For estimating the altitude-distribution pattern of carbon stocks in desert grasslands and analyzing the possible mechanism for this distribution, a detailed study was performed through a series of field vegetation su...For estimating the altitude-distribution pattern of carbon stocks in desert grasslands and analyzing the possible mechanism for this distribution, a detailed study was performed through a series of field vegetation surveys and soil samplings from 90 vegetation plots and 45 soil profiles at 9 sites of the Hexi Corridor region, Northwestern China. Aboveground, belowground, and litter-fall biomass-carbon stocks ranged from 43 to 109, 23 to 64, and 5 to 20 g/m2, with mean values of 80.82,44.91, and 12.15 g/m2, respectively. Soil-carbon stocks varied between 2.88 and 3.98 kg/m2, with a mean value of 3.43 kg/m2 in the 0–100-cm soil layer. Both biomass-and soil-carbon stocks had an increasing tendency corresponding to the altitudinal gradient. A significantly negative correlation was found between soil-carbon stock and mean annual temperature, with further better correlations between soil-and biomass-carbon stocks, and mean annual precipitation. Furthermore, soil carbon was found to be positively correlated with soil-silt and-clay content, and negatively correlated with soil bulk density and the volume percent of gravel. It can be concluded that variations in soil texture and climate condition were the key factors influencing the altitudinal pattern of carbon stocks in this desert-grassland ecosystem. Thus, by using the linear-regression functions between altitude and carbon stocks, approximately 4.18 Tg carbon were predicted from the 1,260 km2 of desert grasslands in the study area.展开更多
Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is s...Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is still a great challenge.Here,we report a series of catechol-decorated polyallylamines(CPAs),denoted as pseudo-Mytilus edulis foot protein 5(pseudoMefp-5),that mimic not only the catechol and amine groups but also the backbone of Mefp-5.CPAs can fabricate highly adhesive,robust,multifunctional polyCPA(PCPA)coatings based on synergetic catechol-polyamine chemistry as universal building blocks.Due to the interpenetrating entangled network architectures,these coatings exhibit high chemical robustness against harsh conditions(HCl,pH 1;NaOH,pH 14;H2O2,30%),good mechanical robustness,and wear resistance.In addition,PCPA coatings provide abundant grafting sites,enabling the fabrication of various functional surfaces through secondary modification.Furthermore,the versatility,multifaceted robustness,and scalability of PCPA coatings indicate their great potential for surface engineering,especially for withstanding harsh conditions in multipurpose biomedical applications.展开更多
Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like prote...Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like protein surface engineering strategy we called as“armored-tank”strategy for dual functionalization of medical devices.The“armored-tank”strategy is realized by decoration of partially conformational transformed LZM(PCTL)assembly through oxidant-mediated process,followed by armoring with super-hydrophilic poly-2-methacryloyloxyethyl phosphorylcholine(pMPC).The outer armor of the“armored-tank”shows potent and durable zone defense against fibrinogen,platelet and bacteria adhesion,leading to long-term antithrombogenic properties over 14 days in vivo without anticoagulation.Additionally,the“fired”PCTL from“armored-tank”actively and effectively kills both Gram-positive and Gram-negative bacterial over 30 days as a supplement to the lacking bactericidal functions of passive outer armor.Overall,this“armored-tank”surface engineering strategy serves as a promising solution for preventing biofouling and thrombotic occlusion of medical devices.展开更多
Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor fo...Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor for tailoring temporary interventional devices with durable resistance to protein adsorption and the following protein-mediated complications.By mimicking the phenol-polyamine chemistry assisted by phenol oxidases during sclerotization,we develop a facile one-step method to crosslink bovine serum albumin(BSA)with oxidized hydrocaffeic acid(HCA),resulting in a stable and universal BSA@HCA armor.Furthermore,the surface of the BSA@HCA armor,enriched with carboxyl groups,supports the secondary grafting of polyethylene glycol(PEG),further enhancing both its antifouling performance and durability.The synergy of robustly immobilized BSA and covalently grafted PEG provide potent resistance to the adhesion of proteins,platelets,and vascular cells in vitro.In ex vivo blood circulation experiment,the armored surface reduces thrombus formation by 95%.Moreover,the antifouling armor retained over 60%of its fouling resistance after 28 days of immersion in PBS.Overall,our armor engineering strategy presents a promising solution for enhancing the antifouling properties and clinical performance of temporary interventional medical devices.展开更多
Thrombosis and infection are two major complications associated with central venous catheters(CVCs),which significantly contribute to morbidity and mortality.Antifouling coating strategies currently represent an effic...Thrombosis and infection are two major complications associated with central venous catheters(CVCs),which significantly contribute to morbidity and mortality.Antifouling coating strategies currently represent an efficient approach for addressing such complications.However,existing antifouling coatings have limitations in terms of both duration and effectiveness.Herein,we propose a durable zwitterionic polymer armor for catheters.This armor is realized by pre-coating with a robust phenol-polyamine film inspired by insect sclerotization,followed by grafting of poly-2-methacryloyloxyethyl phosphorylcholine(pMPC)via in-situ radical polymerization.The resulting pMPC coating armor exhibits super-hydrophilicity,thereby forming a highly hydrated shell that effectively prevents bacterial adhesion and inhibits the adsorption and activation of fibrinogen and platelets in vitro.In practical applications,the armored catheters significantly reduced inflammation and prevented biofilm formation in a rat subcutaneous infection model,as well as inhibited thrombus formation in a rabbit jugular vein model.Overall,our robust zwitterionic polymer coating presents a promising solution for reducing infections and thrombosis associated with vascular catheters.展开更多
Integration of two or more biomolecules with synergetic and complementary effects on a material surface can help to obtain multi-functions for various biomedical applications.However,the amounts of biomolecules integr...Integration of two or more biomolecules with synergetic and complementary effects on a material surface can help to obtain multi-functions for various biomedical applications.However,the amounts of biomolecules integrated and their physiological functions are compromised due to the limited surface anchoring sites.Herein,we propose a novel concept of film engineering strategy“from surface to bulk synergetic modification”.This new concept is realized by employing the surface amine groups of plasma polymerized allylamine(PPAm)film for grafting a molecule e.g.,thrombin inhibitor,bivalirudin(BVLD),meanwhile its bulk amine groups is used as a universal depot for storing and releasing therapeutic nitric oxide(NO)gas as supplement to the functions of BVLD.It is demonstrated that such a“from surface to bulk synergetic modification”film engineering can impart the modified-substrates with anti-platelet and anti-coagulant dual functions,giving rise to a highly endotheliummimetic thromboresistant property.We believe that our research provides a very promising strategy to deliver multifunctional surface versatilely that require NO release in combination with other properties,which will find broad biomedical applications in blood-contacting devices,and et al.Moreover,it also provides a brand-new film engineering strategy for tailoring surface multi-functionalities of a wide range of materials.展开更多
The design of assembling high-nuclearity transition-lanthanide(3d-4f) clusters along with excellent magnetocaloric effect(MCE) is one of the most prominent fields but is extremely challenging. Herein, two heterometall...The design of assembling high-nuclearity transition-lanthanide(3d-4f) clusters along with excellent magnetocaloric effect(MCE) is one of the most prominent fields but is extremely challenging. Herein, two heterometallic metal coordination polymers are constructed via the “carbonatetemplate” method, formulated as {[Gd_(18)Ni_(24)(IDA)_(22)(CO_(3))_(7)(μ_(3)-OH)_(32)(μ_(2)-OH)_(3)(H_(2)O)_(5)Cl]·Cl_(8)·(H_(2)O)_(14)}nand{[Eu_(18)Ni_(23.5)(IDA)_(22)(CO_(3)_(7)(μ_(3)-OH)_(32)(H_(2)O)_(5)(IN)(CH_(3)COO)_(2)(NH_(2)CH_(2)COO)Cl]·C_(l6)·(H_(2)O)_(17)}n[abbreviated as 1-(Gd_(18)Ni_(24))nand 2-(Eu_(18)Ni_(23.5))n respectively;H_(2)IDA = iminodiacetic acid;HIN = isonicotinic acid]. Concerning the structures, compounds 1-(Gd_(18)Ni_(24))nand 2-(Eu_(18)Ni_(23.5))nboth feature the one-dimensional(1D) chain-like structure which is rarely reported in high-nuclearity metal complexes. Meanwhile, the large presences of Gd3+ ions in compound 1-(Gd18Ni24)nare conducive to the fantastic MCE, and the value of-ΔS_(m)is 35.30 J kg^(-1)K^(-1) at 3.0 K and ΔH = 7.0 T. And more significantly, compound 1-Gd_(18)Ni_(24)n shows the large low-field magnetic entropy change(-ΔS_(m)= 20.95 J kg(-1) K(-1) at 2.0 K and ΔH = 2.0 T)among the published 3 d-4 f mixed metal clusters.展开更多
Chemical fixation of CO_(2)into C1 source, as a general approach, can effectively alleviate the emission of greenhouse gasses. Whereas, the challenge posed by the need for efficient catalysts with high catalytic activ...Chemical fixation of CO_(2)into C1 source, as a general approach, can effectively alleviate the emission of greenhouse gasses. Whereas, the challenge posed by the need for efficient catalysts with high catalytic active sites still exists. In this work, we reported a series of new hexavanadate clusters, [(C6H6ON)2(C2H8N2)2(CH3O)6VIV6O8](V6–1), [(C6H6ON)2(C3H10N2)2(CH3O)6VIV6O8](V6–2), [(C6H6ON)2(C6H14N2)2(CH3O)6VIV6O8](V6–3) and [(C6H6ON)2(C4H11N2O)2(CH3O)4VIV6O8](V6–4), assembled by 2-aminophenol and four different kinds of Lewis bases(LB), ethanediamine(en), 1,2-diaminopropane, 1,2-cyclohexanediamine and N-(2-hydroxyethyl)ethylenediamine(ben) together. Among them, the basic unit {V6} cluster featured Z-shaped configuration represents a brand-new example of hexanuclear vanadium clusters. Remarkably, the catalytic tests demonstrated that V6–1 as catalyst displays high catalytic activity in the cycloaddition for the CO_(2)fixation into cyclic carbonates by virtue of open V sites. As expected, for oxidative desulfurization of sulfides, V6–1 also exhibits satisfied catalytic effectiveness. Furthermore, the recycling test confirmed that catalyst V6–1 may be a bifunctional heterogeneous catalyst with great promise for both CO_(2)cycloaddition and oxidative desulfurization reactions.展开更多
Batterymanagement systems(BMSs)are essential in ensuring the safe and stable operation of lithium-ion batteries(LIBs)in electric vehicles(EVs).Accurate sensor signals,particularly voltage,current,and temperature senso...Batterymanagement systems(BMSs)are essential in ensuring the safe and stable operation of lithium-ion batteries(LIBs)in electric vehicles(EVs).Accurate sensor signals,particularly voltage,current,and temperature sensor signals,are essential for a BMS to performfunctions such as state estimation,balance control,and fault diagnosis.The smooth operation of a BMS depends primarily on sensor signals,which provide current,voltage,and temperature information to maintain the battery pack in a safe running state.However,sensor failures and inaccurate measurement data can easily occur because of external interference and complex operating conditions.Therefore,an investigation into the faultdiagnosis of battery sensors and fault-tolerant control(FTC)is necessary to ensure the normal operation of a BMS.This paper analyzes themodes of sensor faults,fault diagnosismethods,and fault-tolerant control techniques.First,the differentmodes of sensor faults are analyzed,andmathematical expressions for these faults are provided.Second,diagnostic methods for sensor faults based on models,signal processing,and data-drivenmethods are analyzed in detail.Finally,FTC techniques are introduced to ensure stable sensor operation.Based on an analysis of the research status of sensor fault diagnosis,a new development direction for sensor fault diagnosis is proposed.展开更多
基金funded by the Key Research Program of Frontier Sciences of Chinese Academy of Sciences (QYZDJ-SSW-DQC040)the National Key Research and Development Program of China (2017YFC0504306 and 2017YFC0504304)the China National Natural Science Foundation (41201284)
文摘For estimating the altitude-distribution pattern of carbon stocks in desert grasslands and analyzing the possible mechanism for this distribution, a detailed study was performed through a series of field vegetation surveys and soil samplings from 90 vegetation plots and 45 soil profiles at 9 sites of the Hexi Corridor region, Northwestern China. Aboveground, belowground, and litter-fall biomass-carbon stocks ranged from 43 to 109, 23 to 64, and 5 to 20 g/m2, with mean values of 80.82,44.91, and 12.15 g/m2, respectively. Soil-carbon stocks varied between 2.88 and 3.98 kg/m2, with a mean value of 3.43 kg/m2 in the 0–100-cm soil layer. Both biomass-and soil-carbon stocks had an increasing tendency corresponding to the altitudinal gradient. A significantly negative correlation was found between soil-carbon stock and mean annual temperature, with further better correlations between soil-and biomass-carbon stocks, and mean annual precipitation. Furthermore, soil carbon was found to be positively correlated with soil-silt and-clay content, and negatively correlated with soil bulk density and the volume percent of gravel. It can be concluded that variations in soil texture and climate condition were the key factors influencing the altitudinal pattern of carbon stocks in this desert-grassland ecosystem. Thus, by using the linear-regression functions between altitude and carbon stocks, approximately 4.18 Tg carbon were predicted from the 1,260 km2 of desert grasslands in the study area.
基金supported by the National Natural Science Foundation of China(projects 82072072,32171326,82272157,32261160372,and 82350710800)the Guangdong Basic and Applied Basic Research Foundation(2022B1515130010 and 2021A1515111035)+1 种基金the National Natural Science Foundation of China/Research Grants Council(NSFC/RGC)Joint Research Scheme(N_PolyU526/22)the Leading Talent Project of Guangzhou Development District(2020-L013)。
文摘Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is still a great challenge.Here,we report a series of catechol-decorated polyallylamines(CPAs),denoted as pseudo-Mytilus edulis foot protein 5(pseudoMefp-5),that mimic not only the catechol and amine groups but also the backbone of Mefp-5.CPAs can fabricate highly adhesive,robust,multifunctional polyCPA(PCPA)coatings based on synergetic catechol-polyamine chemistry as universal building blocks.Due to the interpenetrating entangled network architectures,these coatings exhibit high chemical robustness against harsh conditions(HCl,pH 1;NaOH,pH 14;H2O2,30%),good mechanical robustness,and wear resistance.In addition,PCPA coatings provide abundant grafting sites,enabling the fabrication of various functional surfaces through secondary modification.Furthermore,the versatility,multifaceted robustness,and scalability of PCPA coatings indicate their great potential for surface engineering,especially for withstanding harsh conditions in multipurpose biomedical applications.
基金supported by by the National Natural Science Foundation of China(Project 82202325,82072072,32171326,32261160372)the Guang Dong Basic and Applied Basic Research Foundation(2022B1515130010,2021A1515111035)China Postdoctoral Science Foundation(2022M721524).
文摘Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like protein surface engineering strategy we called as“armored-tank”strategy for dual functionalization of medical devices.The“armored-tank”strategy is realized by decoration of partially conformational transformed LZM(PCTL)assembly through oxidant-mediated process,followed by armoring with super-hydrophilic poly-2-methacryloyloxyethyl phosphorylcholine(pMPC).The outer armor of the“armored-tank”shows potent and durable zone defense against fibrinogen,platelet and bacteria adhesion,leading to long-term antithrombogenic properties over 14 days in vivo without anticoagulation.Additionally,the“fired”PCTL from“armored-tank”actively and effectively kills both Gram-positive and Gram-negative bacterial over 30 days as a supplement to the lacking bactericidal functions of passive outer armor.Overall,this“armored-tank”surface engineering strategy serves as a promising solution for preventing biofouling and thrombotic occlusion of medical devices.
基金supported by the National Natural Science Foundation of China,China(Project 82202325,82072072,32171326,32261160372)the Guangdong Basic and Applied Basic Research Foundation,China(2022B1515130010,2021A1515111035)+2 种基金Dongguan Science and Technology of Social Development Program,China(20231800906311,20231800900332)China Postdoctoral Science Foundation,China(2022M721524)Leading Talent Project of Guangzhou Development District,China(2020-L013)。
文摘Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor for tailoring temporary interventional devices with durable resistance to protein adsorption and the following protein-mediated complications.By mimicking the phenol-polyamine chemistry assisted by phenol oxidases during sclerotization,we develop a facile one-step method to crosslink bovine serum albumin(BSA)with oxidized hydrocaffeic acid(HCA),resulting in a stable and universal BSA@HCA armor.Furthermore,the surface of the BSA@HCA armor,enriched with carboxyl groups,supports the secondary grafting of polyethylene glycol(PEG),further enhancing both its antifouling performance and durability.The synergy of robustly immobilized BSA and covalently grafted PEG provide potent resistance to the adhesion of proteins,platelets,and vascular cells in vitro.In ex vivo blood circulation experiment,the armored surface reduces thrombus formation by 95%.Moreover,the antifouling armor retained over 60%of its fouling resistance after 28 days of immersion in PBS.Overall,our armor engineering strategy presents a promising solution for enhancing the antifouling properties and clinical performance of temporary interventional medical devices.
基金supported by the National Natural Science Foundation of China (Project 82072072,32261160372,32171326,32371377)the Guangdong Basic and Applied Basic Research Foundation (2022B1515130010,2021A1515111035)Dongguan Science and Technology of Social Development Program (20231800906311,20231800900332).
文摘Thrombosis and infection are two major complications associated with central venous catheters(CVCs),which significantly contribute to morbidity and mortality.Antifouling coating strategies currently represent an efficient approach for addressing such complications.However,existing antifouling coatings have limitations in terms of both duration and effectiveness.Herein,we propose a durable zwitterionic polymer armor for catheters.This armor is realized by pre-coating with a robust phenol-polyamine film inspired by insect sclerotization,followed by grafting of poly-2-methacryloyloxyethyl phosphorylcholine(pMPC)via in-situ radical polymerization.The resulting pMPC coating armor exhibits super-hydrophilicity,thereby forming a highly hydrated shell that effectively prevents bacterial adhesion and inhibits the adsorption and activation of fibrinogen and platelets in vitro.In practical applications,the armored catheters significantly reduced inflammation and prevented biofilm formation in a rat subcutaneous infection model,as well as inhibited thrombus formation in a rabbit jugular vein model.Overall,our robust zwitterionic polymer coating presents a promising solution for reducing infections and thrombosis associated with vascular catheters.
基金This work was supported by the National Natural Science Foundation of China(Project 31570957)the National Key Research and Development Program of China(2017YFB0702504)+1 种基金International Cooperation Project by Science and Technology Department of Sichuan Province(2019YFH0103)Applied Basic Research Project funded by Sichuan Provincial Science and Technology Department(2017JY0296).
文摘Integration of two or more biomolecules with synergetic and complementary effects on a material surface can help to obtain multi-functions for various biomedical applications.However,the amounts of biomolecules integrated and their physiological functions are compromised due to the limited surface anchoring sites.Herein,we propose a novel concept of film engineering strategy“from surface to bulk synergetic modification”.This new concept is realized by employing the surface amine groups of plasma polymerized allylamine(PPAm)film for grafting a molecule e.g.,thrombin inhibitor,bivalirudin(BVLD),meanwhile its bulk amine groups is used as a universal depot for storing and releasing therapeutic nitric oxide(NO)gas as supplement to the functions of BVLD.It is demonstrated that such a“from surface to bulk synergetic modification”film engineering can impart the modified-substrates with anti-platelet and anti-coagulant dual functions,giving rise to a highly endotheliummimetic thromboresistant property.We believe that our research provides a very promising strategy to deliver multifunctional surface versatilely that require NO release in combination with other properties,which will find broad biomedical applications in blood-contacting devices,and et al.Moreover,it also provides a brand-new film engineering strategy for tailoring surface multi-functionalities of a wide range of materials.
基金supported by the Natural Science Foundation of China (No. 21571103)Jiangsu (No. BK20191359)the Project of Natural Science Foundation of the Higher Education Institutions of Anhui Province, China (No. KJ2019A0350)。
文摘The design of assembling high-nuclearity transition-lanthanide(3d-4f) clusters along with excellent magnetocaloric effect(MCE) is one of the most prominent fields but is extremely challenging. Herein, two heterometallic metal coordination polymers are constructed via the “carbonatetemplate” method, formulated as {[Gd_(18)Ni_(24)(IDA)_(22)(CO_(3))_(7)(μ_(3)-OH)_(32)(μ_(2)-OH)_(3)(H_(2)O)_(5)Cl]·Cl_(8)·(H_(2)O)_(14)}nand{[Eu_(18)Ni_(23.5)(IDA)_(22)(CO_(3)_(7)(μ_(3)-OH)_(32)(H_(2)O)_(5)(IN)(CH_(3)COO)_(2)(NH_(2)CH_(2)COO)Cl]·C_(l6)·(H_(2)O)_(17)}n[abbreviated as 1-(Gd_(18)Ni_(24))nand 2-(Eu_(18)Ni_(23.5))n respectively;H_(2)IDA = iminodiacetic acid;HIN = isonicotinic acid]. Concerning the structures, compounds 1-(Gd_(18)Ni_(24))nand 2-(Eu_(18)Ni_(23.5))nboth feature the one-dimensional(1D) chain-like structure which is rarely reported in high-nuclearity metal complexes. Meanwhile, the large presences of Gd3+ ions in compound 1-(Gd18Ni24)nare conducive to the fantastic MCE, and the value of-ΔS_(m)is 35.30 J kg^(-1)K^(-1) at 3.0 K and ΔH = 7.0 T. And more significantly, compound 1-Gd_(18)Ni_(24)n shows the large low-field magnetic entropy change(-ΔS_(m)= 20.95 J kg(-1) K(-1) at 2.0 K and ΔH = 2.0 T)among the published 3 d-4 f mixed metal clusters.
基金supported by Natural Science Foundation of Jiangsu (No. BK20191359)the Natural Science Foundation of China (No. 21571103)the Postgraduate Research & Practice Innovation Program of Jiangsu Province (No. KYCX22_1343)。
文摘Chemical fixation of CO_(2)into C1 source, as a general approach, can effectively alleviate the emission of greenhouse gasses. Whereas, the challenge posed by the need for efficient catalysts with high catalytic active sites still exists. In this work, we reported a series of new hexavanadate clusters, [(C6H6ON)2(C2H8N2)2(CH3O)6VIV6O8](V6–1), [(C6H6ON)2(C3H10N2)2(CH3O)6VIV6O8](V6–2), [(C6H6ON)2(C6H14N2)2(CH3O)6VIV6O8](V6–3) and [(C6H6ON)2(C4H11N2O)2(CH3O)4VIV6O8](V6–4), assembled by 2-aminophenol and four different kinds of Lewis bases(LB), ethanediamine(en), 1,2-diaminopropane, 1,2-cyclohexanediamine and N-(2-hydroxyethyl)ethylenediamine(ben) together. Among them, the basic unit {V6} cluster featured Z-shaped configuration represents a brand-new example of hexanuclear vanadium clusters. Remarkably, the catalytic tests demonstrated that V6–1 as catalyst displays high catalytic activity in the cycloaddition for the CO_(2)fixation into cyclic carbonates by virtue of open V sites. As expected, for oxidative desulfurization of sulfides, V6–1 also exhibits satisfied catalytic effectiveness. Furthermore, the recycling test confirmed that catalyst V6–1 may be a bifunctional heterogeneous catalyst with great promise for both CO_(2)cycloaddition and oxidative desulfurization reactions.
基金funded by the Key Industrial Chain Technology Research Program of Xi’an(24ZDCYJSGG0048)the Key Research and Development Program of Xianyang(L2023-ZDYF-SF-077)the Fundamental Research Funds for the Central Universities in Chang'an University(300102384201).
文摘Batterymanagement systems(BMSs)are essential in ensuring the safe and stable operation of lithium-ion batteries(LIBs)in electric vehicles(EVs).Accurate sensor signals,particularly voltage,current,and temperature sensor signals,are essential for a BMS to performfunctions such as state estimation,balance control,and fault diagnosis.The smooth operation of a BMS depends primarily on sensor signals,which provide current,voltage,and temperature information to maintain the battery pack in a safe running state.However,sensor failures and inaccurate measurement data can easily occur because of external interference and complex operating conditions.Therefore,an investigation into the faultdiagnosis of battery sensors and fault-tolerant control(FTC)is necessary to ensure the normal operation of a BMS.This paper analyzes themodes of sensor faults,fault diagnosismethods,and fault-tolerant control techniques.First,the differentmodes of sensor faults are analyzed,andmathematical expressions for these faults are provided.Second,diagnostic methods for sensor faults based on models,signal processing,and data-drivenmethods are analyzed in detail.Finally,FTC techniques are introduced to ensure stable sensor operation.Based on an analysis of the research status of sensor fault diagnosis,a new development direction for sensor fault diagnosis is proposed.
