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Gas adsorption in Mg-porphyrin-based porous organic frameworks: A computational simulation by first-principles derived force field.Theoretical simulation of CO2 capture in organic cage impregnated with polyoxometalates.Modeling the selectivity of indoor pollution gases over N2 on covalent organic frameworks.Multiscale simulation of pollution gases adsorption in porous organic cage CC3.Theoretical design and simulation of supramolecular polymer unit based on multiple hydrogen bonds.A Nano-Sized [MnII18] Metallamacrocycle Serving as Unprecedented Building Unit to Construct Stable Metal-Organic Framework: Effective Gas Adsorption and Magnetic PropertyMechanistic insight on water and substrate catalyzed the synthesis of 3-(1H-indol-3-yl)-2-(4-methoxybenzyl)isoindolin-1-one: Driving by noncovalent interactionsFrom molecules to materials: computational design of N-containing porous aromatic frameworks for CO2 captureSelective chiral symmetry breaking and luminescence sensing of a Zn(ii) metal-organic frameworkThe Origin of the Reproduction of Different Nitrogen Uptakes in Covalent Organic Frameworks (COFs)Tetranuclear cobalt(ii)-isonicotinic acid frameworks: selective CO2 capture, magnetic properties, and derived "Co3O4" exhibiting high performance in lithium ion batteriesAnionic Lanthanide Metal-Organic Frameworks: Selective Separation of Cationic Dyes, Solvatochromic Behavior, and Luminescent Sensing of Co(II) IonMechanistic insights into N-Bromosuccinimide-promoted synthesis of imidazo[1,2-a]pyridine in water: Reactivity mediated by substrates and solventTailoring Coral-Like Fe7Se8@C for Superior Low-Temperature Li/Na-Ion Half/Full Batteries: Synthesis, Structure, and DFT StudiesInvestigation of two-dimensional hf-based MXenes as the anode materials for li/na-ion batteries: A DFT studyTheoretical Investigation of the Topology of Spiroborate-Linked Ionic Covalent Organic Frameworks (ICOFs)
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Q38719862-3A745119-0386-47DD-A9E3-B94175A83C5FQ48048157-BEE610D0-24F5-425B-AB4A-250763EB23A7Q48852007-E280E7D8-5CA7-42FD-8085-2B79C7CBD340Q48913932-C2CD1434-7826-429F-ABF5-A3F1DF08BA26Q50447426-5E519AE9-DF9E-45B9-9D91-DE12CEFFB937Q57035333-68A5E680-1F7C-4498-8E68-375D753A2360Q57037871-59AAADA8-B470-466C-AB72-E23B1C6F790EQ88131290-99EC4D24-8C91-4901-A409-E17E4C40675FQ88888630-F24CEA3D-895A-47A1-B4D0-E92C6573B85FQ90266610-A7046565-0D28-4B32-BF93-93C80D3CD6F5Q90268971-25745DD7-28A7-4D5F-B49F-72590005F599Q91218394-37490FF8-DDF1-43F5-A731-E3140192EE54Q91608470-94DC698D-17A1-45CE-8B80-C589FA4F854AQ91664189-ED73811E-27C7-4766-8182-A0EE6C271757Q91676456-EAFA8461-7636-4737-85D4-3962C2308D9AQ92518101-FAAAA705-F249-4A99-BA49-4C16823DE5BB
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description
researcher (ORCID 0000-0002-0864-0358)
@en
name
Wenliang Li
@en
type
label
Wenliang Li
@en
prefLabel
Wenliang Li
@en
P31
P496
0000-0002-0864-0358