Your search keyword '"covalent bonds"' showing total 11,029 results

1. Prediction of a novel two-dimensional superatomic Cd6S2 monolayer for photocatalytic water splitting.

Author

Wang, Zhifang, Gui, Zaijun, Yan, Chen, Li, Dan, Yuan, Qinqin, and Cheng, Longjiu

Subjects

*CHEMICAL bonds, *ANALYTICAL chemistry, *ABSORPTION coefficients, *LIGHT absorption, *COVALENT bonds

Abstract

Two-dimensional transition metal dichalcogenides possess a significant specific surface area, adjustable bandgaps, and excellent optical absorption properties, rendering them highly conducive to photocatalytic applications. Herein, a MoS2-like 2D superatomic Cd6S2 monolayer is predicted, wherein the octahedral Cd6 superatom unit connects with S atoms via six vertices. Chemical bonding analysis reveals that the remarkable dynamic, thermal, and mechanical stability of the Cd6S2 monolayer results from the covalent Cd–S bonds and the 6-center 8-electron (6c–8e) delocalized bond within the Cd6 core, which ensures the chemical octet rule for both the S atom and the Cd6 superatom. Demonstrating notable optical absorption coefficients and a strain-tuned energy band structure, the Cd6S2 monolayer emerges as a viable candidate for catalyzing the solar-powered splitting of water. This work offers an alternative avenue to modify or improve the properties of 2D materials for photocatalytic applications through superatomic assembly. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electrostatically embedded symmetry-adapted perturbation theory.

Author

Glick, Caroline S., Alenaizan, Asem, Cheney, Daniel L., Cavender, Chapin E., and Sherrill, C. David

Subjects

*PERTURBATION theory, *QUANTUM mechanics, *COVALENT bonds, *WATER use, *ELECTROSTATICS

Abstract

Symmetry-adapted perturbation theory (SAPT) is an ab initio approach that directly computes noncovalent interaction energies in terms of electrostatics, exchange repulsion, induction/polarization, and London dispersion components. Due to its high computational scaling, routine applications of even the lowest order of SAPT are typically limited to a few hundred atoms. To address this limitation, we report here the addition of electrostatic embedding to the SAPT (EE-SAPT) and ISAPT (EE-ISAPT) methods. We illustrate the embedding scheme using water trimer as a prototype example. Then, we show that EE-SAPT/EE-ISAPT can be applied for efficiently and accurately computing noncovalent interactions in large systems, including solvated dimers and protein–ligand systems. In the latter application, particular care must be taken to properly handle the quantum mechanics/molecular mechanics boundary when it cuts covalent bonds. We investigate various schemes for handling charges near this boundary and demonstrate which are most effective in the context of charge-embedded SAPT. [ABSTRACT FROM AUTHOR]

Published

2024

3. Designing building blocks of covalent organic frameworks through on-the-fly batch-based Bayesian optimization.

Author

Yao, Yuxuan and Oberhofer, Harald

Subjects

*REORGANIZATION energy, *COORDINATION polymers, *SYMMETRIC spaces, *STANDARD hydrogen electrode, *COVALENT bonds

Abstract

In this work, we use a Bayesian optimization (BO) algorithm to sample the space of covalent organic framework (COF) components aimed at the design of COFs with a high hole conductivity. COFs are crystalline, often porous coordination polymers, where organic molecular units—called building blocks (BBs)—are connected by covalent bonds. Even though we limit ourselves here to a space of three-fold symmetric BBs forming two-dimensional COF sheets, their design space is still much too large to be sampled by traditional means through evaluating the properties of each element in this space from first principles. In order to ensure valid BBs, we use a molecular generation algorithm that, by construction, leads to rigid three-fold symmetric molecules. The BO approach then trains two distinct surrogate models for two conductivity properties, level alignment vs a reference electrode and reorganization free energy, which are combined in a fitness function as the objective that evaluates BBs' conductivities. These continuously improving surrogates allow the prediction of a material's properties at a low computational cost. It thus allows us to select promising candidates which, together with candidates that are very different from the molecules already sampled, form the updated training sets of the surrogate models. In the course of 20 such training steps, we find a number of promising candidates, some being only variations on already known motifs and others being completely novel. Finally, we subject the six best such candidates to a computational reverse synthesis analysis to gauge their real-world synthesizability. [ABSTRACT FROM AUTHOR]

Published

2024

4. Direct measurement of tensile mechanical properties of few-layer hexagonal boron nitride (h-BN).

Author

Zhou, Jingzhuo, Zhu, Mengya, Han, Ying, Zhou, Xuefeng, Wang, Shanmin, Chen, Juzheng, Wu, Hao, Hou, Yuan, and Lu, Yang

Subjects

*YOUNG'S modulus, *TENSILE tests, *DIELECTRIC properties, *THERMAL conductivity, *COVALENT bonds, *BORON nitride

Abstract

Hexagonal boron nitride (h-BN) has excellent thermal conductivity and dielectric properties, which shows great potential for low-dimensional devices. However, mechanical properties of h-BN have not been comprehensively investigated through experiments. In this work, we conduct in situ direct tensile tests on freestanding single-crystal few-layer h-BN nanosheets with various layer numbers from 3 to 8, with an elaborate sample transfer and characterization protocol. Young's modulus of 573.8 ± 101.4 GPa and a tensile fracture strain up to 3.2% are revealed, which are comparable to its monolayer counterpart. Moreover, we find a tough-to-brittle transition in few-layer h-BN with the increase in layer number, which is attributed the interplay between the van der Waals interaction and in-plane covalent bonding. These findings could open up new possibilities in mechanical research of van der Waals materials and provide guidance for the design of h-BN-based devices and composites. [ABSTRACT FROM AUTHOR]

Published

2024

5. Understanding electronic structure tunability by metal dopants for promoting MgB2 hydrogenation.

Author

Lefcochilos-Fogelquist, H. M., Wan, L. F., Rowberg, A. J. E., Kang, S., Stavila, V., Klebanoff, L. E., Allendorf, M. D., and Wood, B. C.

Subjects

*ELECTRONIC structure, *METALS, *DENSITY functional theory, *HYDRIDES, *COVALENT bonds

Abstract

Hydrogen is a promising energy carrier, but its onboard application is limited by the need for compact, low-pressure storage solutions. Solid-state complex metal hydride systems, such as MgB 2 /Mg(BH 4) 2 , offer high storage capacities but suffer from sluggish kinetics and poor reversibility. One avenue for improving reactivity is to introduce metal dopants to alter electronic and atomic properties, but the role of these chemical additives remains poorly understood, particularly for the hydrogenation reaction. In this work, we used density functional theory calculations on model MgB 2 systems to rationalize the potential role of metal dopants in destabilizing B–B bonding within the MgB 2 lattice. We carried out detailed electronic structure analyses for 28 different metal dopant adatoms to identify properties that contribute to a dopant's efficacy. Based on the simulation results, we propose that an intermediate ionic and covalent character of the bonds between adatoms and B atoms is desirable for facilitating charge redistribution, disrupting the B–B bond network, and promoting H 2 dissociation and H atom chemisorption on MgB 2. [ABSTRACT FROM AUTHOR]

Published

2024

6. Element effects in endohedral metal–metal-bonding fullerenes M2@C82 (M = Sc, Y, La, Lu).

Author

Shui, Yuan, Liu, Dong, Zhao, Pei, Zhao, Xiang, Ehara, Masahiro, Lu, Xing, Akasaka, Takeshi, and Yang, Tao

Subjects

*FULLERENES, *METAL-metal bonds, *ATOMIC orbitals, *IONIZATION energy, *COVALENT bonds, *ORBITAL hybridization

Abstract

Endohedral metal–metal-bonding fullerenes have recently emerged, in which encapsulated metals form a metal–metal bond. However, the physical reasons why some metal elements prefer to form metal–metal bonds inside fullerene are still unclear. Herein, we reported first-principles calculations on electronic structures, bonding properties, dynamics, and thermodynamic stabilities of endohedral metallofullerenes M2@C82 (M = Sc, Y, La, Lu). Multiple bonding analysis approaches unambiguously reveal the existence of one two-center two-electron σ covalent metal–metal bond in M2@C82 (M = Sc, Y, Lu); however, the La–La bonding interaction in La2@C82 is weaker and could not be categorized as one metal–metal covalent bond. The energy decomposition analysis on bonding interactions between an encapsulated metal dimer and fullerene cages suggested that there exist two electron-sharing bonds between a metal dimer and fullerene cages. The reasons why La2 prefers to donate electrons to fullerene cages rather than form a standard σ covalent metal–metal bond are mainly attributed to two following facts: La2 has a lower ionization potential, while the hybridization of ns, (n − 1)d, and np atomic orbitals in La2 is higher. Ab initio molecular dynamic simulations reveal that the M–M bond length at room temperature follows the trend of Sc < Lu < Y. The statistical thermodynamics calculations at different temperatures reveal that the experimentally observed endohedral metal–metal-bonding fullerenes M2@C82 have high concentrations in the endohedral fullerene formation temperature range. [ABSTRACT FROM AUTHOR]

Published

2023

7. Atomic and electronic origin of robust off-state insulation properties in Al-rich AlxTey glass for ovonic threshold switching applications.

Author

Li, Xiao-Dong, Tian, Maoan, Wang, Bai-Qian, Chen, Nian-Ke, and Li, Xian-Bin

Subjects

*COORDINATE covalent bond, *GLASS, *COVALENT bonds, *METAL bonding, *BOND index funds, *METALLIC glasses

Abstract

Ovonic threshold switching (OTS) selectors play a critical role in suppressing the sneak-path current of three-dimensional crossbar integration circuits. Compared to conventional nonmetal-telluride OTS selectors, selectors based on AlxTey glass are found to have both satisfactory on-state current and selectivity. However, it is unclear why the Al-rich AlxTey glass-based OTS selectors have robust insulation properties for reducing the off-state current. This work reveals the structure–property correlations of amorphous AlxTey at the atomic scale by first-principles calculations. It is found that the stoichiometric Al2Te3 glass tends to have a clean bandgap owing to the covalent and dative bonds formed by non-equivalent sp3-hybridized Al orbitals and the lone-pair electrons of Te. Unexpectedly, for Al-rich AlxTey glass (Al2.21Te2.79), the Al–Al bonds formed by redundant Al-atoms have an integrated crystal orbital bond index (ICOBI) of 0.8–0.9, which is much larger than that of Al–Al bonds in pure metals (0.227), indicating they are covalent. It is the covalent Al–Al bonds that ensure the robust insulation characteristics of Al-rich AlxTey glass, while the Te–Te interaction in the Al-poor AlxTey glass (Al1.79Te3.21) produces midgap states, thereby reducing the insulativity. The presented atomic and electronic pictures here will provide useful theoretical insights for designing OTS selectors with improved performances. [ABSTRACT FROM AUTHOR]

Published

2023

8. Simultaneous identification of strong and weak interactions with Pauli energy, Pauli potential, Pauli force, and Pauli charge.

Author

Zhang, Wenbiao, He, Xin, Li, Meng, Zhang, Jingwen, Zhao, Dongbo, Liu, Shubin, and Rong, Chunying

Subjects

*METALLIC bonds, *IONIC bonds, *COVALENT bonds, *CHEMICAL systems, *DENSITY functional theory, *INTERFACIAL bonding

Abstract

Strong and weak interatomic interactions in chemical and biological systems are ubiquitous, yet how to identify them on a unified theoretical foundation is still not well established. Recently, we proposed employing Pauli energy-based indexes, such as strong covalent interaction and bonding and noncovalent interaction indexes, in the framework of density functional theory for the purpose. In this work, we extend our previous theoretical work by directly employing Pauli energy, Pauli potential, Pauli force, and Pauli charge to simultaneously identify both strong covalent bonding and weak noncovalent interactions. Our results from this work elucidate that using their signature isosurfaces, we can identify different types of interactions, either strong or weak, including single, double, triple, and quadruple covalent bonds, ionic bond, metallic bond, hydrogen bonding, and van der Waals interaction. We also discovered strong linear correlations between Pauli energy derived quantities and different covalent bond orders. These qualitative and quantitative results from our present study solidify the viewpoint that a unified approach to simultaneously identify both strong and weak interactions is possible. In our view, this work signifies one step forward towards the goal of establishing a density-based theory of chemical reactivity in density functional theory. [ABSTRACT FROM AUTHOR]

Published

2023

9. Effects of N doping on mechanical properties of Fe and interlayer adhesion of Fe with Cr, Ti, and Si: A spin-polarized density functional theory study.

Author

Yang, Zaixiu, Niu, Zhenwei, Tang, Mei, Zhang, Junyan, and Zhang, Bin

Subjects

*IRON clusters, *DENSITY functional theory, *COVALENT bonds, *SURFACE properties

Abstract

Interlayers between a substrate and a functional film are used extensively to tailor film adhesion and avoid failure induced by delamination. With nitrogen doping increasingly used to improve the surface properties of steel, how to select appropriate interlayers for high film adhesion on substrate remains elusive in theory. Using spin-polarized density functional theory computations, the authors investigated the effects of N doping on the mechanical properties of Fe and its adhesion with widely used Cr, Ti, and Si interlayers. The results showed that N atoms doped at the Fe octahedron center increased hardness by 30% under 4 wt. % N. N atom at Cr/Fe, Ti/Fe, Si/Fe interfaces interestingly increased the interlayer adhesion of Ti/Fe and Si/Fe, while reducing that of Cr/Fe. This behavior is attributed to competition between magnetic coupling and atomic bonding. For Cr/Fe with strong magnetic coupling, the reduction in adhesion was resulted from doped N that inhibited magnetic coupling at the interface. For Ti/Fe and Si/Fe with weak magnetic coupling, the formation of covalent bonds at the interface by the N atom increased interfacial adhesion. This study provides insights into the nitrogen doping of steel and the selection of proper interlayers for strong film-substrate adhesion. [ABSTRACT FROM AUTHOR]

Published

2023

10. Comparison of classical and ab initio simulations of hydronium and aqueous proton transfer.

Author

Maurer, Manuela and Lazaridis, Themis

Subjects

*PROTONS, *BAND gaps, *COVALENT bonds, *MOLECULAR dynamics, *HYDROGEN bonding, *VALENCE bonds

Abstract

Proton transport in aqueous systems occurs by making and breaking covalent bonds, a process that classical force fields cannot reproduce. Various attempts have been made to remedy this deficiency, by valence bond theory or instantaneous proton transfers, but the ability of such methods to provide a realistic picture of this fundamental process has not been fully evaluated. Here we compare an ab initio molecular dynamics (AIMD) simulation of an excess proton in water to a simulation of a classical H3O+ in TIP3P water. The energy gap upon instantaneous proton transfer from H3O+ to an acceptor water molecule is much higher in the classical simulation than in the AIMD configurations evaluated with the same classical potential. The origins of this discrepancy are identified by comparing the solvent structures around the excess proton in the two systems. One major structural difference is in the tilt angle of the water molecules that accept an hydrogen bond from H3O+. The lack of lone pairs in TIP3P produces a tilt angle that is too large and generates an unfavorable geometry after instantaneous proton transfer. This problem can be alleviated by the use of TIP5P, which gives a tilt angle much closer to the AIMD result. Another important factor that raises the energy gap is the different optimal distance in water-water vs H3O+-water H-bonds. In AIMD the acceptor is gradually polarized and takes a hydronium-like configuration even before proton transfer actually happens. Ways to remedy some of these problems in classical simulations are discussed. [ABSTRACT FROM AUTHOR]

Published

2023

11. First-principle and experimental investigation into the interfacial characters of Ti-doped ZTA and high chromium cast iron.

Author

Hou, Ming-hao, Jia, Lei, Huang, Rui, Li, Chen-wei, Shi, Zhong-qi, Cui, Jie, Lu, Zhen-lin, and Kondoh, Katsuyoshi

Subjects

*ORBITAL hybridization, *IONIC bonds, *CAST-iron, *COVALENT bonds, *CERAMIC materials

Abstract

Ti doping can improve the interfacial wettability and bonding condition between ZTA ceramic and high chromium cast iron (HCCI), but the underlying mechanism is still unclear. Therefore, the effects of Ti doping on the interfacial characters between ZTA and HCCI were investigated by experiment and first-principles calculations. Results of XRD, SEM, and high-temperature drop test indicate the presence of Ti at the interface and its effect on the formation of interfacial diffusion layer to improve the interface wettability and bonding obviously. The heat of segregation and work of adhesion obtained by first-principle calculations shows that the improvement in interface wettability and bonding is due to the promotion of dopped Ti atoms on the diffusion of Fe, Al, and Zr elements, but not the diffusion of Ti itself. Further investigation from the electronic level reveals that the doped Ti changes the charge distribution and orbital hybridization, and thus makes the formation or enhancement of strong ionic bonds and covalent bonds at the interface, improving the bonding strength and wettability of interfaces in ZTA/HCCI. The findings of this research can offer new insights into the modification of ceramics and enlarge the application of advanced ceramic materials. [ABSTRACT FROM AUTHOR]

Published

2024

12. Poly[2]catenane Gels Based on Sequential Assembly of Small Molecules†.

Author

Zhang, Hanwei, Li, Jinsa, Hu, Ziqing, and Ji, Xiaofan

Subjects

*SUPRAMOLECULAR chemistry, *SUPRAMOLECULAR polymers, *HYDROGEN bonding, *COVALENT bonds, *SMALL molecules

Abstract

Comprehensive Summary: Polycatenane gels have attracted extensive attention due to their high degree of freedom and mobility. However, the syntheses of poly[2]catenane gels reported to date all rely on the polymer as the backbone. Herein, we prepared poly[2]catenane gels based on entirely sequential assembly of small molecules. Monomer M1 with two unclosed rings was first prepared, which self‐assembled to form supramolecular polymers (SPs) via hydrogen bonding and π‐π interactions. Upon adding small molecule monomers M2 and M3 with aldehyde groups, ring closing of SPs occurred because the amino groups in the SPs reacted with M2 to form imine bonds. In addition, M3, which had twice the number of aldehyde groups as M2, enabled SPs to ring‐close, causing the proceeding of crosslinking process at the same time. Thus linear SPs were transformed into poly[2]catenane gel networks. Due to the presence of hydrogen bonds in the poly[2]catenane gel, the gel also possessed stimulus responsiveness and self‐healing properties. [ABSTRACT FROM AUTHOR]

Published

2024

13. Poly[2]catenane Gels Based on Sequential Assembly of Small Molecules†.

Author

Zhang, Hanwei, Li, Jinsa, Hu, Ziqing, and Ji, Xiaofan

Subjects

SUPRAMOLECULAR chemistry, SUPRAMOLECULAR polymers, HYDROGEN bonding, COVALENT bonds, SMALL molecules

Abstract

Comprehensive Summary: Polycatenane gels have attracted extensive attention due to their high degree of freedom and mobility. However, the syntheses of poly[2]catenane gels reported to date all rely on the polymer as the backbone. Herein, we prepared poly[2]catenane gels based on entirely sequential assembly of small molecules. Monomer M1 with two unclosed rings was first prepared, which self‐assembled to form supramolecular polymers (SPs) via hydrogen bonding and π‐π interactions. Upon adding small molecule monomers M2 and M3 with aldehyde groups, ring closing of SPs occurred because the amino groups in the SPs reacted with M2 to form imine bonds. In addition, M3, which had twice the number of aldehyde groups as M2, enabled SPs to ring‐close, causing the proceeding of crosslinking process at the same time. Thus linear SPs were transformed into poly[2]catenane gel networks. Due to the presence of hydrogen bonds in the poly[2]catenane gel, the gel also possessed stimulus responsiveness and self‐healing properties. [ABSTRACT FROM AUTHOR]

Published

2024

14. Polydopamine-functionalized polyethersulfone membrane: A paradigm advancement in the field of α-amylase stability and immobilization.

Author

Mehrabi, Zahra, Harsij, Zohreh, and Taheri-Kafrani, Asghar

Subjects

*IMMOBILIZED enzymes, *COVALENT bonds, *INDUSTRIAL capacity, *FOULING, *ENZYMES, *POLYETHERSULFONE

Abstract

Biocatalytic membranes have great potential in various industrial sectors, with the immobilization of enzymes being a crucial stage. Immobilizing enzymes through covalent bonds is a complex and time-consuming process for large-scale applications. Polydopamine (PDA) offers a more sustainable and eco-friendly alternative for enzyme immobilization. Therefore, surface modification with polydopamine as mussel-inspired antifouling coatings has increased resistance to fouling. In this study, α-amylase enzyme was covalently bound to a bioactive PDA-coated polyethersulfone (PES) membrane surface using cyanuric chloride as a linker. The optimal activity of α-amylase enzyme immobilized on PES/PDA membrane was obtained at temperature and pH of 55°C and 6.5, respectively. The immobilized enzyme can be reused up to five reaction cycles with 55 % retention of initial activity. Besides, it maintained 60 % of its activity after being stored for five weeks at 4°C. Additionally, the immobilized enzyme demonstrated increased Michaelis constant and maximum velocity values during starch hydrolysis. The results of the biofouling experiment of various membranes in a dead-end cell demonstrated that the PES membrane's water flux increased from 6722.7 Lmh to 7560.2 Lmh after PDA modification. Although α-amylase immobilization reduced the flux to 7458.5 Lmh due to enhanced hydrophilicity, compared to unmodified membrane. The findings of this study demonstrated that the membrane produced through co-deposition exhibited superior hydrophilicity, enhanced coating stability, and strong antifouling properties, positioning it as a promising candidate for industrial applications. [Display omitted] • α-Amylase was covalently immobilized onto polydopamine-functionalized polyethersulfone membrane. • Surface modification with polydopamine generated a mussel-inspired coating to inhibit fouling. • The immobilization technique effectively preserved the activity of α-amylase enzyme. • The biocatalyst membrane exhibited superior stability and strong antifouling properties. [ABSTRACT FROM AUTHOR]

Published

2024

15. Fabrication of soy protein–polyphenol covalent complex nanoparticles with improved wettability to stabilize high‐oil‐phase curcumin emulsions.

Author

Xu, Jingjing, Ji, Fuyun, Luo, Shuizhong, Jiang, Shaotong, Yu, Zhenyu, Ye, Aiqian, and Zheng, Zhi

Subjects

*SOY proteins, *EPIGALLOCATECHIN gallate, *COVALENT bonds, *CONTACT angle, *ULTRAVIOLET radiation

Abstract

BACKGROUND: Recent studies have shown that the wettability of protein‐based emulsifiers is critical for emulsion stability. However, few studies have been conducted to investigate the effects of varying epigallocatechin gallate (EGCG) concentrations on the wettability of protein‐based emulsifiers. Additionally, limited studies have examined the effectiveness of soy protein–EGCG covalent complex nanoparticles with improved wettability as emulsifiers for stabilizing high‐oil‐phase (≥ 30%) curcumin emulsions. RESULTS: Soy protein isolate (SPI)–EGCG complex nanoparticles (SPIEn) with improved wettability were fabricated to stabilize high‐oil‐phase curcumin emulsions. The results showed that EGCG forms covalent bonds with SPI, which changes its secondary structure, enhances its surface charge, and improves its wettability. Moreover, SPIEn with 2.0 g L −1 EGCG (SPIEn‐2.0) exhibited a better three‐phase contact angle (56.8 ± 0.3o) and zeta potential (−27 mV) than SPI. SPIEn‐2.0 also facilitated the development of curcumin emulsion gels at an oil volume fraction of 0.5. Specifically, the enhanced network between droplets as a result of the packing effects and SPIEn‐2.0 with inherent antioxidant function was more effective at inhibiting curcumin degradation during long‐term storage and ultraviolet light exposure. CONCLUSION: The results of the present study indicate that SPIEn with 2.0 g L −1 EGCG (SPIEn‐2.0) comprises the optimum conditions for fabricating emulsifiers with improved wettability. Additionally, SPIEn‐0.2 can improve the physicochemical stability of high‐oil‐phase curcumin emulsions, suggesting a novel strategy to design and fabricate high‐oil‐phase emulsion for encapsulating bioactive compounds. © 2024 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

16. Preparation and Properties of Self-Healing Polyurethane-Modified Asphalt Composed of Different Soft Segments.

Author

Li, Kenan, Fang, Kai, Niu, Yanhui, Li, Xin, Xu, Mingliang, Gan, Congyang, and Ai, Tao

Subjects

*FATIGUE limit, *ASPHALT pavements, *RHEOLOGY, *COVALENT bonds, *POLYBUTADIENE

Abstract

When asphalt pavement is in practical use, it is prone to cracking and other diseases due to the long-term effects of load and climate and the restricted self-healing properties of the asphalt material. In order to improve the properties and durability of asphalt pavement, we introduced disulfide bonds into polyurethane (PU) in this study. We prepared polyurethane-modified asphalt (PUA) containing dynamic disulfide covalent bonds using polytetrahydrofuran (PTMG), polyethylene adipate (PEA), and hydroxyl-terminated polybutadiene (HTPB) as soft segments. Subsequently, the rheological properties, healing performance, and microstructure of the PUA were studied. The results indicated that the PU with disulfide bonds was integrated into the asphalt and had good dispersity. A cross-linked network structure formed between them. PUA with HTPB as the soft segment had excellent high-temperature deformation and low-temperature cracking resistance and a prominent advantage in durability. In comparison, PUA synthesized with PEA had better high-temperature performance and fatigue resistance, and PUA synthesized with PTMG had considerable low-temperature properties and stability. The disulfide bonds had a positive impact on the high-temperature performance, aging resistance, and healing properties of PUA through constant dynamic exchange and topological rearrangement effects. This study provides a reference for the preparation of PUA with ideal self-healing ability and has instructive significance for the selection of soft segment materials for synthesizing PUA. [ABSTRACT FROM AUTHOR]

Published

2024

17. A facile method for carbon nanotube/carbon fiber‐reinforced polylactic acid composites.

Author

Cao, Jiandong, Gao, Yan, Li, Guohao, He, Bohui, Ren, Shangyuan, Bai, Yongxiao, and Wang, Fushan

Subjects

*CARBON nanotubes, *COUPLING agents (Chemistry), *COVALENT bonds, *SURFACE roughness, *TISSUE scaffolds, *POLYLACTIC acid

Abstract

Highlights The mechanical strength of polylactic acid (PLA) can be improved by carbon fiber (CF) compositing to expand its application in tissue engineering scaffolds. However, the mechanical strength of CF‐reinforced polylactic acid (CFRPLA) composites is compromised due to weak interfacial interaction resulting from the chemically inert surface of CF. In the article, carbon nanotube (CNT) with poly(diallyldimethylammonium chloride) (PDDA) as a coupling agent was covered on CF to improve the chemical activity and roughness of the surface of CF, and then the as‐prepared CF‐PCNT were further incorporated into PLA via melt compounding. The yield strength, modulus, and thermal conductivity of PLA/CF‐PCNT were 14.09%, 7.65%, and 5.24% higher than those of PLA/CF, respectively, and the volume resistivity was 99.74% lower at a 10 wt% loading. The enhancement for the mechanical properties of PLA/CF‐PCNT composites could be ascribed to the mechanical locking, hydrogen bonds and covalent bonds between CF and matrix through the interface modulation of CNT and PDDA. This facile and non‐destructive method offers a novel strategy for the modification of CF fillers. CF was modified by PDDA and CNT through a facile and non‐destructive method. The active functional groups and roughness on the surface of CF were increased. The surfaces of CFs were characterized by FT‐IR, Raman spectra, XPS and SEM. The interface was improved by mechanical locking, covalent, and hydrogen bonds. The mechanical strength, electrical and thermal conductivity of composites were improved. [ABSTRACT FROM AUTHOR]

Published

2024

18. Exploring the Physical Properties of LiBeX (X = Sb, Bi) Compounds via Ab Initio Approach.

Author

Mazhar, Muhammad, Andleeb, Farah, Imran, Iqra, Manzoor, Alina, Altaf, Saima, Rafiq, Muhammad Amir, and Rasul, Muhammad Nasir

Subjects

*FRONTIER orbitals, *ELECTRONIC structure, *COVALENT bonds, *OPTOELECTRONICS, *PHOTOVOLTAIC power generation

Abstract

In the current study, it is aimed to scrutinize the physical properties of LiBeX (X = Sb, Bi) compounds in detail. Density‐functional‐theory‐based WIEN2k and the Vienna Ab initio Simulation Package, employing the generalized gradient approximation of Perdew–Burke–Ernzerhof, Wu–Cohen, and Tran–Blaha‐modified Becke–Johnson (TB‐mBJ) exchange‐correlation schemes, are utilized to better validate the outcomes. The compounds exhibit energetic, lattice dynamic, and mechanical stability. Electronic structure calculations using the TB‐mBJ functional reveal indirect bandgaps of 1.007 eV for LiBeSb and 0.789 eV for LiBeBi compounds, respectively. The partial charge distribution in the highest occupied molecular orbital and the lowest unoccupied molecular orbital discloses maximum charge localization around the X site. The examination of the crystal orbital Hamilton population reveals the strongest BeX bonding interactions among the bonding pairs. The physio‐mechanical properties indicate brittle and mechanically anisotropic behavior of both compounds, with covalent bonding characteristics. The comparative analysis suggests that the TB‐mBJ potential is suitable for bandgap calculations due to its close alignment with experimental results. Additionally, the optimized results for these compounds indicate their potential for use in optoelectronic devices, such as visible to ultraviolet sensors and photovoltaics. The determined properties are consistent with previous theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2024

19. Mimosa‐Inspired Body Temperature‐Responsive Shape Memory Polymer Networks: High Energy Densities and Multi‐Recyclability.

Author

Kong, Qingming, Tan, Yu, Zhang, Haiyang, Zhu, Tengyang, Li, Yitan, Xing, Yongzheng, and Wang, Xu

Subjects

*SHAPE memory polymers, *RECYCLABLE material, *POLYMER networks, *COVALENT bonds, *ENERGY density

Abstract

Inspired by the Mimosa plant, this study herein develops a unique dynamic shape memory polymer (SMP) network capable of transitioning from hard to pliable with heat, featuring reversible actuation, self‐healing, recyclability, and degradability. This material is adept at simulating the functionalities of artificial muscles for a variety of tasks, with a remarkable specific energy density of 1.8 J g−1—≈46 times higher than that of human skeletal muscle. As an intelligent manipulator, it demonstrates remarkable proficiency in identifying and handling items at high temperatures. Its suitable rate of shape recovery around human body temperature indicates its promising utility as an implant material for addressing acute obstructions. The dynamic covalent bonding within the network structure not only provides excellent resistance to solvents but also bestows remarkable abilities for self‐healing, reprocessing, and degradation. These attributes significantly boost its practicality and environmental sustainability. Anticipated to promote advancements in the sectors of biomedical devices, soft robotics, and smart actuators, this SMP network represents a forward leap in simulating artificial muscles, marking a stride toward the future of adaptive and sustainable technology. [ABSTRACT FROM AUTHOR]

Published

2024

20. Metal‐Ligand Bonds Based Reprogrammable and Re‐Processable Supramolecular Liquid Crystal Elastomer Network.

Author

Zhou, Xiaorui, Jin, Binjie, Zhu, Zhan, Wu, Jingjun, Zhao, Qian, and Chen, Guancong

Subjects

*SUPRAMOLECULAR polymers, *LIQUID crystals, *SMART materials, *COVALENT bonds, *SOFT robotics

Abstract

Dynamic covalent bonds endow liquid crystal elastomers (LCEs) with network rearrangeability, facilitating the fixation of mesogen alignment induced by external forces and enabling reversible actuation. In comparison, the bond exchange of supramolecular interactions is typically too significant to stably maintain the programmed alignment, particularly under intensified external stimuli. Nevertheless, remaking and recycling of supramolecular interaction‐based polymer networks are more accessible than those based on dynamic covalent bonds, as the latter are difficult to completely dissociate. Thus, preparing an LCE that possesses both supramolecular‐like exchangeability and covalent bond‐level stability remains a significant challenge. In this work, we addressed this issue by employing metal‐ligand bonds as the crosslinking points of LCE networks. As such, mesogen alignment can be repeatedly encoded through metal‐ligand bond exchange and stably maintained after programming, since the bond exchange rate is sufficiently slow when the programming and actuation temperatures are below the bond dissociation temperature. More importantly, the metal‐ligand bonds can be completely dissociated at high temperatures, allowing the LCE network to be dissolved in a solvent and reshaped into desired geometries via solution casting. Building on these properties, our LCEs can be fabricated into versatile actuators, such as reversible folding origami, artificial muscles, and soft robotics. [ABSTRACT FROM AUTHOR]

Published

2024

21. Dynamically Crosslinked Hydrogels Composed of Carboxymethyl Chitosan and Tannic Acid for Sustained Release of Encapsulated Protein.

Author

Yamada, Tasuku, Mizuno, Yosuke, Tian, Li, Kitaguchi, Tetsuya, and Fujie, Toshinori

Subjects

*GREEN fluorescent protein, *BIOPRINTING, *COVALENT bonds, *CONCENTRATION gradient, *SCHIFF bases, *TANNINS

Abstract

Polysaccharide‐based hydrogels are promising for biomedical applications such as drug delivery owing to their biocompatibility, biodegradability, and bioactivities. In particular, there is a need for hydrogels with injectability for minimally invasive therapies and controlled sustained release for sustained drug effect. Hydrogels made from carboxymethyl chitosan (CMC) and tannic acid (TA) (CMC‐TA) contain dynamic covalent bonds owing to autoxidation between CMC and TA, and interact with proteins via TA, elucidation of the detailed mechanism of dynamic covalent bonding in CMC‐TA hydrogels will facilitate stable loading and zero‐order release of proteins. Herein, the physical properties of oxidized CMC‐TA (Oxi‐CMC‐TA) prepared for the encapsulation and sustained release of proteins are explored. Following incubation at 37 °C for 24 h, CMC‐TA undergoes secondary crosslinking by autoxidation to produce Oxi‐CMC‐TA. Notably, CMC‐TA is viscoelastic and shear‐thinning, allowing for injection and 3D bioprinting. Indeed, CMC‐TA can be 3D‐printed with green fluorescent protein (GFP) encapsulated in its matrix. Oxi‐CMC‐TA also exhibits an affinity for protein owing to its gallol groups, enabling Oxi‐CMC‐TA to collect GFP in aqueous solutions against a concentration gradient. Moreover, Oxi‐CMC‐TA releases GFP over 15 days. Injectable, 3D‐printable, protein‐collecting, and zero‐order sustained‐releasing Oxi‐CMC‐TA has the potential to make a significant contribution to drug delivery. [ABSTRACT FROM AUTHOR]

Published

2024

22. Closed‐Loop Recyclable and Totally Renewable Liquid Crystal Networks with Room‐Temperature Programmability and Reconfigurable Functionalities.

Author

Zhang, Chenxuan, Zhang, Zhuoqiang, and Liu, Xiaokong

Subjects

*COVALENT crystals, *LIQUID crystals, *POLYMER degradation, *WASTE recycling, *COVALENT bonds

Abstract

Dynamic covalent liquid crystal networks (DCv‐LCNs) with straightforward (re)programmability, reprocessability, and recyclability facilitates the manufacture of sophisticated LCN actuators and intelligent robots. However, the DCv‐LCNs are still limited to heat‐assisted programming and polymer‐to‐polymer reprocessing/recycling, which inevitably lead to deterioration of the LCN structures and the actuation performances after repeated programming/processing treatments, owing to the thermal degradation of the polymer network and/or external agent interference. Here, a totally renewable azobenzene‐based DCv‐LCN with room‐temperature programmability and polymer‐to‐monomers chemical recyclability is reported, which was synthesized by crosslinking the azobenzene‐containing dibenzaldehyde monomer and the triamine monomer via the dynamic and dissociable imine bonds. Thanks to the water‐activated dynamics of the imine bonds, the resultant DCv‐LCN can be simply programmed, upon water‐soaking at room temperature, to yield a UV/Vis light‐driven actuator. Importantly, the reported DCv‐LCN undergoes depolymerization in an acid‐solvent medium at room temperature because of the acid‐catalyzed hydrolysis of the imine bonds, giving rise to easy separation and recovery of both monomers in high purity, even with tolerance to additives. The recovered pure monomers can be used to regenerate totally new DCv‐LCNs and actuators, and their functionalities can be reconfigured by removing old and introducing new additives, by implementing the closed‐loop polymer‐monomers‐polymer recycling. [ABSTRACT FROM AUTHOR]

Published

2024

23. Modulating Charge‐Transfer Excited States of Multiple Resonance Emitters via Intramolecular Covalent Bond Locking.

Author

Huang, Tingting, Xu, Yincai, Lu, Xueying, Qu, Yupei, Wei, Jinbei, and Wang, Yue

Subjects

*DELAYED fluorescence, *LIGHT emitting diodes, *COVALENT bonds, *QUANTUM efficiency, *EXCITED states, *ORGANIC light emitting diodes

Abstract

Advanced multiple resonance thermally activated delayed fluorescence (MR‐TADF) emitters with high efficiency and color purity have emerged as a research focus in the development of ultra‐high‐definition displays. Herein, we disclose an approach to modulate the charge‐transfer excited states of MR emitters via intramolecular covalent bond locking. This strategy can promote the evolution of strong intramolecular charge‐transfer (ICT) states into weak ICT states, ultimately narrowing the full‐width at half‐maximum (FWHM) of emitters. To modulate the ICT intensity, two octagonal rings are introduced to yield molecule m‐DCzDAz‐BNCz. Compounds m‐CzDAz‐BNCz and m‐DCzDAz‐BNCz exhibit bright light‐green and green fluorescence in toluene, with emission maxima of 504 and 513 nm, and FWHMs of 28 and 34 nm, respectively. Sensitized organic light‐emitting diodes (OLEDs) employing emitters m‐CzDAz‐BNCz and m‐DCzDAz‐BNCz exhibit green emission with peaks of 508 and 520 nm, Commission Internationale de L'Eclairage (CIE) coordinates of (0.12, 0.65) and (0.19, 0.69), and maximum external quantum efficiencies (EQEs) of 30.2 % and 32.6 %, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

24. Synthesis of body temperature-triggerable dynamic liquid crystal elastomers using Diels–Alder crosslinkers.

Author

St-Germain, Jérémy Baribeault and Zhao, Yue

Subjects

*LIQUID crystals, *BODY temperature, *COVALENT bonds, *WASTE recycling, *ELASTOMERS

Abstract

Novel liquid crystal elastomers (LCEs) with solely Diels–Alder dynamic covalent bonds (DADCBs) as crosslinks and body temperature sensitivity have been developed. The appealing attributes of the material, such as recyclability, reprogrammability and reconfigurability, have led to soft actuators capable of reversible deformation stimulated by shifting between ambient and body temperature, highlighting the potential for innovative applications in the biomedical field. [ABSTRACT FROM AUTHOR]

Published

2024

25. Construction of bispecific antibodies by specific pairing between the heavy chain and the light chain using removable SpyCatcher/SnoopCatcher units.

Author

Yoshida, Jyunna, Kato, Yuki, Isogawa, Ai, Tanaka, Yoshikazu, Kumagai, Izumi, Asano, Ryutaro, Nakanishi, Takeshi, and Makabe, Koki

Subjects

*BISPECIFIC antibodies, *IMMUNOTECHNOLOGY, *COVALENT bonds, *ANTIBODY formation, *T cells, *TRANSGLUTAMINASES

Abstract

During the production of bispecific antibodies (bsAbs), nonspecific pairing results in low yields of target bsAb molecules, an issue known as the "mispairing problem." Several antibody engineering techniques have been developed to overcome mispairing issues. Here, we introduce "bsAb by external pairing and excision" (BAPE), a novel chain pairing method that induces specific chain pairing by fusing external SpyCatcher/Tag and SnoopCatcher/Tag units. These tags are then removed via protease cleavage. In this study, we applied this method to force the correct pairings of heavy and light chains while the heavy-chain pairing was achieved by the Knobs-into-Holes mutation. We then confirmed the formation of interchain bridges with covalent isopeptide bonds. Both anti-CD3/anti-Her2 and anti-CD3/anti-EGFR bsAbs displayed satisfactory target binding activities and in vitro cell-killing activity with activated T-cells. [ABSTRACT FROM AUTHOR]

Published

2024

26. Polarizable H‐Bond Concept in Aromatic Poly(thiourea)s: Unprecedented High Refractive Index, Transmittance, and Degradability at Force to Enhance Lighting Efficiency.

Author

Watanabe, Seigo, Cavinato, Luca M., Calvi, Vladimir, van Rijn, Richard, Costa, Rubén D., and Oyaizu, Kenichi

Subjects

*ELECTRIC batteries, *MOLECULES, *REFRACTIVE index, *QUANTUM efficiency, *COVALENT bonds, *POLYMER networks

Abstract

Developing transparent and highly refractive environmentally friendly polymers has not been realized yet toward sustainable optoelectronics. This work describes poly(thiourea)s (PTUs) design following a new "polarizable group synergy" concept, combining highly polarizable hydrogen bonding groups and aromatic‐based spacers to form densely packed and high‐refractive‐index polymer networks. Specifically, PTUs containing m‐ and p‐phenylene spacers exhibit an easy synthesis, high thermostability (Tg = 159 °C), visible transparency (>92%T at 1 µm‐film), ultra‐high refractive index (nD = 1.81) based on the random H‐bonding arrays with a high packing constant (Kp = 0.738), and straightforward preparation of flexible films via solvent‐based techniques. Capitalizing on these assets, PTU‐films are integrated into benchmark graphene‐based lighting device architectures based on the light‐emitting electrochemical cells (LECs) concept. A joint optical modeling and experimental validation confirm the increase in external quantum efficiency expected by the enhanced light out‐coupling of PTU‐films. Finally, PTUs are efficiently depolymerized to low molecular weight compounds by simply adding diamines under heating, following the dynamic covalent bond exchange between thiourea moieties. Overall, this work highlights the PTU family as new promising materials with a unique polarizable H‐bond design to meet efficient and sustainable thin‐film lighting devices. [ABSTRACT FROM AUTHOR]

Published

2024

27. Ionic Covalent Organic Frameworks Consisting of Tetraborate Nodes and Flexible Linkers.

Author

Wayment, Lacey J., Huang, Shaofeng, Chen, Hongxuan, Lei, Zepeng, Ley, Ashley, Lee, Se‐Hee, and Zhang, Wei

Subjects

*COVALENT bonds, *CARBON sequestration, *CRYSTALLINE polymers, *DEGREE of polymerization, *ENERGY storage

Abstract

Covalent organic frameworks (COFs) have emerged as versatile materials with many applications, such as carbon capture, molecular separation, catalysis, and energy storage. Traditionally, flexible building blocks have been avoided due to their potential to disrupt ordered structures. Recent studies have demonstrated the intriguing properties and enhanced structural diversity achievable with flexible components by judicious selection of building blocks. This study presents a novel series of ionic COFs (ICOFs) consisting of tetraborate nodes and flexible linkers. These ICOFs use borohydrides to irreversibly deprotonate the alcohol monomers to achieve a high degree of polymerization. Structural analysis confirms the dia topologies. Reticulation is explored using various monomers and metal counterions. Also, these frameworks exhibit excellent stability in alcohols and coordinating solvents. The materials have been tested as single‐ion conductive solid‐state electrolytes. ICOF‐203‐Li displays one of the lowest activation energies reported for ion conduction. This tetraborate chemistry is anticipated to facilitate further structural diversity and functionality in crystalline polymers. [ABSTRACT FROM AUTHOR]

Published

2024

28. N-P covalent bond regulation of mesoporous carbon-based catalyst for lowered oxygen reduction overpotential and enhanced zinc-air battery performance.

Author

Ao, Kelong, Yue, Xian, Zhang, Xiangyang, Zhao, Hu, Liu, Jiapeng, Shi, Jihong, Daoud, Walid A., and Li, Hong

Subjects

*OXYGEN reduction, *COVALENT bonds, *CATALYSTS, *ACTIVATION energy, *POWER density, *ELECTROCATALYSTS, *SOLID state batteries

Abstract

We introduce N-P pair into the carbon matrix to construct N,P-C electrocatalyst by a facile pyrolysis strategy. Benefiting from the moderate adsorption energy of *OH on the active sites (C adjacent to P atom in N-P), the achieved N,P-C-1000 displays outstanding alkaline ORR performance and high power density primary liquid and solid ZABs. [Display omitted] • N-P pair was introduced into the carbon matrix to construct N,P-C electrocatalyst by a facile pyrolysis strategy. • The catalyst exhibits superior ORR activity with a E 1/2 of 0.83 V, comparable to that of commercial 20 wt% Pt/C. • Its C-2p orbit has higher interaction strength with the intermediates, thus reducing the overall reaction energy barrier. • High power density primary liquid and solid ZABs are achieved using N,P-C-1000 as cathodic catalysts. Developing sustainable metal-free carbon-based electrocatalysts is essential for the deployment of metal-air batteries such as zinc-air batteries (ZABs), among which doping of heteroatoms has attracted tremendous interest over the past decade. However, the effect of the heteroatom covalent bonds in carbon matrix on catalysis was neglected in most studies. Here, an efficient metal-free oxygen reduction reaction (ORR) catalyst is demonstrated by the N-P bonds anchored carbon (termed N,P-C-1000). The N,P-C-1000 catalyst exhibits superior specific surface area of 1362 m2 g−1 and ORR activity with a half-wave potential of 0.83 V, close to that of 20 wt% Pt/C. Theoretical computations reveal that the p-band center for C-2p orbit in N,P-C-1000 has higher interaction strength with the intermediates, thus reducing the overall reaction energy barrier. The N,P-C-1000 assembled primary ZAB can attain a large peak power density of 121.9 mW cm−2 and a steady discharge platform of ∼1.20 V throughout 120 h. Besides, when served as the cathodic catalyst in a solid-state ZAB, the battery shows flexibility, conspicuous open circuit potential (1.423 V), and high peak power density (85.8 mW cm−2). Our findings offer a strategy to tune the intrinsic structure of carbon-based catalysts for improved electrocatalytic performance and shed light on future catalysts design for energy storage technologies beyond batteries. [ABSTRACT FROM AUTHOR]

Published

2024

29. Nearly linear orbital molecules on a pyrochlore lattice.

Author

Krajewska, Aleksandra, Yaresko, Alexander N., Nuss, Jürgen, Bette, Sebastian, Gibbs, Alexandra S., Blankenhorn, Marian, Dinnebier, Robert E., Sari, Dita P., Watanabe, Isao, Bertinshaw, Joel, Gretarsson, Hlynur, Kenji Ishii, Daiju Matsumura, Takuya Tsuji, Masahiko Isobe, Keimer, Bernhard, Hidenori Takagi, and Tomohiro Takayama

Subjects

*SPIN-orbit interactions, *MOLECULAR orbitals, *COVALENT bonds, *LOW temperatures, *HIGH temperatures, *PYROCHLORE

Abstract

The interplay of spin-orbit coupling with other relevant parameters gives rise to the rich phase competition in complex ruthenates featuring octahedrally coordinated Ru4+. While locally, spin-orbit coupling stabilizes a nonmagnetic Jeff = 0 state, intersite interactions resolve one of two distinct phases at low temperatures: an excitonic magnet stabilized by the magnetic exchange of upper-lying Jeff = 1 states or Ru2 molecular orbital dimers driven by direct orbital overlap. Pyrochlore ruthenates A2Ru2O7 (A = rare earth, Y) are candidate excitonic magnets with geometrical frustration. We synthesized In2Ru2O7 with covalent In-O bonds. This pyrochlore ruthenate hosts a local Jeff = 0 state at high temperatures; however, at low temperatures, it forms a unique nonmagnetic ground state with nearly linear Ru-O-Ru molecules, in stark contrast to other A2Ru2O7 compounds. The disproportionation of covalent In-O bonds drives Ru2O molecule formation, quenching not only the local spin-orbit singlet but also geometrical frustration. [ABSTRACT FROM AUTHOR]

Published

2024

30. Mechanochemical Diversity in Block Copolymers.

Author

Zhang, Hang and Diesendruck, Charles E.

Subjects

*COVALENT bonds, *MECHANICAL chemistry, *MOLECULES, *POLYMERS, *PROBABILITY theory

Abstract

Covalent polymer chains are known to undergo mechanochemical events when subjected to mechanical forces. Such force‐coupled reactions, like C−C bond scission in homopolymers, typically occur in a non‐selective manner but with a higher probability at the mid‐chain. In contrast, block copolymers (BCPs), composed of two or more chemically distinct chains linked by covalent bonds, have recently been shown to exhibit significantly different mechanochemical reactivities and selectivities. These differences may be attributable to the atypical conformations adopted by their chains, compared to the regular random coil. Beyond individual molecules, when BCPs self‐assemble into ordered aggregates in solution, the non‐covalent interactions between the chains lead to meaningful acceleration in the activation of embedded force‐sensitive motifs. Furthermore, the microphase segregation of BCPs in bulk creates periodically dispersed polydomains, locking the blocks in specific conformations which have also been shown to affect their mechanochemical reactivity, with different morphologies influencing reactivity to varying extents. This review summarizes the studies of mechanochemistry in BCPs over the past two decades, from the molecular level to assemblies, and up to bulk materials. [ABSTRACT FROM AUTHOR]

Published

2024

31. A Chemoselective Enrichment Strategy for In‐Depth Coverage of the Methyllysine Proteome.

Author

Yan, Lufeng, Zheng, Manqian, Fan, Mingzhu, Yao, Rui, Zou, Kun, Feng, Shan, and Wu, Mingxuan

Subjects

*POST-translational modification, *DIAZONIUM compounds, *RADIOLABELING, *AFFINITY chromatography, *COVALENT bonds

Abstract

Proteomics is a powerful method to comprehensively understand cellular posttranslational modifications (PTMs). Owing to low abundance, tryptic peptides with PTMs are usually enriched for enhanced coverage by liquid chromatography‐mass spectrometry/mass spectrometry (LC–MS/MS). Affinity chromatography for phosphoproteomes by metal‐oxide and pan‐specific antibodies for lysine acetylome allow identification of tens of thousands of modification sites. Lysine methylation is a significant PTM; however, only hundreds of methylation sites were identified by available approaches. Herein we report an aryl diazonium based chemoselective strategy that enables enrichment of monomethyllysine (Kme1) peptides through covalent bonds with extraordinary sensitivity. We identified more than 10000 Kme1 peptides from diverse cell lines and mouse tissues, which implied a wide lysine methylation impact on cellular processes. Furthermore, we found a significant amount of methyl marks that were not S‐adenosyl methionine (SAM)‐dependent by isotope labeling experiments. [ABSTRACT FROM AUTHOR]

Published

2024

32. Progress of Self‐healing Materials based on Hindered Urea Bonds.

Author

Yan, Xixian, He, Xiaogang, Zhao, Chunguang, Zhang, Chi, Li, Ning, Zeng, Fanglei, Zhang, Xiaoyu, and Ding, Jianning

Subjects

*PHOTOTHERMAL effect, *EXCHANGE reactions, *COVALENT bonds, *LOW temperatures, *POLYURETHANES

Abstract

Over the past few decades, polymers with dynamic covalent bonds have received a lot of attention due to their self‐healing, shape memory, and environmental adaptation properties. However, most of them require a change in catalyst or environmental conditions to achieve bond reduction and exchange reactions, and the harsh conditions are not conducive to the practical application of the material. However, the dr‐polyurea based polyurethane (PUU) can be prepared at low temperatures, and can be worn and rebuilt in a catalyst free and mild environment, thus showing excellent self‐healing function. In this paper, the unique dynamic reaction mechanism of hindered urea bond (HUB), the properties of related polymers and the development of frontier are reviewed. In addition, the performance research of HUB and the application prospect of innovative synthetic PUU are also reviewed. [ABSTRACT FROM AUTHOR]

Published

2024

33. Quantum Chemical Molecular Dynamics Simulations for Methane‐Water Cages.

Author

Lanza, Giuseppe

Subjects

*METHANE hydrates, *AB-initio calculations, *MOLECULAR dynamics, *DYNAMIC stability, *COVALENT bonds, *VAN der Waals forces

Abstract

The dynamic stability of various methane‐water clathrate‐like cages (CH4@(H2O)n, n = 16, 18, 20, 22), has been analyzed explicitly considering thermal effects by means of ab initio M06‐2X/6–31+G*/PCM calculations, which make use of Gaussian basis functions. Starting from the equilibrium filled cage structures, classical, dynamic reaction coordinate (DRC) on the Born–Oppenheimer surface, and semiclassical, Born–Oppenheimer plus harmonic zero‐point energy surface (BOMD), molecular dynamics have been carried out. Water molecules have a high tendency to orient covalent O–H bonds tangentially to the hydrophobic surface, thus clathrate‐like arrangements are an acceptable model to fully hydrate methane. If the cage size is such as to minimize core repulsion, due to electron cloud overlap, and to maximize host–guest van der Waals attractions, the clathrate‐like structures have a life‐time of two picoseconds in classical DRC simulations. The inclusion of quantum kinetic energy in BOMD simulations results in less structured cages with a reduced amount of hydrogen bond network. The preferential tangential orientation of the O‐H bonds is largely maintained, although few of them point toward the methane for a very short time in BOMD simulations. The reduced configurational space of water molecules hydrating hydrophobic moiety is highlighted, thus any satisfactory molecular modeling has to account for it. [ABSTRACT FROM AUTHOR]

Published

2024

34. Effect of pH on the surface charges of permanently/variably charged soils and clay minerals.

Author

Cao, Hua, Liu, Xinmin, Feng, Bo, Sun, Jiaqi, Ma, Deyuan, Chen, Xijing, and Li, Hang

Subjects

*CLAY minerals, *CLAY soils, *SURFACE charges, *COVALENT bonds, *PH effect

Abstract

Traditionally, the surface charge number (SCN) of permanently charged soils/clay minerals is believed to be unaffected by environmental pH. However, recent studies have revealed the occurrence of polarization-induced covalent bonding between H+ and the surface O atoms of permanently charged clay minerals. This discovery challenges the traditional notions of "permanently charged soil" and "permanently charged clay mineral". The purpose of this study is to confirm that there are no true "permanently charged clay" or "permanently charged soil". In this study, the SCNs of two permanently charged clay minerals, two variably charged clay minerals, five permanently charged soils (temperate soils), and four variably charged soils (tropical or subtropical soils) were measured at different pH values using the universal determination method of SCN. The results showed that: (1) The SCNs of the permanently/variably charged soils and clay minerals decreased significantly with decreasing pH; (2) the SCN of montmorillonite decreased less with decreasing pH than the SCNs of variably charged minerals, whereas the SCN of illite decreased to nearly the same extent, indicating strong polarization-induced covalent bonding between H+ and the surface O atoms of illite; (3) the SCNs of permanently charged soils decreased to a similar extent as those of variably charged soils with decreasing pH. This study demonstrated that the concepts, "permanently charged clay mineral" or "permanently charged soil", are questionable because of the polarization-induced covalent bonding between H+ and the surface O atoms of clay minerals. [ABSTRACT FROM AUTHOR]

Published

2024

35. Facile Fabrication of Starch‐Based UV Barrier Films with Remolding Ability and Reinforcement for Water Resistance.

Author

Shibasaki, Kazuki, Hsu, Yu‐I, and Uyama, Hiroshi

Subjects

*PACKAGING materials, *COVALENT bonds, *MONOMERS, *PACKAGING film, *STARCH, *BIODEGRADABLE plastics

Abstract

Petroleum‐derived plastics are harmful to ecosystems because they are not decomposed in the natural environment. Therefore, the replacement of petroleum‐derived plastics with biodegradable plastics has attracted considerable attention. UV‐barrier films in the agricultural and packaging fields are mainly composed of petroleum‐derived plastics, which have a negative impact on the ecosystem when they leak into the environment. Thermoplastic starch (TPS) is an inexpensive and sustainable biodegradable plastic that has recently attracted considerable attention. In this study, the addition of UV barrier properties and remolding ability to TPS for replacing petroleum‐derived UV barrier films are investigated. Also, a biodegradable polyester coating is studied to improve the water resistance of the prepared UV‐barrier TPS (U‐TPS). To prepare U‐TPS, a conjugated enamine structure is formed by reacting starch acetoacetate with diamine monomers during melt kneading. U‐TPS exhibits high UV barrier properties across the UV regions (200–400 nm) owing to the presence of acetoacetyl groups and enamines. These results indicate the possibility of increasing the utilization of TPS in agriculture and as a packaging material. [ABSTRACT FROM AUTHOR]

Published

2024

36. Anti-inflammatory effect of covalent PPARγ ligands that have a hybrid structure of GW9662 and a food-derived cinnamic acid derivative.

Author

Miyazawa, Shinano, Sakai, Misa, Omae, Yuma, Ogawa, Yusuke, Shigemori, Hideyuki, and Miyamae, Yusaku

Subjects

*PEROXISOME proliferator-activated receptors, *CINNAMIC acid derivatives, *COVALENT bonds, *INFLAMMATION, *NITRIC oxide

Abstract

Peroxisome proliferator-activated receptor γ (PPARγ) belongs to the nuclear receptor superfamily and is involved in the inflammatory process. Previously, we synthesized the ligands of PPARγ that possess the hybrid structure of a food-derived cinnamic acid derivative (CA) and GW9662, an irreversible PPARγ antagonist. These ligands activate the transcription of PPARγ through the covalent bond formation with the Cys285 residue of PPARγ, whereas their anti-inflammatory effect has not been examined yet. Here, we show the anti-inflammatory effect of the covalent PPARγ ligands in RAW264 cells, murine macrophage-like cells. GW9662 suppressed the production of nitric oxide (NO) stimulated by lipopolysaccharide and exerted a synergistic effect in combination with CA. The compounds bearing their hybrid structure dramatically inhibited NO production and transcription of proinflammatory cytokines. A comparison study suggested that the 2-chloro-5-nitrobenzoyl group of the ligands is important for anti-inflammation. Furthermore, we synthesized an alkyne-tagged analogue that becomes an activity-based probe for future mechanistic study. [ABSTRACT FROM AUTHOR]

Published

2024

37. Engineering extracellular vesicles for diagnosis and therapy.

Author

Fei, Zhengyue, Zheng, Jiamin, Zheng, Xiangxiang, Ren, Hao, and Liu, Guannan

Subjects

*EXTRACELLULAR vesicles, *CLICK chemistry, *COVALENT bonds, *REGENERATIVE medicine, *DIAGNOSIS

Abstract

Bio-orthogonal labeling of vesicles conjugated with fluorescent molecular groups, enables in vivo bioimaging to monitor their behavior, thus aiding in diagnostics or revealing the internalization mechanisms of extracellular vesicles (EVs). Orthogonally based magnetic beads, microfluidics, and microarray chips specifically and in a high-throughput manner isolate EVs derived from various cancers for diagnosis of diseases and cancer development. By loading drugs onto the surface of EVs or forming covalent bonds between EVs and cells through bio-orthogonal methods, the therapeutic efficiency of EVs can be enhanced. Bio-orthogonal glycometabolism enables EVs to directly target tumor cells and their derived EVs in vivo , thereby inhibiting tumor metastasis and growth. Extracellular vesicle (EV)-based therapeutics have gained substantial interest in the areas of drug delivery, immunotherapy, and regenerative medicine. However, the clinical translation of EVs has been slowed due to limited yields and functional heterogeneity, as well as inadequate targeting. Engineering EVs to modify their inherent function and endow them with additional functions has the potential to advance the clinical translation of EV applications. Bio-orthogonal click chemistry is an engineering approach that modifies EVs in a controlled, specific, and targeted way without compromising their intrinsic structure. Here, we provide an overview of bio-orthogonal labeling approaches involved in EV engineering. We also present the isolation methods of bio-orthogonally labeled vesicles using magnetic beads, microfluidics, and microarray chip technologies. We highlight the in vivo applications of bio-orthogonal labeling EVs for diagnosis and therapy, especially the exciting potential of bio-orthogonal glycometabolic engineered EVs for targeted therapies. [ABSTRACT FROM AUTHOR]

Published

2024

38. Creep-Resistant Covalent Adaptable Networks with Excellent Self-Healing and Reprocessing Performance via Phase-Locked Dynamic Covalent Benzopyrazole-Urea Bonds.

Author

Xie, Miao, Wang, Xiao-Rong, Wang, Zhan-Hua, and Xia, He-Sheng

Subjects

*PLASTIC scrap, *SELF-healing materials, *COVALENT bonds, *ADDITION reactions, *PHASE separation, *POLYMER networks

Abstract

Covalent adaptive networks (CANs) are capable of undergoing segment rearrangement after being heated, which endows the materials with excellent self-healing and reprocessing performance, providing an efficient solution to the environment pollution caused by the plastic wastes. The main challenge remains in developing CANs with both excellent reprocessing performance and creep-resistance property. In this study, a series of CANs containing dynamic covalent benzopyrazole-urea bonds were developed based on the addition reaction between benzopyrazole and isocyanate groups. DFT calculation confirmed that relatively low dissociation energy is obtained through undergoing a five-member ring transition state, confirming excellent dynamic property of the benzopyrazole-urea bonds. As verified by the FTIR results, this nice dynamic property can be well maintained after incorporating the benzopyrazole-urea bonds into polymer networks. Excellent self-healing and reprocessing performance is observed by the 3-ABP/PDMS elastomers owing to the dynamic benzopyrazole-urea bonds. Phase separation induced by the aggregation of the hard segments locked the benzopyrazole-urea bonds, which also makes the elastomers display excellent creep-resistance performance. This hard phase locking strategy provides an efficient approach to design CANs materials with both excellent reprocessing and creep-resistance performance. [ABSTRACT FROM AUTHOR]

Published

2024

39. Regulating Actuations and Shapes of Liquid Crystal Elastomers through Combining Dynamic Covalent Bonds with Cooling-Rate-Mediated Control.

Author

Liu, Ya-Wen, Liang, Huan, Xu, Hong-Tu, He, En-Jian, Yang, Zhi-Jun, Wang, Yi-Xuan, Wei, Yen, Li, Zhen, and Ji, Yan

Subjects

*LIQUID crystals, *COVALENT bonds, *MODE shapes, *COPPER plating, *EXCHANGE reactions

Abstract

Realizing multiple locked shapes in pre-oriented liquid crystal elastomers (LCEs) is highly desired for diversifying deformations and enhancing multi-functionality. However, conventional LCEs only deform between two shapes for each actuation cycle upon liquid crystal-isotropic phase transitions induced by external stimuli. Here, we propose to regulate the actuation modes and the locked shapes of a pre-orientated epoxy LCE by combining dynamic covalent bonds with cooling-rate-mediated control. The actuation modes can be adjusted on demand by exchange reactions of dynamic covalent bonds. Derived from the established actuation modes, such as elongation, bending, and spiraling, the epoxy LCE displays varied locked shapes at room temperature under different cooling rates. Various mediums are utilized to control the cooling rate, including water, silicone oil, and copper plates. This approach provides a novel way for regulating the actuation modes and locked shapes of cutting-edge intelligent devices. [ABSTRACT FROM AUTHOR]

Published

2024

40. Dynamic Sulfur-Rich Polymers from Elemental Sulfur and Epoxides.

Author

Chen, Ke-Xiang, Cui, Chen-Hui, Li, Zhen, Xu, Ting, Teng, Hao-Qing, He, Zhi-Yuan, Guo, Yin-Zhou, Ming, Xiao-Qing, Ge, Zhi-Shen, Zhang, Yan-Feng, and Wang, Tie-Jun

Subjects

*INDUSTRIAL wastes, *SULFUR compounds, *COVALENT bonds, *HYDROXYL group, *INDUSTRIAL goods, *POLYSULFIDES

Abstract

Sulfur-containing dynamic polymers had attracted significant attention due to their unique chemical structures with high reversibility. Utilizating sulfur, an inexpensive industrial waste product, to synthesize dynamic polysulfide polymers through reverse vulcanization has been a notable approach. However, this method required high temperatures and resulted in the release of unpleasant oders. In this study, we presented a robust method for the preparation of sulfur-rich polymers with dynamic polysulfide bonds from elemental sulfur and inexpensive epoxide monomers via a one-pot strategy at the mild room temperature. Different types of polysulfide molecules and polymers were synthesized by reacting various epoxide compounds with sulfur, along with the investigation of their structures and dynamic behaviors. It was noteworthy that the obatined polymers prepared from m-(2,3-epoxypropoxy)-N,N-bis(2,3-epoxypropyl)aniline and elemental sulfur exhibit multiple dynamic behaviors, including polysulfide metathesis and polysulfide-thiol exchange, enabling their rapid stress relaxation, self-healing, reprocessing and degradable properties of the cross-linked polymer. More importantly, the hydroxyl groups at the side chains from epoxide ring opening exhibited potential transesterification. This work provided a facile strategy for designing dynamic sulfur-rich polymers via a mild synthesis route. [ABSTRACT FROM AUTHOR]

Published

2024

41. Catalyst-free and Reprocessable Aromatic Polydithiourethanes.

Author

Yang, Bo, Feng, Hai-Jun, Ni, Tian-Tian, Zhou, Xiao-Rui, Xie, Tao, and Zheng, Ning

Subjects

*MECHANICAL behavior of materials, *COVALENT bonds, *POLYMERS, *CATALYSTS

Abstract

The incorporation of dynamic covalent bonds into thermosets facilitates the reprocessing of polymer networks, thereby meeting the sustainable requirements for polymer recycling. However, the mechanical properties of many materials often decline significantly upon reprocessing due to side reactions caused by harsh processing conditions. In this work, we find that the aromatic dithiocarbamate bond can undergo dissociation under mild conditions without the need for a catalyst, enabling the efficient reprocessing of the corresponding polydithiourethane. As a consequence, the mechanical properties of the polydithiourethane can be largely preserved after reprocessing. The discovery of this dynamic chemistry is anticipated to broaden the potential for material design in dynamic covalent polymer networks. [ABSTRACT FROM AUTHOR]

Published

2024

42. Ultra‐Fast Selenol‐Yne Click (SYC) Reaction Enables Poly(selenoacetal) Covalent Adaptable Network Formation.

Author

Zhang, Mengyao, Chen, Sisi, Xu, Guichuan, Lu, Weihong, Li, Jiajia, Zhang, Jiandong, Zhang, Zhengbiao, Zhu, Jian, and Pan, Xiangqiang

Subjects

*CHEMICAL recycling, *WASTE recycling, *COVALENT bonds, *DENSITY functional theory, *SMALL molecules

Abstract

The emergence of covalent adaptable networks (CANs) based on dynamic covalent bonds (DCBs) presents a promising avenue for achieving resource recovery and utilization. In this study, we discovered a dynamic covalent bond called selenacetal, which is obtained through a double click reaction between selenol and activated alkynes. Density functional theory (DFT) calculations demonstrated that the ΔG for the formation of selenoacetals ranges from 12 to 18 kJ mol−1, suggesting its potential for dynamic reversibility. Dynamic exchange experiments involving small molecules and polymers provide substantial evidence supporting the dynamic exchange properties of selenoacetals. By utilizing this highly efficient click reaction, we successfully synthesized dynamic materials based on selenoacetal with remarkable reprocessing capabilities without any catalysts. These materials exhibit chemical recycling under alkaline conditions, wherein selenoacetal (SA) can decompose into active enone selenide (ES) and diselenides. Reintroducing selenol initiates a renewed reaction with the enone selenide, facilitating material recycling and yielding a newly developed dynamic material exhibiting both photo‐ and thermal responsiveness. The results underscore the potential of selenoacetal polymers in terms of recyclability and selective degradation, making them a valuable addition to conventional covalent adaptable networks. [ABSTRACT FROM AUTHOR]

Published

2024

43. Dynamic Covalent Bonds Enabled Carbon Fiber Reinforced Polymers Recyclability and Material Circularity.

Author

Fan, Xiaotong, Zheng, Jie, Yeo, Jayven Chee Chuan, Wang, Sheng, Li, Ke, Muiruri, Joseph Kinyanjui, Hadjichristidis, Nikos, and Li, Zibiao

Subjects

*CARBON fibers, *COVALENT bonds, *BORONIC esters, *MATERIALS science, *WASTE recycling

Abstract

Due to their remarkable features of lightweight, high strength, stiffness, high‐temperature resistance, and corrosion resistance, carbon fiber reinforced polymers (CFRPs) are extensively used in sports equipment, vehicles, aircraft, windmill blades, and other sectors. The urging need to develop a resource‐saving and environmentally responsible society requires the recycling of CFRPs. Traditional CFRPs, on the other hand, are difficult to recycle due to the permanent covalent crosslinking of polymer matrices. The combination of covalent adaptable networks (CANs) with carbon fibers (CFs) marks a new development path for closed‐loop recyclable CFRPs and polymer resins. In this review, we summarize the most recent developments of closed‐loop recyclable CFRPs from the unique paradigm of dynamic crosslinking polymers, CANs. These sophisticated materials with diverse functions, oriented towards CFs recycling and resin sustainability, are further categorized into several active domains of dynamic covalent bonds, including ester bonds, imine bonds, disulfide bonds, boronic ester bonds, and acetal linkages, etc. Finally, the possible strategies for the future design of recyclable CFPRs by combining dynamic covalent chemistry innovation with materials interface science are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

44. Application of supramolecular hydrogel in supercapacitors: Opportunities and challenges.

Author

Xu, Wenshi and Chen, Aibing

Subjects

ENERGY storage, HYDROGEN bonding, SPECIAL functions, COVALENT bonds, POWER density

Abstract

Supercapacitors (SCs) are studied and used in various fields due to their high power density, fast charging/discharging rate, as well as long cycle life. Compared to other traditional electrode and electrolyte materials, supramolecular hydrogels have great advantages in the application of SCs due to their excellent properties. Unlike covalent bonds, supramolecular systems are assembled through dynamic reversible bonds, including host–guest interactions, ion interactions, electrostatic interactions, hydrogen bonding, coordination interactions, etc. The resulting supramolecular hydrogels show some special functions, such as stretching, compression, adhesion, self‐healing, stimulus responsiveness, etc., making them strong candidates for the next generation of energy storage devices. This paper reviews the representative progress of electrodes, electrolytes, and SCs based on supramolecular hydrogels. Besides, the properties of supramolecular hydrogels, such as conductivity, extensibility, compressibility and elasticity, self‐healing, frost resistance, adhesion, and flexibility, are also reviewed to highlight the key role of excellent properties of hydrogel materials in SCs. In addition, this article also discusses the challenges faced by current technologies, hoping to continue promoting future research in this field. [ABSTRACT FROM AUTHOR]

Published

2024

45. Ultrahigh‐Ni Cathode with Superior Structure Stability Enabled by a Covalent Bonding Strategy.

Author

Li, Caihu, Zhang, Xudong, Cui, Yichao, Xu, Yanan, Zhang, Xiong, Sun, Xianzhong, Wang, Kai, and Ma, Yanwei

Subjects

STRUCTURAL stability, COVALENT bonds, CATHODES, SINTERING, POWDERS

Abstract

Ultrahigh‐nickel layered oxide cathodes are the most promising cathode materials for high‐energy lithium‐ion batteries. However, the rapid structural degradation during cycling charge‐discharge process limits its commercial application. Herein, we report a covalent pinning strategy to enhance structure stability of ultrahigh‐Ni cathode LiNi0.9Co0.06Mn0.04O2 (NCM90). Zr is gradient diffused into the lattice of NCM90 and forms Zr−O bonds during the sintering process, which can effectively alleviate the lattice distortion like introducing pinning centers due to the stronger bond energy, enhancing its structure stability during charge‐discharge process. In the meanwhile, the Zr−O on the surface of NCM90 powder forms LixZryOz coating layer due to the reaction with lithium residue, which prevents from the edge reconstruction and mitigates the occurrence of side reactions, as well as ensuring a fast Li+ diffusion pathway crossing the interface. As a result, the Zr−O modified NCM90 (Zr‐NCM) achieves 88.8 % remarkable capacity retention at 1 C after 200 cycles over 2.8–4.3 V, which is superior to the pristine NCM90 with 71.2 % retention. This work demonstrates that the Zr−O bonding can provide an effective structure pinning for the ultrahigh‐Ni cathode, which will largely guide the development of high‐performance lithium‐ion battery cathode materials. [ABSTRACT FROM AUTHOR]

Published

2024

46. Catalyst-Free and Sustainable Bio-Based Epoxy Vitrimer Prepared Based on Ester Exchange and Imine Bonding.

Author

Zhao, Yanna, Zhang, Yingying, Bai, Xiaowei, Wang, Yuqi, Hou, Wentong, and Huang, Yuqing

Subjects

GLYCERYL ethers, FREE groups, HYDROXYL group, FOREIGN exchange rates, COVALENT bonds, GLYCOLS

Abstract

Conventional epoxy anhydride curing systems typically require large amounts of catalyst to ensure a high ester exchange rate, and the resulting cured epoxy vitrimer has renewable and self-repairing properties, but is limited by the amount of catalyst loading. In this study, a diol (VT) containing imine bonds was synthesized from vanillin (VAN) and tyramine (TA) to catalyze the epoxy-anhydride curing process, and glycerol triglycidyl ether (GTE) was co-cured with VT and methylhexahydrophthalic anhydride (MHHPA), which constructed a bio-based regenerative and repairable epoxy vitrimer with dual dynamic covalent bonds (GMV), the free hydroxyl groups in the crosslinked network could rapidly promote the ester exchange rate. The thermal, mechanical, solvent resistance, self-repairing, renewable and shape memory properties of GMV were systematically investigated by adjusting the ratio of anhydride and hydroxyl groups. It exhibits a better thermal stability property Td5% (281.27℃) and a shorter relaxation time τ (12.15 s) at 140 °C. In addition, the scratches of GMV could be almost completely healed at 120 °C for 60 min, and this test demonstrated that GMV has better self-healing and renewable tests. The present work promotes the epoxy vitrimer species and expands the esterification scheme performed without catalyst. [ABSTRACT FROM AUTHOR]

Published

2024

47. KCl supported by γ‐Al2O3 for selective adsorption of gaseous oxidized mercury: Preparation and adsorption mechanism.

Author

Tong, Jiangyi, Li, Haiyang, Jin, Rui, Liu, Xiaoshuo, Hu, Haitao, Duan, Yufeng, Ma, Xiuyuan, Zhong, Li, and Han, Lipeng

Subjects

*VAN der Waals forces, *COVALENT bonds, *TRANSMISSION electron microscopy, *DENSITY functional theory, *CHARGE exchange

Abstract

The separation of Hg0 and HgCl2 with selective adsorbents is crucial for mercury speciation detection. KCl is commonly used but has a limited surface area, a short lifespan, and an unclear mechanism for Hg0/HgCl2 adsorption. Hence, KCl supported by γ‐Al2O3 to create a high‐surface‐area selective adsorbent to enhance practical performance was proposed and the selective adsorption mechanisms of Hg0 and HgCl2 through experimental investigations and density functional theory (DFT) calculations were elucidated. Compared to the total breakthrough of pure KCl, that of KCl/γ‐Al2O3 exhibits markedly selective adsorption efficacy on HgCl2, with a nearly complete breakthrough rate on Hg0 at a KCl‐to‐γ‐Al2O3 molar ratio of 1, attributed to their favorable porosity and dispersed active sites. The DFT results verify a weak van der Waals force between KCl and Hg0, indicating physisorption, while covalent bonding occurs between KCl and HgCl2, suggesting chemisorption. High‐resolution transmission electron microscopy (HRTEM) identifies two crystalline surfaces of 001 and 011 on the developed adsorbent. This clarifies three stable adsorption configurations: 001 Top‐Cl, 011 Top‐Cl, and 011 Cl–Cl bridge, with adsorption energies of −87.11, −110.74, and −174.91 kJ/mol, respectively. Analyses of the electronic structure and interaction region indicator (IRI) reveal that the Hg atom within HgCl2 forms covalent bonds with unsaturated Cl atoms on the KCl surface. Additionally, integrated crystal orbital Hamilton population (ICOHP) analysis and electron transfer results demonstrate that the interaction strength of the three configurations with HgCl2 follows the order of 011 Cl–Cl bridge > 011 Top‐Cl > 001 Top‐Cl. This matches the three different temperature peaks of 276, 231, and 120°C, respectively, in the analysis of the temperature‐programmed desorption of HgCl2 (HgCl2‐TPD). This study offers a novel insight on mercury speciation partitioning between Hg0 and HgCl2. [ABSTRACT FROM AUTHOR]

Published

2024

48. The effect of Cu doping on the piezoelectric properties of ZnO systems: First-principles calculations.

Author

Liu, Lin, Yu, Wentao, Zhao, Yujie, Zhu, Wensheng, Li, Jing, Wu, Lingkang, and Wang, Hao

Subjects

*COPPER, *ZINC oxide thin films, *IONIC bonds, *ZINC oxide, *LATTICE constants, *LEAD zirconate titanate, *COVALENT bonds

Abstract

First-principles calculations are performed, revealing a significant enhancement of the piezoelectric properties of wurtzite Zn 3 6 O 3 6 upon the incorporation of a single Cu atom. Research has demonstrated that the piezoelectric constant d 3 3 reaches its maximum value at a doping concentration of 1.4% for Cu atoms. The lattice parameters a and c of Zn 3 6 O 3 6 are decreased and the piezoelectric strain coefficient d 3 3 is increased by replacing one Cu atom in Zn 3 6 O 3 6 . It is found that elastic softening is the primary factor responsible for the increase of d 3 3 in Zn 3 5 Cu1O 3 6 . By differential charge density analysis, it is found that the covalency between Cu–O bonds is lower than that of Zn–O bonds, and the covalent bonding characteristics are weakened. Bader charge analysis shows that the charge of Cu is higher than that of Zn, indicating a more significant ionic bonding feature than that of Zn. Thus, a weaker covalent and stronger ionic bond are considered to play an essential role in promoting elastic softening for ZnO, which eventually promotes a significant enhancement in piezoelectric properties. [ABSTRACT FROM AUTHOR]

Published

2024

49. Molecular Necklaces Formed Through Zn2+‐Templated Binding of Macrocycles with Dynamically Formed Imines as Guest Recognition Sites.

Author

Wu, Yi‐Ju, Liu, Yi‐Hung, and Chiu, Sheng‐Hsien

Subjects

*ALDEHYDE derivatives, *COVALENT bonds, *AMINE derivatives, *CHEMICAL bonds, *CATENANES

Abstract

Herein we demonstrate an "in‐ring establishing" strategy for assembling interlocked molecules through dynamic imine formation, "establishing" the host recognition sites in situ. Using Zn2+ ions to template the assembly of a pyridine‐containing macrocycle with semidumbbell‐shaped triazole‐containing aldehyde and amine derivatives, we obtained the corresponding [2]rotaxane in high yield (85 %) after subsequent imine reduction (NaBH4) and amine protonation (NH4PF6). We performed the same three steps (assembly, reduction, protonation) to prepare a stable and highly symmetrical [5]molecular necklace ([5]MN) from 12 components (two almost‐90°‐oriented dialdehydes, two almost‐90°‐oriented diamines, four macrocycles, four Zn2+ ions) in an overall yield of 69 %. [ABSTRACT FROM AUTHOR]

Published

2024

50. Stabilizing NiS2 on Conductive Component via Electrostatic Self‐assembly and Covalent Bond Strategy for Promoting Sodium Storage.

Author

Luo, Siman, Shang, Jian, Xu, Yi'nan, Cheng, Hao, Zhang, Luojiang, and Tang, Yongbing

Subjects

*CHEMICAL kinetics, *LAYERED double hydroxides, *COVALENT bonds, *METAL sulfides, *GRAPHENE oxide, *POLYSULFIDES, *ELECTRIC batteries, *LITHIUM sulfur batteries

Abstract

The high theoretical capacities and excellent redox activities motivate transitional metal sulfides (TMSs) to serve as promising anode materials for sodium‐ion batteries. However, TMSs would experience low electronic conductivity as well as notorious polysulfides dissolution and shuttle effect during charge/discharge processes, which leads to unsatisfactory rate capability and cycling stability. Herein, TMSs‐based anode materials with NiS2 nanoparticles tightly anchoring on nitrogen‐doped graphene (NiS2/NG) via the Ni–N covalent bond have been developed through an electrostatic self‐assembly approach between exfoliated positively charged layered double hydroxide and negatively charged graphene oxide nanosheets, followed by a sulfidation process. The strong coupling between conductive and active components enables NiS2/NG to possess good structural integrity, high ion/electron conductivity, and strong polysulfides adsorption capability, ensuring fast reaction kinetics and energetically stable performance. In consequence, the NiS2/NG delivers a high capacity of 664 mAh g−1 at 0.1 A g−1, good rate performance of 545 mAh g−1 at 2 A g−1, and excellent cycling stability with a retained capacity of 589.9 mAh g−1 after 1200 cycles at 0.5 A g−1, among the best results of reported TMSs‐based anodes. The study provides an effective strategy to design heterostructured materials with strong coupling interaction for high‐efficient‐stable sodium storage. [ABSTRACT FROM AUTHOR]

Published

2024