involved the nature of the single crystal and polycrystalline diamond film deposition with similar mechanism and processes. The principle of CC growth process with detailed classification was elaborated, and influence of nucleus size and orientation mismatch was clarified, which is regarded as the core problem of large area SCD film growth via coessential-connection process.

Published
2022
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13. Advances in ultra-high temperature ceramics, composites, and coatings

Author

Dewei Ni, Yuan Cheng, Jiaping Zhang, Ji-Xuan Liu, Ji Zou, Bowen Chen, Haoyang Wu, Hejun Li, Shaoming Dong, Jiecai Han, Xinghong Zhang, Qiangang Fu, and Guo-Jun Zhang

Subjects
ultra-high temperature ceramics (UHTCs), coatings, composites, high-entropy ultra-high temperature ceramics, Clay industries. Ceramics. Glass, TP785-869
Abstract

Abstract Ultra-high temperature ceramics (UHTCs) are generally referred to the carbides, nitrides, and borides of the transition metals, with the Group IVB compounds (Zr & Hf) and TaC as the main focus. The UHTCs are endowed with ultra-high melting points, excellent mechanical properties, and ablation resistance at elevated temperatures. These unique combinations of properties make them promising materials for extremely environmental structural applications in rocket and hypersonic vehicles, particularly nozzles, leading edges, and engine components, etc. In addition to bulk UHTCs, UHTC coatings and fiber reinforced UHTC composites are extensively developed and applied to avoid the intrinsic brittleness and poor thermal shock resistance of bulk ceramics. Recently, highentropy UHTCs are developed rapidly and attract a lot of attention as an emerging direction for ultra-high temperature materials. This review presents the state of the art of processing approaches, microstructure design and properties of UHTCs from bulk materials to composites and coatings, as well as the future directions.

Published
2021
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14. High-efficiency broadband achromatic metalens for near-IR biological imaging window

Author

Yujie Wang, Qinmiao Chen, Wenhong Yang, Ziheng Ji, Limin Jin, Xing Ma, Qinghai Song, Alexandra Boltasseva, Jiecai Han, Vladimir M. Shalaev, and Shumin Xiao

Subjects
Science
Abstract

Though broadband achromatic metalens are attractive for biological applications, existing metalenses show limited performance in the biological imaging window. Here, the authors report high-efficiency broadband achromatic metalens featuring record-high aspect ratio titanium dioxide metasurfaces.

Published
2021
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15. Direct observation of chaotic resonances in optical microcavities

Author

Shuai Wang, Shuai Liu, Yilin Liu, Shumin Xiao, Zi Wang, Yubin Fan, Jiecai Han, Li Ge, and Qinghai Song

Subjects
Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Abstract Optical microcavities play a significant role in the study of classical and quantum chaos. To date, most experimental explorations of their internal wave dynamics have focused on the properties of their inputs and outputs, without directly interrogating the dynamics and the associated mode patterns inside. As a result, this key information is rarely retrieved with certainty, which significantly restricts the verification and understanding of the actual chaotic motion. Here we demonstrate a simple and robust approach to directly and rapidly map the internal mode patterns in chaotic microcavities. By introducing a local index perturbation through a pump laser, we report a spectral response of optical microcavities that is proportional to the internal field distribution. With this technique, chaotic modes with staggered mode spacings can be distinguished. Consequently, a complete chaos assisted tunneling (CAT) and its time-reversed process are experimentally verified in the optical domain with unprecedented certainty.

Published
2021
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16. Modifying redox properties and local bonding of Co3O4 by CeO2 enhances oxygen evolution catalysis in acid

Author

Jinzhen Huang, Hongyuan Sheng, R. Dominic Ross, Jiecai Han, Xianjie Wang, Bo Song, and Song Jin

Subjects
Science
Abstract

Developing efficient and stable earth-abundant electrocatalysts for acidic oxygen evolution reaction is challenging. Here, the authors modify the local bonding environment of Co3O4 by CeO2 nanocrystallites to regulate the redox properties, thus enhance the catalytic activity.

Published
2021
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17. Reprogrammable meta-hologram for optical encryption

Author

Geyang Qu, Wenhong Yang, Qinghai Song, Yilin Liu, Cheng-Wei Qiu, Jiecai Han, Din-Ping Tsai, and Shumin Xiao

Subjects
Science
Abstract

Here, the authors demonstrate a re-programmable metasurface that can produce arbitrary holographic images for optical encryption. The encrypted information is divided into two matrices and defined to the incident laser to produce arbitrary holographic images.

Published
2020
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18. Lead halide perovskite vortex microlasers

Author

Wenzhao Sun, Yilin Liu, Geyang Qu, Yubin Fan, Wei Dai, Yuhan Wang, Qinghai Song, Jiecai Han, and Shumin Xiao

Subjects
Science
Abstract

Integration of III-V semiconductor microlasers into modern Si or Si3N4 based photonic integrated circuits remains a challenge. Here, the authors demonstrate a perovskite vortex microlaser with highly directional outputs and well-controlled topological charges that is highly compatible with most materials.

Published
2020
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19. All-dielectric metasurface for high-performance structural color

Author

Wenhong Yang, Shumin Xiao, Qinghai Song, Yilin Liu, Yunkai Wu, Shuai Wang, Jie Yu, Jiecai Han, and Din-Ping Tsai

Subjects
Science
Abstract

Here, the authors fabricate a metasurface with high brightness and large gamut structured colors by combining a silicon metasurface with a refractive index matching layer. The experimentally demonstrated gamut is 181.8% of sRGB, 135.6% of Adobe RGB, and 97.2% of Rec.2020.

Published
2020
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20. High‐Polarity Fluoroalkyl Ether Electrolyte Enables Solvation‐Free Li+ Transfer for High‐Rate Lithium Metal Batteries

Author

Liwei Dong, Yuanpeng Liu, Kechun Wen, Dongjiang Chen, Dewei Rao, Jipeng Liu, Botao Yuan, Yunfa Dong, Ze Wu, Yifang Liang, Mengqiu Yang, Jianyi Ma, Chunhui Yang, Chuan Xia, Baoyu Xia, Jiecai Han, Gongming Wang, Zaiping Guo, and Weidong He

Subjects
fluoroalkyl ether, high rate, lithium metal batteries, Li+ solvation structure, long cycle, Science
Abstract

Abstract Lithium metal batteries (LMBs) have aroused extensive interest in the field of energy storage owing to the ultrahigh anode capacity. However, strong solvation of Li+ and slow interfacial ion transfer associated with conventional electrolytes limit their long‐cycle and high‐rate capabilities. Herein an electrolyte system based on fluoroalkyl ether 2,2,2‐trifluoroethyl‐1,1,2,3,3,3‐hexafluoropropyl ether (THE) and ether electrolytes is designed to effectively upgrade the long‐cycle and high‐rate performances of LMBs. THE owns large adsorption energy with ether‐based solvents, thus reducing Li+ interaction and solvation in ether electrolytes. With THE rich in fluoroalkyl groups adjacent to oxygen atoms, the electrolyte owns ultrahigh polarity, enabling solvation‐free Li+ transfer with a substantially decreased energy barrier and ten times enhancement in Li+ transference at the electrolyte/anode interface. In addition, the uniform adsorption of fluorine‐rich THE on the anode and subsequent LiF formation suppress dendrite formation and stabilize the solid electrolyte interphase layer. With the electrolyte, the lithium metal battery with a LiFePO4 cathode delivers unprecedented cyclic performances with only 0.0012% capacity loss per cycle over 5000 cycles at 10 C. Such enhancement is consistently observed for LMBs with other mainstream electrodes including LiCoO2 and LiNi0.5Mn0.3Co0.2O2, suggesting the generality of the electrolyte design for battery applications.

Published
2022
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21. Electrolyte Engineering for High-Voltage Lithium Metal Batteries

Author

Liwei Dong, Shijie Zhong, Botao Yuan, Yuanpeng Ji, Jipeng Liu, Yuanpeng Liu, Chunhui Yang, Jiecai Han, and Weidong He

Subjects
Science
Abstract

High-voltage lithium metal batteries (HVLMBs) have been arguably regarded as the most prospective solution to ultrahigh-density energy storage devices beyond the reach of current technologies. Electrolyte, the only component inside the HVLMBs in contact with both aggressive cathode and Li anode, is expected to maintain stable electrode/electrolyte interfaces (EEIs) and facilitate reversible Li+ transference. Unfortunately, traditional electrolytes with narrow electrochemical windows fail to compromise the catalysis of high-voltage cathodes and infamous reactivity of the Li metal anode, which serves as a major contributor to detrimental electrochemical performance fading and thus impedes their practical applications. Developing stable electrolytes is vital for the further development of HVLMBs. However, optimization principles, design strategies, and future perspectives for the electrolytes of the HVLMBs have not been summarized in detail. This review first gives a systematical overview of recent progress in the improvement of traditional electrolytes and the design of novel electrolytes for the HVLMBs. Different strategies of conventional electrolyte modification, including high concentration electrolytes and CEI and SEI formation with additives, are covered. Novel electrolytes including fluorinated, ionic-liquid, sulfone, nitrile, and solid-state electrolytes are also outlined. In addition, theoretical studies and advanced characterization methods based on the electrolytes of the HVLMBs are probed to study the internal mechanism for ultrahigh stability at an extreme potential. It also foresees future research directions and perspectives for further development of electrolytes in the HVLMBs.

Published
2022
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22. Dual‐Enhanced Doping in ReSe2 for Efficiently Photoenhanced Hydrogen Evolution Reaction

Author

Ran Wang, Jiecai Han, Ping Xu, Tangling Gao, Jun Zhong, Xianjie Wang, Xinghong Zhang, Zhijun Li, Lingling Xu, and Bo Song

Subjects
dual‐enhanced doping, photoenhanced hydrogen evolution reaction (PE‐HER), ReSe 2 nanosheets, Science
Abstract

Abstract Rhenium dichalcogenides (ReX2, X = S or Se) are catalysts that have great promise for the photoenhanced hydrogen evolution reaction (PE‐HER) because of their unique physiochemical properties. However, the catalytic performance is still restricted by their low concentration of electrocatalytic activity sites and poor injection of hot electrons. Herein, dual‐enhancement in ReSe2 nanosheets (NSs) with high concentration of active sites and efficient use of hot electrons is simultaneously achieved with moderate Mo doping. Contributions from exposed catalytically active sites, improved electrical conductivity, and enhanced solar spectral response are systematically investigated. Superior PE‐HER catalytical performance is obtained in Re0.94Mo0.06Se2, which has more catalytically active sites and optimized band structure than other Re1−xMoxSe2 samples. Here, it is demonstrated that only doping can reduce the overpotential (η10) from 239 to 174 mV at −10 mA cm−2 (Δ1η10 = 65 mV). Then, η10 is further improved to 137 mV under simulated AM 1.5 sun illumination (Δ2η10 = 37 mV). The total improvement (Δη10) toward PE‐HER is 102 mV (Δ1η10 + Δ2η10 = 102 mV) in optimal Re0.94Mo0.06Se2. This work presents a new perspective for researching high‐efficiency photoenhanced HER ReSe2‐based electrocatalysts and other layered transition metal dichalcogenides.

Published
2020
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27. A polysulfide-functionalized separator enables robust long-cycle operation of lithium-metal batteries

Author

Mengqiu Yang, Yuanpeng Ji, Yunfa Dong, Shijie Zhong, Haodong Xie, Yuanpeng Liu, Caomeng Zhang, Sue Hao, Chunhui Yang, Jiecai Han, and Weidong He

Abstract

PSU has strong interaction with lithium ions, which is responsible for the uniform distribution of Li+. PE are functionalized with both PSU and PVDF (PESV), Li/Li cell with PESV cycles stably without noticeable current change for nearly 1000 h.

Published
2023

28. Reconstruction of LiF-rich interphases through an anti-freezing electrolyte for ultralow-temperature LiCoO2 batteries

Author

Jipeng Liu, Botao Yuan, Niandong He, Liwei Dong, Dongjiang Chen, Shijie Zhong, Yuanpeng Ji, Jiecai Han, Chunhui Yang, Yuanpeng Liu, and Weidong He

Subjects
Nuclear Energy and Engineering, Renewable Energy, Sustainability and the Environment, Environmental Chemistry, Pollution
Abstract

With iso-butyl formate (IF) as anti-freezing agent, a fluorine–sulfur electrolyte is designed to achieve low coordination number, high desolvation energy and stable LiF-rich interphase, and enables the stable operation of an electric fan at −70 °C.

Published
2023

29. Bias process for heteroepitaxial diamond nucleation on Ir substrates

Author

Weihua Wang, Shilin Yang, Benjian Liu, Xiaobin Hao, Jiecai Han, Bing Dai, and Jiaqi Zhu

Subjects
Inorganic Chemistry, Renewable Energy, Sustainability and the Environment, Process Chemistry and Technology, Organic Chemistry, Materials Chemistry, Ceramics and Composites, Energy Engineering and Power Technology
Published
2022

37. Thermal response, oxidation and ablation of ultra–high temperature ceramics, C/SiC, C/C, graphite and graphite–ceramics

Author

Ping Hu, Xinghong Zhang, Jiecai Han, Baihe Du, and Yuan Cheng

Subjects
Materials science, Polymers and Plastics, business.industry, Mechanical Engineering, Metals and Alloys, engineering.material, Ultra-high-temperature ceramics, Thermal conductivity, Heat flux, Mechanics of Materials, Volumetric heat capacity, visual_art, Heat transfer, Materials Chemistry, Ceramics and Composites, Emissivity, engineering, visual_art.visual_art_medium, Ceramic, Composite material, business, Thermal energy
Abstract

Various thermal protection materials exhibit obviously different and complicated thermal response, oxidation and ablation behavior, which are very important for the appropriate design and selection. However, the relative researches are very few currently. In this work, the thermal response, oxidation and ablation behavior of representative thermal protection materials including ultra–high temperature ceramics, C/SiC, C/C, graphite and graphite–ceramic were investigated systematically in strong heat flux, high enthalpy and low-pressure environments. Thermal response of these materials was analyzed based on experimental results and thermal energy balance that accounts for all of the heat transfer processes transporting energy into and out of the surface. Many factors were playing important roles in the thermal response including thermal conductivity, volumetric heat capacity, catalytic efficiency, emissivity and oxidation characteristics of the materials. The importance of each factor not only depends on the material characteristics such as material composition and phase content but also environment parameters including heat flux, enthalpy, pressure and testing time. The comparisons and relationships of oxidation and ablation behaviors for these materials under extreme environments were also illustrated in detail. Furthermore, thermal response and ablation behaviors of pre–oxidized material or repeated tests were also performed to evaluate the effect of pre–treatment on the performance and reusability of thermal protection materials. This work offers guiding significance for the appropriate design and selection of thermal protection materials.

Published
2022

39. Two-Dimensional High-Entropy Metal Phosphorus Trichalcogenides for Enhanced Hydrogen Evolution Reaction

Author

Ran Wang, Jinzhen Huang, Xinghong Zhang, Jiecai Han, Zhihua Zhang, Tangling Gao, Lingling Xu, Shengwei Liu, Ping Xu, and Bo Song

Subjects
General Engineering, General Physics and Astronomy, General Materials Science
Abstract

Developing earth-abundant and highly effective electrocatalysts for hydrogen evolution reaction (HER) is a prerequisite for the upcoming hydrogen energy society. Two-dimensional (2D) high-entropy metal phosphorus trichalcogenides (MPCh

Published
2022

40. Eco-friendly and sustainable approach of assembling sugars into biobased carbon fibers

Author

Yu Yang, Daming Chen, Yuan Cheng, Boqian Sun, Guangdong Zhao, Weidong Fei, Wenbo Han, Jiecai Han, and Xinghong Zhang

Subjects
Environmental Chemistry, Pollution
Abstract

Sugars are used as precursors to manufacture carbon fibers, obviating the need for hazardous solvents. Through the synergy of sugars and the hydrogel network, the carbon yield was significantly improved and the structure was well retained.

Published
2022

43. Influence of vanadium content on the microstructural evolution and mechanical properties of (TiZrHfVNbTa)C high-entropy carbides processed by pressureless sintering

Author

Jiecai Han, Lei Chen, Yu Zhou, Xinghong Zhang, Peng Jia, Yujin Wang, Yongqiang Tan, Wen Zhang, and Chenguang Xu

Subjects
Materials science, Vanadium, chemistry.chemical_element, Homogeneous distribution, Grain size, Carbide, chemistry, Flexural strength, visual_art, Vickers hardness test, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Grain boundary, Ceramic, Composite material
Abstract

A series of (TiZrHfVNbTa)C high-entropy ceramics with different vanadium contents have been fabricated by pressureless sintering at 2300 °C–2500 °C for 1 h, utilizing self-synthesized carbide powders obtained by carbothermal reduction. The addition of vanadium is beneficial to promote densification process and refine grain, as well as facilitate the homogeneous distribution of metal elements. The distribution of pores is also modified, almost entirely existing at grain boundary, and the integral mechanical properties achieve optimization. However, excess adding vanadium does not favor forming a single-phase (TiZrHfVNbTa)C high-entropy ceramic. The optimal (TiZrHfVNbTa)C high-entropy ceramic sintered at 2300 °C possesses a high relative density of 97.5 % and homogeneous microstructure with small grain size of 1.2 μm. The flexural strength and Vickers hardness reach 473 MPa and 24.9 GPa, respectively. This work has established a cost-effective and convenient preparation of novel (TiZrHfVNbTa)C high-entropy carbide ceramics.

Published
2021

44. Synergistically Designed Dual Interfaces to Enhance the Electrochemical Performance of MoO

Author

Xiaofeng, Li, Ran, Wang, Qing, Wu, Yonghao, Yu, Tangling, Gao, Tai, Yao, Xianjie, Wang, Jiecai, Han, and Bo, Song

Abstract

It is indispensable to develop and design high capacity, high rate performance, long cycling life, and low-cost electrodes materials for lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs). Herein, MoO

Published
2022

45. A Single‐Layer Piezoelectric Composite Separator for Durable Operation of Li Metal Anode at High Rates

Author

Yuanpeng Ji, Botao Yuan, Jiawei Zhang, Zhezhi Liu, Shijie Zhong, Jipeng Liu, Yuanpeng Liu, Mengqiu Yang, Changguo Wang, Chunhui Yang, Jiecai Han, and Weidong He

Subjects
Renewable Energy, Sustainability and the Environment, General Materials Science, Environmental Science (miscellaneous), Waste Management and Disposal, Energy (miscellaneous), Water Science and Technology
Published
2022

46. SiO2/HfO2 Laser Film with Enhanced Protection and Antireflection for Sapphire Infrared Windows at High Temperatures

Author

Si-Ying Zhang, Jiecai Han, Fan Xu, Da-Qiang Zhao, Guo-Shuang Qin, Gui-Gen Wang, and Baolin Wang

Subjects
Materials science, business.industry, Infrared, Laser, Electronic, Optical and Magnetic Materials, law.invention, law, Infrared window, Materials Chemistry, Electrochemistry, Sapphire, Optoelectronics, business, Single crystal
Abstract

It is indispensable to achieve antireflection and protection of the sapphire (i.e., Al2O3 single crystal) infrared window, especially in extreme environments such as high temperature and high-energ...

Published
2021

47. Recent progress in thin separators for upgraded lithium ion batteries

Author

Botao Yuan, Liwei Dong, Dongjiang Chen, Shijie Zhong, Zhaoxu Guang, Qun Li, Yunfa Dong, Jiecai Han, Yuanpeng Ji, and Weidong He

Subjects
Battery (electricity), Materials science, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, Separator (oil production), Free space, Engineering physics, Energy storage, Ion, chemistry, Mechanical strength, Energy density, General Materials Science, Lithium
Abstract

Lithium-based batteries are promising and encouraging energy storage devices in different fields such as portable electronic equipment and new-energy vehicles. Separator, which serves as a physical blockade between electrodes as well as a reliable bridge for ion transport, plays a vital role in maintaining the sustainability of batteries. Unfortunately, most studies in the field of lithium-based batteries have only focused on separators between 20-25 μm so as to achieve a balance between battery safety and performance. However, such thick separators come at the expense of less free space for accommodating active materials inside the battery, thus impeding further development of next-generation lithium-based batteries with high energy density. Thin separators with robust mechanical strength are undoubtedly prime choice to make lithium-based batteries more reliable and safer. This review focuses mainly on recent developments in thin separators for lithium-based batteries, lithium-ion batteries (LIBs) and lithium-sulfur (Li-S) batteries in particular, with a detailed introduction of thin separator preparation methodologies and an analysis of new progress in separators owning the thickness less than 15 μm or an ultrathin functional layer less than 1 μm. Effects of separator thickness on energy density are explored through practical evaluation. Furthermore, a brief outlook for realizing an ‘infinitely-thin’ separator with excellent physical performances and negligible resistance is provided.

Published
2021

48. High-efficiency broadband achromatic metalens for near-IR biological imaging window

Author

Jiecai Han, Limin Jin, Yujie Wang, Xing Ma, Wenhong Yang, Qinmiao Chen, Vladimir M. Shalaev, Qinghai Song, Alexandra Boltasseva, Shumin Xiao, and Ziheng Ji

Subjects
Optics and Photonics, Materials science, Infrared Rays, Surface Properties, Science, General Physics and Astronomy, General Biochemistry, Genetics and Molecular Biology, Article, law.invention, law, Broadband, Nanopillar, Lenses, Titanium, Multidisciplinary, business.industry, Optical Imaging, Metamaterial, General Chemistry, Equipment Design, Aspect ratio (image), Numerical aperture, Nanostructures, Achromatic lens, Metamaterials, Optoelectronics, Photonics, business, Biological imaging
Abstract

Over the past years, broadband achromatic metalenses have been intensively studied due to their great potential for applications in consumer and industry products. Even though significant progress has been made, the efficiency of technologically relevant silicon metalenses is limited by the intrinsic material loss above the bandgap. In turn, the recently proposed achromatic metalens utilizing transparent, high-index materials such as titanium dioxide has been restricted by the small thickness and showed relatively low focusing efficiency at longer wavelengths. Consequently, metalens-based optical imaging in the biological transparency window has so far been severely limited. Herein, we experimentally demonstrate a polarization-insensitive, broadband titanium dioxide achromatic metalens for applications in the near-infrared biological imaging. A large-scale fabrication technology has been developed to produce titanium dioxide nanopillars with record-high aspect ratios featuring pillar heights of 1.5 µm and ~90° vertical sidewalls. The demonstrated metalens exhibits dramatically increased group delay range, and the spectral range of achromatism is substantially extended to the wavelength range of 650–1000 nm with an average efficiency of 77.1%–88.5% and a numerical aperture of 0.24–0.1. This research paves a solid step towards practical applications of flat photonics., Though broadband achromatic metalens are attractive for biological applications, existing metalenses show limited performance in the biological imaging window. Here, the authors report high-efficiency broadband achromatic metalens featuring record-high aspect ratio titanium dioxide metasurfaces.

Published
2021

50. Chiral emission from resonant metasurfaces

Author

Xudong Zhang, Yilin Liu, Jiecai Han, Yuri Kivshar, and Qinghai Song

Subjects
Multidisciplinary
Abstract

Ultracompact sources of circularly polarized light are important for classical and quantum optical information processing. Conventional approaches for generating chiral emission are restricted to excitation power ranges and fail to provide high-quality radiation with perfect polarization conversion. We used the physics of chiral quasi-bound states in the continuum to demonstrate the efficient and controllable emission of circularly polarized light from resonant metasurfaces. Exploiting intrinsic chirality and giant field enhancement, we revealed how to simultaneously modify and control spectra, radiation patterns, and spin angular momentum of photoluminescence and lasing without any spin injection. The superior characteristics of chiral emission and lasing promise multiple applications in nanophotonics and quantum optics.

Published
2022

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