High-performance lithium metal batteries benefit from the construction of composite polymer electrolytes(CPEs)which are synthesized by incorporating inorganic fillers into polymer matrices[1].However,the random distri...High-performance lithium metal batteries benefit from the construction of composite polymer electrolytes(CPEs)which are synthesized by incorporating inorganic fillers into polymer matrices[1].However,the random distribution of added fillers within the polymer matrix can lead to tortuous ion pathways and longer transmission distances(Fig.1).As a result,the ion transport capability of CPEs may decrease,while interface contact may deteriorate.Therefore,the organized arrangement of fillers emerges as a crucial consideration in constructing electrolyte membranes.One highly effective approach is the adoption of a vertically aligned filler configuration,where ceramic fillers are constructed to be perpendicular to the electrolyte membrane.If so,the filler/electrolyte interface impedance can be significantly reduced,while continuous ion transport channels along the specified direction are formed,thus significantly enhancing the ion conduction(Fig.1(a))[1].展开更多
As a powerful synthetic tool,ruthenium-catalyzed ring-opening metathesis polymerization(ROMP)has been widely utilized to prepare diverse heteroatom-containing polymers.In this contribution,we report the synthesis of t...As a powerful synthetic tool,ruthenium-catalyzed ring-opening metathesis polymerization(ROMP)has been widely utilized to prepare diverse heteroatom-containing polymers.In this contribution,we report the synthesis of the novel imine-based polymer through the copolymerization of cyclooctene with cyclic imine comonomer via ROMP.Because of the efficient hydrolysis reactions of the imine group,the generated copolymer can be easily degraded under mild condition.Moreover,the generated degradable product was the telechelic polymer bearing amine group,which was highly challenged for its direct synthesis.And this telechelic polymer could also be used for the further synthesis of new polymer through post-transformation.The introduction of imine unit in this work provides a new example of the degradable polymer synthesis.展开更多
Aims and Scope,Chinese Journal of Polymer Science(CJPS)is a monthly journal published in Englishand sponsored by the Chinese Chemical Society and the Institute of Chemistry,,Chinese Academy of Sciences.CJPS isedited b...Aims and Scope,Chinese Journal of Polymer Science(CJPS)is a monthly journal published in Englishand sponsored by the Chinese Chemical Society and the Institute of Chemistry,,Chinese Academy of Sciences.CJPS isedited by a distinguished Editorial Board headed by Professor Qi-Feng Zhouand supported by an International Advisory Board in which many famous active polymerscientists alloverthe world are included.The journal was first published in 1983 under the title Polymer Communications and has the current name since 1985.展开更多
Chain-growth radical polymerization of vinyl monomers is essential for producing a wide range of materials with properties tailored to specific applications.However,the inherent resistance of the polymer's C―C ba...Chain-growth radical polymerization of vinyl monomers is essential for producing a wide range of materials with properties tailored to specific applications.However,the inherent resistance of the polymer's C―C backbone to degradation raises significant concerns regarding long-term environmental persistence,which also limits their potential in biomedical applications.To address these challenges,researchers have developed strategies to either degrade preexisting vinyl polymers or incorporate cleavable units into the backbone to modify them with enhanced degradability.This review explores the various approaches aimed at achieving backbone degradability in chain-growth radical polymerization of vinyl monomers,while also highlighting future research directions for the development of application-driven degradable vinyl polymers.展开更多
Incorporation of acetal groups in the backbone is a potent strategy to create polymers that are cleavable or degradable under acidic conditions.We report here an in-depth study on the ring-closing-opening copolymeriza...Incorporation of acetal groups in the backbone is a potent strategy to create polymers that are cleavable or degradable under acidic conditions.We report here an in-depth study on the ring-closing-opening copolymerization of o-phthalaldehyde(OPA)and epoxide using Lewis pair type two-component organocatalysts for producing acetal-functionalized polyether and polyurethane.Notably,triethylborane as the Lewis acid,in comparison with tri(n-butyl)borane,more effectively enhances the polymerization activity by mitigating borane-induced reduction of the aldehyde group into extra initiating(borinic ester)species.Density functional theory(DFT)calculations present comparable energy barriers of OPA-epoxide cross-propagation and epoxide self-propagation,which is consistent with the experimental finding that an alternating-rich copolymer comprising mostly OPA-epoxide units but also epoxide-epoxide linkages is produced.In particular,when epoxide is added in a large excess,the product becomes a polyether containing acetal functionalities in the central part of the backbone and thus being convertible into polyurethane with refined acid degradability.展开更多
Functional hyperbranched polymers,as an important class of materials,are widely applied in diverse areas.Therefore,the development of simple and efficient reactions to prepare hyperbranched polymers is of great signif...Functional hyperbranched polymers,as an important class of materials,are widely applied in diverse areas.Therefore,the development of simple and efficient reactions to prepare hyperbranched polymers is of great significance.In this work,trialdehydes,diamines,and trimethylsilyl cyanide could easily undergo multicomponent polymerization under mild conditions,producing hyperbranched poly(α-aminonitrile)s with high molecular weights(M_(w) up to 4.87×10^(4))in good yields(up to 85%).The hyperbranched poly(α-aminonitrile)s have good solubility in commonly used organic solvents,high thermal stability as well as morphological stability.Furthermore,due to the numerous aldehyde groups in their branched chains,these hb-poly(α-aminonitrile)s can undergo one-pot,two-step,four-component post-polymerization with high efficiency.This work not only confirms the efficiency of our established catalyst-free multicomponent polymerization of aldehydes,amines and trimethylsilyl cyanide,but also provides a versatile and powerful platform for the preparation of functional hyperbranched polymeric materials.展开更多
Solid polymer electrolytes(SPEs)have garnered considerable interest in the field of lithium metal batteries(LMBs)owing to their exceptional mechanical strength,excellent designability,and heightened safety characteris...Solid polymer electrolytes(SPEs)have garnered considerable interest in the field of lithium metal batteries(LMBs)owing to their exceptional mechanical strength,excellent designability,and heightened safety characteristics.However,their inherently low ion transport efficiency poses a major challenge for their application in LMBs.To address this issue,covalent organic framework(COF)with their ordered ion transport channels,chemical stability,large specific surface area,and designable multifunctional sites has shown promising potential to enhance lithium-ion conduction.Here,we prepared an anionic COF,Tp Pa-COOLi,which can catalyze the ring-opening copolymerization of cyclic lactone monomers for the in situ fabrication of SPEs.The design leverages the high specific surface area of COF to facilitate the absorption of polymerization precursor and catalyze the polymerization within the pores,forming additional COF-polymer junctions that enhance ion transport pathways.The partial exfoliation of COF achieved through these junctions improved its dispersion within the polymer matrix,preserving ion transport channels and facilitating ion transport across COF grain boundaries.By controlling variables to alter the crystallinity of Tp Pa-COOLi and the presence of-COOLi substituents,Tp Pa-COOLi with partial long-range order and-COOLi substituents exhibited superior electrochemical performance.This research demonstrates the potential in constructing high-performance SPEs for LMBs.展开更多
The recent commercialization of gene products has sparked significant interest in gene therapy,necessitating efficient and precise gene delivery via various vectors.Currently,viral vectors and lipid-based nanocarriers...The recent commercialization of gene products has sparked significant interest in gene therapy,necessitating efficient and precise gene delivery via various vectors.Currently,viral vectors and lipid-based nanocarriers are the predominant choices and have been extensively investigated and reviewed.Beyond these vectors,polymeric nanocarriers also hold the promise in therapeutic gene delivery owing to their versatile functionalities,such as improving the stability,cellar uptake and endosomal escape of nucleic acid drugs,along with precise delivery to targeted tissues.This review presents a brief overview of the status quo of the emerging polymeric nanocarriers for therapeutic gene delivery,focusing on key cationic polymers,nanocarrier types,and preparation methods.It also highlights targeted diseases,strategies to improve delivery efficiency,and potential future directions in this research area.The review is hoped to inspire the development,optimization,and clinical translation of highly efficient polymeric nanocarriers for therapeutic gene delivery.展开更多
To achieve the target of carbon neutrality,it is crucial to develop an efficient and green synthesis methodology with good atomic economy to achieve sufficient utilization of energy and sustainable development.Photoin...To achieve the target of carbon neutrality,it is crucial to develop an efficient and green synthesis methodology with good atomic economy to achieve sufficient utilization of energy and sustainable development.Photoinduced electron transfer reversible addition-fragmentation chain-transfer(PET-RAFT)polymerization is a precise methodology for constructing polymers with well-defined structures.However,conventional semiconductor-mediated PET-RAFT polymerization still has considerable limitations in terms of efficiency as well as the polymerization environment.Herein,sulfur-doped carbonized polymer dots(CPDs)were hydrothermally synthesized for catalysis of aqueous PET-RAFT polymerization at unprecedented efficiency with a highest propagation rate of 5.05 h-1.The resulting polymers have well-controlled molecular weight and narrow molecular weight dispersion(Ð<1.10).Based on the optoelectronic characterizations,we obtained insights into the photoinduced electron transfer process and proposed the mechanism for CPD-mediated PET-RAFT polymerization.In addition,as-synthesized CPDs for PET-RAFT polymerization were also demonstrated to be suitable for a wide range of light sources(blue/green/solar irradiation),numerous monomers,low catalyst loading(low as 0.01 mg mL^(-1)),and multiple polar solvent environments,all of which allowed to achieve efficiencies much higher than those of existing semiconductor-mediated methods.Finally,the CPDs were confirmed to be non-cytotoxic and catalyzed PET-RAFT polymerization successfully in cell culture media,indicating broad prospects in biomedical fields.展开更多
In this work,by combining the specific selectivity of molecularly imprinted polymer(MIP)with a simple and sensitive electrochemiluminescence(ECL)detection method,a molecularly imprinted ECL sensor for kanamycin(KA)was...In this work,by combining the specific selectivity of molecularly imprinted polymer(MIP)with a simple and sensitive electrochemiluminescence(ECL)detection method,a molecularly imprinted ECL sensor for kanamycin(KA)was developed.The MIP film was synthesized on the surface of gold electrode via electrochemical polymerization,using pyrrole(PY)as the functional monomer and KA as the template molecule.The commonly used luminescent reagent Ru(bpy)32+was employed as the ECL probe,and its co-reagent tripropylamine(TPA)was added to enhance the detection sensitivity of the sensor.Quantitative analysis of KA was performed by evaluating the difference in ECL responses between MIP film electrodes after KA removal and KA rebinding.The sensor exhibited high selectivity,good reproducibility,and stability toward KA,with a linear range of 5.00×10^(-8) to 1.00×10^(-5) mol·L^(-1) and a limit of detection of 1.67×10^(-8) mol·L^(-1)(S/N=3).This work would provide a new idea for the development of simple and sensitive molecularly imprinted ECL sensors.展开更多
Building and construction sector, including infrastructures, are facing many challenges which are scarcity of raw materials, CO2 emissions, lower construction efficiency, and deterioration under corrosive environment ...Building and construction sector, including infrastructures, are facing many challenges which are scarcity of raw materials, CO2 emissions, lower construction efficiency, and deterioration under corrosive environment that cost the world economy $2.5 trillion and this translates to 3.4% of world gross domestic product. This paper presents several examples that show how the use of the nonmetallic materials improved sustainability and life cycles in the built environment by removing the corrosion issue from its root and using durable NM polymers in construction. The paper details recently patented Aramco technology for the use of nonmetallic paving panels that could be used as an alternative to concrete and asphalt paving. Other case studies presented cover use of GFRP Poles for traffic signs and signal poles to replace traditional steel poles. Details of developments for specialist structural application in bridges, in architectural applications, polymers in soils, fibers in pavement manholes and bendable concrete are presented.展开更多
Driven by the dual imperatives of global plastic pollution control and carbon neutrality,research on depolymerizable polymers has become a cutting-edge focus in polymer science.With the continuous emergence of innovat...Driven by the dual imperatives of global plastic pollution control and carbon neutrality,research on depolymerizable polymers has become a cutting-edge focus in polymer science.With the continuous emergence of innovative materials,strengthened policy support,and maturing industrial chains,these polymers are demonstrating transformative potential in critical sectors,such as environmental protection,healthcare,and industrial manufacturing,promising for reshaping the future landscape of the plastics industry.展开更多
Advancing the integration of artificial intelligence and polymer science requires high-quality,open-source,and large-scale datasets.However,existing polymer databases often suffer from data sparsity,lack of polymer-pr...Advancing the integration of artificial intelligence and polymer science requires high-quality,open-source,and large-scale datasets.However,existing polymer databases often suffer from data sparsity,lack of polymer-property labels,and limited accessibility,hindering system-atic modeling across property prediction tasks.Here,we present OpenPoly,a curated experimental polymer database derived from extensive lit-erature mining and manual validation,comprising 3985 unique polymer-property data points spanning 26 key properties.We further develop a multi-task benchmarking framework that evaluates property prediction using four encoding methods and eight representative models.Our re-sults highlight that the optimized degree-of-polymerization encoding coupled with Morgan fingerprints achieves an optimal trade-off between computational cost and accuracy.In data-scarce condition,XGBoost outperforms deep learning models on key properties such as dielectric con-stant,glass transition temperature,melting point,and mechanical strength,achieving R2 scores of 0.65-0.87.To further showcase the practical utility of the database,we propose potential polymers for two energy-relevant applications:high temperature polymer dielectrics and fuel cell membranes.By offering a consistent and accessible benchmark and database,OpenPoly paves the way for more accurate polymer-property modeling and fosters data-driven advances in polymer genome engineering.展开更多
Compared to subtractive manufacturing and casting,3D printing(additive manufacturing)offers advantages,such as the rapid production of complex structures,reduced material waste,and environmental friendliness.Direct in...Compared to subtractive manufacturing and casting,3D printing(additive manufacturing)offers advantages,such as the rapid production of complex structures,reduced material waste,and environmental friendliness.Direct ink writing(DIW)is one of the most popular 3D printing techniques owing to its ability to print multiple materials simultaneously and its high compatibility with printing inks.However,DIW presents significant challenges,particularly in the printing of high-performance polymers.The main challenges are as follows:1.The rigid structures and reaction kinetics of high-performance polymers make developing new inks difficult.2.The limited types of available high-performance polymers underscore the need for new DIW-suitable materials.3.Layer-by-layer stacking weakens interlayer bonding,affecting the mechanical properties of the printed product.4.The accuracy and speed of DIW printing are insufficient for large-scale manufacturing.After introducing the topic,the requirements for DIW printing inks are first reviewed,emphasizing the importance of thixotropic agents.Then,research progress regarding DIW printing of high-performance polymers is comprehensively reviewed according to the requirements of different polymer inks.Additionally,the applications of these materials across various fields are summarized.Finally,the challenges in DIW printing of high-performance polymers,along with corresponding solutions and future development prospects,are discussed in detail.展开更多
Three-dimensional(3 D)printing has revolutionized the design and production of customized scaffolds,but the minimally invasive implantation of 3 D-printed structures into the human body remains challenging.This has pr...Three-dimensional(3 D)printing has revolutionized the design and production of customized scaffolds,but the minimally invasive implantation of 3 D-printed structures into the human body remains challenging.This has prompted the exploration of innovative materials and technical solutions.Shape-memory polymers,as advanced intelligent materials,exhibit considerable potential in minimally invasive surgical applications.Herein,we developed a novel thermosetting shape-memory polymer,poly(L-lactic acid)-trimethylene carbonate-glycolic acid(PLLA-TMC-GA),for the fabrication of bioengineered scaffolds with body temperature-activated shape-memory functionality.We comprehensively evaluated the mechanical properties,thermal stability,shape-memory capabilities,biocompatibility,biodegradability,and 3 D printing performance of PLLA-TMC-GA terpolymers with various compositions.The results indicate that PLLA-TMC-GA exhibits exceptional shape-memory performance,adjustable material properties,favorable biocompatibility,and the potential for controlled biodegradation and reabsorption.The use of PLLA-TMC-GA as a biodegradable shape-memory polymer allows the reduction of implant volume,simplifies implantation,and enables on-demand activation at body temperature.These characteristics present new opportunities for the advancement of minimally invasive surgical techniques.展开更多
Chinese Journal of Polymer Science(CJPS)is a monthly journal published in English and sponsored by the Chinese Chemical Society and the Institute of Chemistry,Chinese Academy of Sciences.CJPS is edited by a distinguis...Chinese Journal of Polymer Science(CJPS)is a monthly journal published in English and sponsored by the Chinese Chemical Society and the Institute of Chemistry,Chinese Academy of Sciences.CJPS is edited by a distinguished Editorial Board headed by Professor Qi-Feng Zhou and supported by an International Advisory Board in which many famous active polymer scientists all over the world are included.The journal was first published in 1983 under the title Polymer Communications and has the current name since 1985.展开更多
We are pleased to announce the special topic of“AI for Polymers”published in the Chinese Journal of Polymer Science (CJPS).In recent years,the advancements in artificial intelligence (AI) techniques,including machin...We are pleased to announce the special topic of“AI for Polymers”published in the Chinese Journal of Polymer Science (CJPS).In recent years,the advancements in artificial intelligence (AI) techniques,including machine learning(particularly deep learning) and data-driven modeling,are reshaping how we design,synthesize and characterize polymers.In particular,a strong and lively research community in the development and application of AI techniques to polymer science has emerged in China,making great contributions to this important area of research in polymer science.With the growing interest in the application of AI to polymer science,we believe it is the right time to organize a special topic showcasing the activities and achievements of this community.展开更多
The practical application of poly(ethylene oxide)(PEO)-based solid polymer electrolytes in all-solid-state lithium-metal batteries(ASSLBs)still suffers from persistent challenges associated with low ionic conductivity...The practical application of poly(ethylene oxide)(PEO)-based solid polymer electrolytes in all-solid-state lithium-metal batteries(ASSLBs)still suffers from persistent challenges associated with low ionic conductivity and poor oxidative stability.To address these issues,we introduce a novel in-situ ionization strategy using radical polymer poly(2,2,6,6-tetramethyl-1-piperidinyloxy-4-yl acrylate)(PTPA)to enhance ionic conductivity and achieve a high electrochemical stability window in PEO-based electrolyte.Density functional theory(DFT)calculations and molecular dynamics(MD)simulations reveal that the in-situ generation of PTPA+from PTPA within the battery,not only exceptionally decreases the low Highest Occupied Molecular Orbital(HOMO)energy level,but also exhibits a robust anchoring effect on TFSI-anions in the electrolyte,which boosts Li^(+) migration and enables dense Li deposition behavior.As a result,the PEO/10 wt%PTPA/LiTFSI electrolyte demonstrates remarkable oxidative stability up to 5 V and a high Li^(+)transference number(0.57).Li-Li symmetric cells maintain stability over 1000 h at 0.2 mA cm^(-2),and LiFePO_(4)(LFP)//Li battery also presents an enduring cyclic performance over 500 cycles with a remarkable high-capacity retention of 91.8% at 0.5C.Impressively,by coupling with a high-voltage LiCoO_(2)(LCO)cathode(cut-off voltage 4.6 V),the assembled ASSLBs reach a capacity retention of 87.1% after 500 cycles at 1C.Our study explores the mechanism of radical polymer in PEO-based electrolyte and provides a fire-new strategy for construction of high-performance and multifunctional ASSLBs.展开更多
Unsaturated soil mechanics is crucial in understanding ground conditions and constructing geotechnical structures,particularly amidst the challenges posed by global climate change.Nevertheless,acquiring accurate soil ...Unsaturated soil mechanics is crucial in understanding ground conditions and constructing geotechnical structures,particularly amidst the challenges posed by global climate change.Nevertheless,acquiring accurate soil suction values remains challenging due to limitations in existing methodologies,such as susceptibility to cavitation,high costs,and time-intensive procedures.Hence,this study employs a high-suction polymer sensor(HSPS)to evaluate the polymer's performance in determining soil suction.Subsequently,the polymers were used to measure unsaturated soil properties,especially soil-water characteristics curves(SWCC),based on osmotic principles.Five polymer samples classified as superabsorbent polymers(SAP)were synthesized with varying degrees of crosslinking,and their properties were assessed through swelling test and Fourier-transform infrared spectroscopy(FTIR).The soil sample from Turan,located within Nazarbayev University,was analyzed using a bimodal equation to determine the best fit.Results revealed that the swelling value and structural integrity of the polymer significantly affect soil suction capacity,with the findings being deemed temperature-independent,thereby obviating the need for calibration.Two potential factors hindering suction increase were identified:cavitation within the polymer or a reduction in the osmotic gradient due to polymer transformation into hydrogel formation.Overall,the novel polymer shows promise as an alternate material for SWCC measurement considering its simple method and being more sustainable compared to the other polymers,although further investigation is required to enhance the suction potential.展开更多
Solid polymer electrolytes have garnered significant attention for lithium batteries because of their flexibility and safety.However,poor ionic conductivity,lithium dendrite formation,and high impedance hinder their p...Solid polymer electrolytes have garnered significant attention for lithium batteries because of their flexibility and safety.However,poor ionic conductivity,lithium dendrite formation,and high impedance hinder their practical application.In this study,a thin,flexible,3D hybrid solid electrolyte(3DHSE)is prepared by in situ thermal cross-linking polymerization with electrospun 3D nanowebs.The 3DHSE comprises Al-doped Li_(7)La_(3)Zr_(2)O_(12)(ALLZO)embedded in electrospun poly(vinylidene fluoride-cohexafluoropropylene)(PVDF-HFP)nonwoven 3D nanowebs and an in situ cross-linked polyethylene oxide(PEO)-based solid polymer electrolyte.The 3DHSE exhibits high tensile strength(6.55 MPa),a strain of 40.28%,enhanced ionic conductivity(7.86×10^(-4) S cm^(-1)),and a superior lithium-ion transference number(0.76)to that of the PVDF-HFP-based solid polymer electrolyte(PSPE).This enables highly stable lithium plating/stripping cycling for over 900 h at 25℃ with a current density of 0.2 mA cm^(-2).The LiNi_(0.8)Mn_(0.1)Co_(0.1)O_(2)(NCM811)/3DHSE/Li cell has a higher capacity(140.56 mAh g^(-1) at 0.1 C)than the NCM811/PSPE/Li cell(124.88 mAh g^(-1) at 0.1 C)at 25℃.The 3DHSE enhances mechanical properties,stabilizes interfacial contact,improves ion transport,prevents NCM811 cracking,and significantly boosts cycling performance.This study highlights the potential of the 3DHSE as a candidate for advanced lithium polymer battery technology.展开更多
基金supported by the National Natural Science Foundation of China(No.51972293)Hangzhou Key Research Program Project(2023SZD0099)LingYan Project(2024C01090).
文摘High-performance lithium metal batteries benefit from the construction of composite polymer electrolytes(CPEs)which are synthesized by incorporating inorganic fillers into polymer matrices[1].However,the random distribution of added fillers within the polymer matrix can lead to tortuous ion pathways and longer transmission distances(Fig.1).As a result,the ion transport capability of CPEs may decrease,while interface contact may deteriorate.Therefore,the organized arrangement of fillers emerges as a crucial consideration in constructing electrolyte membranes.One highly effective approach is the adoption of a vertically aligned filler configuration,where ceramic fillers are constructed to be perpendicular to the electrolyte membrane.If so,the filler/electrolyte interface impedance can be significantly reduced,while continuous ion transport channels along the specified direction are formed,thus significantly enhancing the ion conduction(Fig.1(a))[1].
基金financially supported by National Key R&D Program of China(No.2021YFA1501700)CAS Project for Young Scientists in Basic Research(No.YSBR-094)+1 种基金Natural Science Foundation of Anhui Province(Nos.2308085Y35 and 2023AH030002)Hefei Natural Science Foundation(No.202304)。
文摘As a powerful synthetic tool,ruthenium-catalyzed ring-opening metathesis polymerization(ROMP)has been widely utilized to prepare diverse heteroatom-containing polymers.In this contribution,we report the synthesis of the novel imine-based polymer through the copolymerization of cyclooctene with cyclic imine comonomer via ROMP.Because of the efficient hydrolysis reactions of the imine group,the generated copolymer can be easily degraded under mild condition.Moreover,the generated degradable product was the telechelic polymer bearing amine group,which was highly challenged for its direct synthesis.And this telechelic polymer could also be used for the further synthesis of new polymer through post-transformation.The introduction of imine unit in this work provides a new example of the degradable polymer synthesis.
文摘Aims and Scope,Chinese Journal of Polymer Science(CJPS)is a monthly journal published in Englishand sponsored by the Chinese Chemical Society and the Institute of Chemistry,,Chinese Academy of Sciences.CJPS isedited by a distinguished Editorial Board headed by Professor Qi-Feng Zhouand supported by an International Advisory Board in which many famous active polymerscientists alloverthe world are included.The journal was first published in 1983 under the title Polymer Communications and has the current name since 1985.
基金funding from the National Natural Science Foundation of China(No.22401037)funding from JST CREST(No.JPMJCR23L1)。
文摘Chain-growth radical polymerization of vinyl monomers is essential for producing a wide range of materials with properties tailored to specific applications.However,the inherent resistance of the polymer's C―C backbone to degradation raises significant concerns regarding long-term environmental persistence,which also limits their potential in biomedical applications.To address these challenges,researchers have developed strategies to either degrade preexisting vinyl polymers or incorporate cleavable units into the backbone to modify them with enhanced degradability.This review explores the various approaches aimed at achieving backbone degradability in chain-growth radical polymerization of vinyl monomers,while also highlighting future research directions for the development of application-driven degradable vinyl polymers.
基金financially supported by the National Key R&D Program of China(No.2022YFC2805103)the National Natural Science Foundation of China(Nos.52022031 and 52263001)the Foundation from Qinghai Science and Technology Department(No.2022-ZJ-944Q)。
文摘Incorporation of acetal groups in the backbone is a potent strategy to create polymers that are cleavable or degradable under acidic conditions.We report here an in-depth study on the ring-closing-opening copolymerization of o-phthalaldehyde(OPA)and epoxide using Lewis pair type two-component organocatalysts for producing acetal-functionalized polyether and polyurethane.Notably,triethylborane as the Lewis acid,in comparison with tri(n-butyl)borane,more effectively enhances the polymerization activity by mitigating borane-induced reduction of the aldehyde group into extra initiating(borinic ester)species.Density functional theory(DFT)calculations present comparable energy barriers of OPA-epoxide cross-propagation and epoxide self-propagation,which is consistent with the experimental finding that an alternating-rich copolymer comprising mostly OPA-epoxide units but also epoxide-epoxide linkages is produced.In particular,when epoxide is added in a large excess,the product becomes a polyether containing acetal functionalities in the central part of the backbone and thus being convertible into polyurethane with refined acid degradability.
基金financially supported by the Scientific Research Start-up Fund Project of Anhui Polytechnic University for Introducing Talents(No.2022YQQ081)Natural Science Research Project of Anhui Educational Committee(No.2024AH050133)the National Natural Science Foundation of China(No.22001078).
文摘Functional hyperbranched polymers,as an important class of materials,are widely applied in diverse areas.Therefore,the development of simple and efficient reactions to prepare hyperbranched polymers is of great significance.In this work,trialdehydes,diamines,and trimethylsilyl cyanide could easily undergo multicomponent polymerization under mild conditions,producing hyperbranched poly(α-aminonitrile)s with high molecular weights(M_(w) up to 4.87×10^(4))in good yields(up to 85%).The hyperbranched poly(α-aminonitrile)s have good solubility in commonly used organic solvents,high thermal stability as well as morphological stability.Furthermore,due to the numerous aldehyde groups in their branched chains,these hb-poly(α-aminonitrile)s can undergo one-pot,two-step,four-component post-polymerization with high efficiency.This work not only confirms the efficiency of our established catalyst-free multicomponent polymerization of aldehydes,amines and trimethylsilyl cyanide,but also provides a versatile and powerful platform for the preparation of functional hyperbranched polymeric materials.
基金the National Natural Science Foundation of China(grant nos.52020105012 and 523B2025)the Innovation and Talent Recruitment Base of New Energy Chemistry and Device(B21003)the Analysis and Testing Center of HUST for the assistance in analysis and testing。
文摘Solid polymer electrolytes(SPEs)have garnered considerable interest in the field of lithium metal batteries(LMBs)owing to their exceptional mechanical strength,excellent designability,and heightened safety characteristics.However,their inherently low ion transport efficiency poses a major challenge for their application in LMBs.To address this issue,covalent organic framework(COF)with their ordered ion transport channels,chemical stability,large specific surface area,and designable multifunctional sites has shown promising potential to enhance lithium-ion conduction.Here,we prepared an anionic COF,Tp Pa-COOLi,which can catalyze the ring-opening copolymerization of cyclic lactone monomers for the in situ fabrication of SPEs.The design leverages the high specific surface area of COF to facilitate the absorption of polymerization precursor and catalyze the polymerization within the pores,forming additional COF-polymer junctions that enhance ion transport pathways.The partial exfoliation of COF achieved through these junctions improved its dispersion within the polymer matrix,preserving ion transport channels and facilitating ion transport across COF grain boundaries.By controlling variables to alter the crystallinity of Tp Pa-COOLi and the presence of-COOLi substituents,Tp Pa-COOLi with partial long-range order and-COOLi substituents exhibited superior electrochemical performance.This research demonstrates the potential in constructing high-performance SPEs for LMBs.
基金supported by National Natural Science Foundation of China(82104082)Natural Science Foundation of Qinghai Province(2024-ZJ-911).
文摘The recent commercialization of gene products has sparked significant interest in gene therapy,necessitating efficient and precise gene delivery via various vectors.Currently,viral vectors and lipid-based nanocarriers are the predominant choices and have been extensively investigated and reviewed.Beyond these vectors,polymeric nanocarriers also hold the promise in therapeutic gene delivery owing to their versatile functionalities,such as improving the stability,cellar uptake and endosomal escape of nucleic acid drugs,along with precise delivery to targeted tissues.This review presents a brief overview of the status quo of the emerging polymeric nanocarriers for therapeutic gene delivery,focusing on key cationic polymers,nanocarrier types,and preparation methods.It also highlights targeted diseases,strategies to improve delivery efficiency,and potential future directions in this research area.The review is hoped to inspire the development,optimization,and clinical translation of highly efficient polymeric nanocarriers for therapeutic gene delivery.
基金supported by the National Natural Science Foundation of China(NSFC)under Grant No.22035001 and No.52233005.
文摘To achieve the target of carbon neutrality,it is crucial to develop an efficient and green synthesis methodology with good atomic economy to achieve sufficient utilization of energy and sustainable development.Photoinduced electron transfer reversible addition-fragmentation chain-transfer(PET-RAFT)polymerization is a precise methodology for constructing polymers with well-defined structures.However,conventional semiconductor-mediated PET-RAFT polymerization still has considerable limitations in terms of efficiency as well as the polymerization environment.Herein,sulfur-doped carbonized polymer dots(CPDs)were hydrothermally synthesized for catalysis of aqueous PET-RAFT polymerization at unprecedented efficiency with a highest propagation rate of 5.05 h-1.The resulting polymers have well-controlled molecular weight and narrow molecular weight dispersion(Ð<1.10).Based on the optoelectronic characterizations,we obtained insights into the photoinduced electron transfer process and proposed the mechanism for CPD-mediated PET-RAFT polymerization.In addition,as-synthesized CPDs for PET-RAFT polymerization were also demonstrated to be suitable for a wide range of light sources(blue/green/solar irradiation),numerous monomers,low catalyst loading(low as 0.01 mg mL^(-1)),and multiple polar solvent environments,all of which allowed to achieve efficiencies much higher than those of existing semiconductor-mediated methods.Finally,the CPDs were confirmed to be non-cytotoxic and catalyzed PET-RAFT polymerization successfully in cell culture media,indicating broad prospects in biomedical fields.
文摘In this work,by combining the specific selectivity of molecularly imprinted polymer(MIP)with a simple and sensitive electrochemiluminescence(ECL)detection method,a molecularly imprinted ECL sensor for kanamycin(KA)was developed.The MIP film was synthesized on the surface of gold electrode via electrochemical polymerization,using pyrrole(PY)as the functional monomer and KA as the template molecule.The commonly used luminescent reagent Ru(bpy)32+was employed as the ECL probe,and its co-reagent tripropylamine(TPA)was added to enhance the detection sensitivity of the sensor.Quantitative analysis of KA was performed by evaluating the difference in ECL responses between MIP film electrodes after KA removal and KA rebinding.The sensor exhibited high selectivity,good reproducibility,and stability toward KA,with a linear range of 5.00×10^(-8) to 1.00×10^(-5) mol·L^(-1) and a limit of detection of 1.67×10^(-8) mol·L^(-1)(S/N=3).This work would provide a new idea for the development of simple and sensitive molecularly imprinted ECL sensors.
文摘Building and construction sector, including infrastructures, are facing many challenges which are scarcity of raw materials, CO2 emissions, lower construction efficiency, and deterioration under corrosive environment that cost the world economy $2.5 trillion and this translates to 3.4% of world gross domestic product. This paper presents several examples that show how the use of the nonmetallic materials improved sustainability and life cycles in the built environment by removing the corrosion issue from its root and using durable NM polymers in construction. The paper details recently patented Aramco technology for the use of nonmetallic paving panels that could be used as an alternative to concrete and asphalt paving. Other case studies presented cover use of GFRP Poles for traffic signs and signal poles to replace traditional steel poles. Details of developments for specialist structural application in bridges, in architectural applications, polymers in soils, fibers in pavement manholes and bendable concrete are presented.
文摘Driven by the dual imperatives of global plastic pollution control and carbon neutrality,research on depolymerizable polymers has become a cutting-edge focus in polymer science.With the continuous emergence of innovative materials,strengthened policy support,and maturing industrial chains,these polymers are demonstrating transformative potential in critical sectors,such as environmental protection,healthcare,and industrial manufacturing,promising for reshaping the future landscape of the plastics industry.
基金financially supported by the National Natural Science Foundation of China (Nos. 92372126,52373203)the Excellent Young Scientists Fund Program
文摘Advancing the integration of artificial intelligence and polymer science requires high-quality,open-source,and large-scale datasets.However,existing polymer databases often suffer from data sparsity,lack of polymer-property labels,and limited accessibility,hindering system-atic modeling across property prediction tasks.Here,we present OpenPoly,a curated experimental polymer database derived from extensive lit-erature mining and manual validation,comprising 3985 unique polymer-property data points spanning 26 key properties.We further develop a multi-task benchmarking framework that evaluates property prediction using four encoding methods and eight representative models.Our re-sults highlight that the optimized degree-of-polymerization encoding coupled with Morgan fingerprints achieves an optimal trade-off between computational cost and accuracy.In data-scarce condition,XGBoost outperforms deep learning models on key properties such as dielectric con-stant,glass transition temperature,melting point,and mechanical strength,achieving R2 scores of 0.65-0.87.To further showcase the practical utility of the database,we propose potential polymers for two energy-relevant applications:high temperature polymer dielectrics and fuel cell membranes.By offering a consistent and accessible benchmark and database,OpenPoly paves the way for more accurate polymer-property modeling and fosters data-driven advances in polymer genome engineering.
基金supported by National Key Research and Development Program of China(Grant No.2022YFB3809000)Major Science and Technology Project of Gansu Province(Grant No.23ZDGA011)+1 种基金National Natural Science Foundation of China(Grant No.22275199,52105224)the Strategic Priority Research Program of the Chinese Academy of Sciences(Grant No.XDB04701022021).
文摘Compared to subtractive manufacturing and casting,3D printing(additive manufacturing)offers advantages,such as the rapid production of complex structures,reduced material waste,and environmental friendliness.Direct ink writing(DIW)is one of the most popular 3D printing techniques owing to its ability to print multiple materials simultaneously and its high compatibility with printing inks.However,DIW presents significant challenges,particularly in the printing of high-performance polymers.The main challenges are as follows:1.The rigid structures and reaction kinetics of high-performance polymers make developing new inks difficult.2.The limited types of available high-performance polymers underscore the need for new DIW-suitable materials.3.Layer-by-layer stacking weakens interlayer bonding,affecting the mechanical properties of the printed product.4.The accuracy and speed of DIW printing are insufficient for large-scale manufacturing.After introducing the topic,the requirements for DIW printing inks are first reviewed,emphasizing the importance of thixotropic agents.Then,research progress regarding DIW printing of high-performance polymers is comprehensively reviewed according to the requirements of different polymer inks.Additionally,the applications of these materials across various fields are summarized.Finally,the challenges in DIW printing of high-performance polymers,along with corresponding solutions and future development prospects,are discussed in detail.
基金supported by the National Natural Science Foundation of China(Nos.82402822,82360427,82372425,82072443,and 32200559)the Priority Union Foundation of Yunnan Provincial Science and Technology Department and Kunming Medical University(No.202301AY070001-164)+1 种基金the Natural Science Foundation of Sichuan Province(No.23NSFSC5880)the Central Government of Sichuan Province Guiding the Special Project of Local Science and Technology Development(No.2024ZYD0155).
文摘Three-dimensional(3 D)printing has revolutionized the design and production of customized scaffolds,but the minimally invasive implantation of 3 D-printed structures into the human body remains challenging.This has prompted the exploration of innovative materials and technical solutions.Shape-memory polymers,as advanced intelligent materials,exhibit considerable potential in minimally invasive surgical applications.Herein,we developed a novel thermosetting shape-memory polymer,poly(L-lactic acid)-trimethylene carbonate-glycolic acid(PLLA-TMC-GA),for the fabrication of bioengineered scaffolds with body temperature-activated shape-memory functionality.We comprehensively evaluated the mechanical properties,thermal stability,shape-memory capabilities,biocompatibility,biodegradability,and 3 D printing performance of PLLA-TMC-GA terpolymers with various compositions.The results indicate that PLLA-TMC-GA exhibits exceptional shape-memory performance,adjustable material properties,favorable biocompatibility,and the potential for controlled biodegradation and reabsorption.The use of PLLA-TMC-GA as a biodegradable shape-memory polymer allows the reduction of implant volume,simplifies implantation,and enables on-demand activation at body temperature.These characteristics present new opportunities for the advancement of minimally invasive surgical techniques.
文摘Chinese Journal of Polymer Science(CJPS)is a monthly journal published in English and sponsored by the Chinese Chemical Society and the Institute of Chemistry,Chinese Academy of Sciences.CJPS is edited by a distinguished Editorial Board headed by Professor Qi-Feng Zhou and supported by an International Advisory Board in which many famous active polymer scientists all over the world are included.The journal was first published in 1983 under the title Polymer Communications and has the current name since 1985.
文摘We are pleased to announce the special topic of“AI for Polymers”published in the Chinese Journal of Polymer Science (CJPS).In recent years,the advancements in artificial intelligence (AI) techniques,including machine learning(particularly deep learning) and data-driven modeling,are reshaping how we design,synthesize and characterize polymers.In particular,a strong and lively research community in the development and application of AI techniques to polymer science has emerged in China,making great contributions to this important area of research in polymer science.With the growing interest in the application of AI to polymer science,we believe it is the right time to organize a special topic showcasing the activities and achievements of this community.
基金supported by the National Natural Science Foundation of China(51973236,51573213)Zhuhai Industry University-Research Cooperation Program(2320004002721)。
文摘The practical application of poly(ethylene oxide)(PEO)-based solid polymer electrolytes in all-solid-state lithium-metal batteries(ASSLBs)still suffers from persistent challenges associated with low ionic conductivity and poor oxidative stability.To address these issues,we introduce a novel in-situ ionization strategy using radical polymer poly(2,2,6,6-tetramethyl-1-piperidinyloxy-4-yl acrylate)(PTPA)to enhance ionic conductivity and achieve a high electrochemical stability window in PEO-based electrolyte.Density functional theory(DFT)calculations and molecular dynamics(MD)simulations reveal that the in-situ generation of PTPA+from PTPA within the battery,not only exceptionally decreases the low Highest Occupied Molecular Orbital(HOMO)energy level,but also exhibits a robust anchoring effect on TFSI-anions in the electrolyte,which boosts Li^(+) migration and enables dense Li deposition behavior.As a result,the PEO/10 wt%PTPA/LiTFSI electrolyte demonstrates remarkable oxidative stability up to 5 V and a high Li^(+)transference number(0.57).Li-Li symmetric cells maintain stability over 1000 h at 0.2 mA cm^(-2),and LiFePO_(4)(LFP)//Li battery also presents an enduring cyclic performance over 500 cycles with a remarkable high-capacity retention of 91.8% at 0.5C.Impressively,by coupling with a high-voltage LiCoO_(2)(LCO)cathode(cut-off voltage 4.6 V),the assembled ASSLBs reach a capacity retention of 87.1% after 500 cycles at 1C.Our study explores the mechanism of radical polymer in PEO-based electrolyte and provides a fire-new strategy for construction of high-performance and multifunctional ASSLBs.
基金supported by the research project from the Ministry of Higher Education and Science of the Republic of Kazakhstan(Grant No.AP19675456)Nazarbayev University Collaborative Research Program(CRP)(Grant No.111024CRP2010)Collaborative Research Program(CRP)(Grant No.111024CRP2011).
文摘Unsaturated soil mechanics is crucial in understanding ground conditions and constructing geotechnical structures,particularly amidst the challenges posed by global climate change.Nevertheless,acquiring accurate soil suction values remains challenging due to limitations in existing methodologies,such as susceptibility to cavitation,high costs,and time-intensive procedures.Hence,this study employs a high-suction polymer sensor(HSPS)to evaluate the polymer's performance in determining soil suction.Subsequently,the polymers were used to measure unsaturated soil properties,especially soil-water characteristics curves(SWCC),based on osmotic principles.Five polymer samples classified as superabsorbent polymers(SAP)were synthesized with varying degrees of crosslinking,and their properties were assessed through swelling test and Fourier-transform infrared spectroscopy(FTIR).The soil sample from Turan,located within Nazarbayev University,was analyzed using a bimodal equation to determine the best fit.Results revealed that the swelling value and structural integrity of the polymer significantly affect soil suction capacity,with the findings being deemed temperature-independent,thereby obviating the need for calibration.Two potential factors hindering suction increase were identified:cavitation within the polymer or a reduction in the osmotic gradient due to polymer transformation into hydrogel formation.Overall,the novel polymer shows promise as an alternate material for SWCC measurement considering its simple method and being more sustainable compared to the other polymers,although further investigation is required to enhance the suction potential.
基金supported by the National Research Foundation of Korea(NRF)(no.:NRF-2020M3H4A3081874)the National Research Council of Science&Technology(NST)grant by the Korea government(MSIT)(no.:GTL24011-000)the Korea Research Institute of Chemical Technology(KRICT),Republic of Korea(no.KS2422-20).
文摘Solid polymer electrolytes have garnered significant attention for lithium batteries because of their flexibility and safety.However,poor ionic conductivity,lithium dendrite formation,and high impedance hinder their practical application.In this study,a thin,flexible,3D hybrid solid electrolyte(3DHSE)is prepared by in situ thermal cross-linking polymerization with electrospun 3D nanowebs.The 3DHSE comprises Al-doped Li_(7)La_(3)Zr_(2)O_(12)(ALLZO)embedded in electrospun poly(vinylidene fluoride-cohexafluoropropylene)(PVDF-HFP)nonwoven 3D nanowebs and an in situ cross-linked polyethylene oxide(PEO)-based solid polymer electrolyte.The 3DHSE exhibits high tensile strength(6.55 MPa),a strain of 40.28%,enhanced ionic conductivity(7.86×10^(-4) S cm^(-1)),and a superior lithium-ion transference number(0.76)to that of the PVDF-HFP-based solid polymer electrolyte(PSPE).This enables highly stable lithium plating/stripping cycling for over 900 h at 25℃ with a current density of 0.2 mA cm^(-2).The LiNi_(0.8)Mn_(0.1)Co_(0.1)O_(2)(NCM811)/3DHSE/Li cell has a higher capacity(140.56 mAh g^(-1) at 0.1 C)than the NCM811/PSPE/Li cell(124.88 mAh g^(-1) at 0.1 C)at 25℃.The 3DHSE enhances mechanical properties,stabilizes interfacial contact,improves ion transport,prevents NCM811 cracking,and significantly boosts cycling performance.This study highlights the potential of the 3DHSE as a candidate for advanced lithium polymer battery technology.
