Wang Hong-bin scite author profile

Wang Hong-bin

42Publications

311Citation Statements Received

628Citation Statements Given

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Hebei Normal University, Jilin University, Shanghai University

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Host–Endosymbiont Genome Integration in a Deep-Sea Chemosymbiotic Clam

Sun

et al. 2020

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Endosymbiosis with chemosynthetic bacteria has enabled many deep-sea invertebrates to thrive at hydrothermal vents and cold seeps, but most previous studies on this mutualism have focused on the bacteria only. Vesicomyid clams dominate global deep-sea chemosynthesis-based ecosystems. They differ from most deep-sea symbiotic animals in passing their symbionts from parent to offspring, enabling intricate co-evolution between the host and the symbiont. Here, we sequenced the genomes of the clam Archivesica marissinica (Bivalvia: Vesicomyidae) and its bacterial symbiont to understand the genomic/metabolic integration behind this symbiosis. At 1.52 gigabases, the clam genome encodes 28 genes horizontally transferred from bacteria, a large number of pseudogenes and transposable elements whose massive expansion corresponded to the timing of the rise and subsequent divergence of symbiont-bearing vesicomyids. The genome exhibits gene family expansion in cellular processes that likely facilitate chemoautotrophy, including gas delivery to support energy and carbon production, metabolite exchange with the symbiont, and regulation of the bacteriocyte population. Contraction in cellulase genes is likely adaptive to the shift from phytoplankton-derived to bacteria-based food. It also shows contraction in bacterial recognition gene familie, indicative of suppressed immune response to the endosymbiont. The gammaproteobacterium endosymbiont has a reduced genome of 1.03 megabases but retains complete pathways for sulfur oxidation, carbon fixation, and biosynthesis of 20 common amino acids, indicating the host’s high dependence on the symbiont for nutrition. Overall, the host-symbiont genomes show not only tight metabolic complementarity, but also distinct signatures of co-evolution allowing the vesicomyids to thrive in chemosynthesis-based ecosystems.

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In-situ self-polymerization restriction to form core-shell LiFePO4/C nanocomposite with ultrafast rate capability for high-power Li-ion batteries

et al. 2017

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Design and synthesis of high performance LiFePO₄/C nanomaterials for lithium ion batteries assisted by a facile H⁺/Li⁺ion exchange reaction

et al. 2015

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Self‐Assembly of Antisite Defectless nano‐LiFePO₄@C/Reduced Graphene Oxide Microspheres for High‐Performance Lithium‐Ion Batteries

et al. 2018

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LiFePO @C/reduced graphene oxide (rGO) hierarchical microspheres with superior electrochemical activity and a high tap density were first synthesized by using a Fe -based single inorganic precursor (LiFePO OH@RF/GO; RF=resorcinol-formaldehyde, GO=graphene oxide) obtained from a template-free self-assembly synthesis followed by direct calcination. The synthetic process requires no physical mixing step. The phase transformation pathway from tavorite LiFePO OH to olivine LiFePO upon calcination was determined by means of the in situ high-temperature XRD technique. Benefitting from the unique structure of the material, these microspheres can be densely packed together, giving a high tap density of 1.3 g cm , and simultaneously, defectless LiFePO primary nanocrystals modified with a highly conductive surface carbon layer and ultrathin rGO provide good electronic and ionic kinetics for fast electron/Li ion transport.

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Synthesis Mechanism of an Environment-Friendly Sodium Lignosulfonate/Chitosan Medium-Density Fiberboard Adhesive and Response of Bonding Performance to Synthesis Mechanism

Guo

Zhu

et al. 2020

Materials

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Environment-friendly medium-density fiberboards (MDFs) prepared using sodium lignosulfonate/chitosan adhesives (L/C) show potential in environment-friendly wood-based panel application. However, the synthesis mechanism of this adhesive and the relationships between synthesis mechanism and bonding performance were not discussed in depth. Herein, the synthesis mechanism of L/C was explored in detail based on characterizations of L/C with different mass ratios of sodium lignosulfonate to chitosan by Fourier-transform infrared spectroscopy, thermogravimetric analysis, and X-ray diffraction. For L/C with different mass ratios of sodium lignosulfonate to chitosan, the corresponding bonding performance was also determined based on characterizations of mechanical and dimensional performance of MDFs. Results showed a 3D network structure of L/C formed through the hydrogen linkages among hydroxyl groups in sodium lignosulfonate and hydroxyl and amino groups in chitosan, amide linkages resulted from reaction between carbonyl groups in sodium lignosulfonate and amino groups in chitosan, and sulfonamide linkages originated from reaction between sulfonic groups in sodium lignosulfonate and amino groups in chitosan. The mechanical performance of MDF was closely related to the 3D network and amino groups of L/C, while the dimensional performance of MDF was negatively affected by sodium lignosulfonate. The MDFs with 1:3 and 1:2 mass ratios of sodium lignosulfonate to chitosan showed superior mechanical properties and comparable dimensional performance with a commercial panel.

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Tuning extreme learning machine by an improved artificial bee colony to model and optimize the boiler efficiency

Niu

et al. 2014

Knowledge-Based Systems

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Assembling porous carbon-coated TiO2(B)/anatase nanosheets on reduced graphene oxide for high performance lithium-ion batteries

Jiang

Wang

Pang

et al. 2015

Electrochimica Acta

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Asgard archaea in the haima cold seep: Spatial distribution and genomic insights

Gao

et al. 2021

Deep Sea Research Part I: Oceanographic Research Papers

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Wang Hong-bin

Host–Endosymbiont Genome Integration in a Deep-Sea Chemosymbiotic Clam

In-situ self-polymerization restriction to form core-shell LiFePO4/C nanocomposite with ultrafast rate capability for high-power Li-ion batteries

Design and synthesis of high performance LiFePO₄/C nanomaterials for lithium ion batteries assisted by a facile H⁺/Li⁺ion exchange reaction

Self‐Assembly of Antisite Defectless nano‐LiFePO₄@C/Reduced Graphene Oxide Microspheres for High‐Performance Lithium‐Ion Batteries

Synthesis Mechanism of an Environment-Friendly Sodium Lignosulfonate/Chitosan Medium-Density Fiberboard Adhesive and Response of Bonding Performance to Synthesis Mechanism

Tuning extreme learning machine by an improved artificial bee colony to model and optimize the boiler efficiency

Assembling porous carbon-coated TiO2(B)/anatase nanosheets on reduced graphene oxide for high performance lithium-ion batteries

Asgard archaea in the haima cold seep: Spatial distribution and genomic insights

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Wang Hong-bin

Host–Endosymbiont Genome Integration in a Deep-Sea Chemosymbiotic Clam

In-situ self-polymerization restriction to form core-shell LiFePO4/C nanocomposite with ultrafast rate capability for high-power Li-ion batteries

Design and synthesis of high performance LiFePO4/C nanomaterials for lithium ion batteries assisted by a facile H+/Li+ion exchange reaction

Self‐Assembly of Antisite Defectless nano‐LiFePO4@C/Reduced Graphene Oxide Microspheres for High‐Performance Lithium‐Ion Batteries

Synthesis Mechanism of an Environment-Friendly Sodium Lignosulfonate/Chitosan Medium-Density Fiberboard Adhesive and Response of Bonding Performance to Synthesis Mechanism

Tuning extreme learning machine by an improved artificial bee colony to model and optimize the boiler efficiency

Assembling porous carbon-coated TiO2(B)/anatase nanosheets on reduced graphene oxide for high performance lithium-ion batteries

Asgard archaea in the haima cold seep: Spatial distribution and genomic insights

Contact Info

Product

Resources

About

Design and synthesis of high performance LiFePO₄/C nanomaterials for lithium ion batteries assisted by a facile H⁺/Li⁺ion exchange reaction

Self‐Assembly of Antisite Defectless nano‐LiFePO₄@C/Reduced Graphene Oxide Microspheres for High‐Performance Lithium‐Ion Batteries