In this study,the Stokes formula is used to analyze the separation effect of three-phase separators used in a Oilfield Central Processing Facility.The considered main influencing factors include(but are not limited to...In this study,the Stokes formula is used to analyze the separation effect of three-phase separators used in a Oilfield Central Processing Facility.The considered main influencing factors include(but are not limited to)the typical size of oil and water droplets,the residence time and temperature of fluid and the dosage of demulsifier.Using the“Specification for Oil and Gas Separators”as a basis,the control loops and operating parameters of each separator are optimized Considering the Halfaya Oilfield as a testbed,it is shown that the proposed approach can lead to good results in the production stage.展开更多
The three-phase separator is a critical component of high-rate anaerobic bioreactors due to its significant contribution in separation of biomass,wastewater,and biogas.However,its role in an anaerobic membrane bioreac...The three-phase separator is a critical component of high-rate anaerobic bioreactors due to its significant contribution in separation of biomass,wastewater,and biogas.However,its role in an anaerobic membrane bioreactor is still not clear.In this study,the distinction between an external anaerobic ceramic membrane bioreactor(EAnCMBR)unequipped(R1)and equipped(R2)with a three-phase separator was investigated in terms of treatment performance,membrane fouling,extracellular polymers of sludge,and microbial community structure.The results indicate that the COD removal efficiencies of Rl and R2 were 98.2%±0.4%and 98.1%±0.4%,respectively,but the start-up period of R2 was slightly delayed.Moreover,the membrane fouling rate of R2(0.4 kPa/d)was higher than that of Rl(0.2 kPa/d).Interestingly,the methane leakage from R2(0.1 L/d)was 20 times higher than that from Rl(0.005 L/d).The results demonstrate that the three-phase separator aggravated the membrane fouling rate and methane leakage in the EAnCMBR.Therefore,this study provides a novel perspective on the effects of a three-phase separator in an EAnCMBR.展开更多
Switched-capacitor/flying capacitor(FC)based multilevel converters have been gaining higher attention for their voltage-boosting ability.This feature makes them an attractive solution for renewable energy systems,such...Switched-capacitor/flying capacitor(FC)based multilevel converters have been gaining higher attention for their voltage-boosting ability.This feature makes them an attractive solution for renewable energy systems,such as low-voltage input photovoltaic power systems and electric vehicle systems.However,they usually require more high voltage rating switches and flying capacitors along with boosting capability.Furthermore,they suffer from high pulse currents at the switching transients.Aiming to solve these issues,this article proposes a new self-balancing three-phase five-level inverter based on the switched-capacitor(5L-SCTPNPC),which reduces the dc voltage requirement.The number of active switches is relatively smaller and seven active switches are required per phase.Especially,a soft-charging circuit for FC is designed to limit the impulse charging current.Compared to conventional multilevel inverters,the proposed five-level inverter reduces dc bus voltage by 50%.Significantly,the voltage stress of FC and the switches in parallel with FC are all reduced by 50%in comparison with some existing similar boosting five-level active-neutral-point-clamped(5L-BANPC)inverters.The operating principles,modulation strategy,and the design of the FC and charging inductor are provided in detailly.A comprehensive comparison study has been made to highlight the merits of the proposed inverter.Finally,the simulations and experiments validate the feasibility of the proposed topology.展开更多
Renewable electricity-driven production of value-added sulfur and H_(2)via electrocatalytic H_(2)S decomposition represents a sustainable route to conventional thermocatalysis.Both the electrocatalyst and electrolyte ...Renewable electricity-driven production of value-added sulfur and H_(2)via electrocatalytic H_(2)S decomposition represents a sustainable route to conventional thermocatalysis.Both the electrocatalyst and electrolyte solution strongly impact the H_(2)S decomposition performance.Despite significant progress in developing sophisticated electrocatalysts,a well-designed electrolyte solution in conjunction with industrial catalysts is an attractive strategy to advance the industrialization process of electrocatalytic H_(2)S decomposition,but remains unexplored.Here,for the first time,we design a solid-liquid-gas three-phase indirect electrolysis system based on a kind of CS_(2)-N electrolyte solution and Ni-Mo_(2)C that can efficiently enable H_(2)S decomposition into valuable H_(2)and sulfur.Specifically,the solid-phase Ni-Mo_(2)C as a heterogeneous redox mediator presents excellent electrocatalytic efficiency for the H_(2)S removal efficiency of up to 99%,and the formation of liquid-phase sulfur product(CS_(2)-N electrolyte solution dissolves sulfur,yield up to 95%)with the generation of gas-phase H_(2)product(~1.32 mL min^(-1)),resulting in an interesting three-phase indirect electrolysis system.Remarkably,it enables the scale-up production(~6 g in a batch experiment)of sulfur with continuous operation for 120 h without attenuation.This work may inaugurate a new electrocatalytic H_(2)S decomposition avenue to explore porous metal materials and electrolyte systems in simultaneous production of value-added sulfur and H_(2).展开更多
The transient phenomena of re-oxidation and slag entrapment occurring in the tundish during the ladle change-over process have been proven detrimental to clean steel production.Therefore,an unsteady three-phase turbul...The transient phenomena of re-oxidation and slag entrapment occurring in the tundish during the ladle change-over process have been proven detrimental to clean steel production.Therefore,an unsteady three-phase turbulence model,coupling velocity,temperature,and phase field was established to study the effect of the ladle shroud immersion depth on the slag eye formation,slag entrainment,slag dragging,air dragging,and flow characteristics during the ladle change-over process of a two-strand tundish.The results showed that reducing the immersion depth decreases the high-velocity region area under the slag layer in the quasi-steady process.During the emptying stage,as the molten bath level gradually decreases,the outlet temperature exhibits a trend of initially decreasing and subsequently increasing across all three shroud immersion depths.However,under a 210 mm shroud immersion depth,molten slag and air are dragged into the shroud,forming slag droplets and causing significant fluctuations,with a maximum scalar velocity of 0.0764 m/s at the monitoring point.In the filling stage,air and molten slag are dragged into the molten bath,forming bubbles and slag droplets at an immersion depth of 210 mm.Bubbles are observed within the molten slag layer,which can readily cause an emulsification phenomenon,making it easier to be dragged as slag droplets.Additionally,the slag eye area measured under 210 mm immersion depth at 45 s is 0.303 m^(2),while the maximum scalar velocity of 2.4259 m/s is detected at 12 s.At an immersion depth of 360 mm,the average area of the slag eye is minimized to 0.06268 m2,with corresponding variances of 0.006753,representing the optimal immersion depth.展开更多
Lithium(Li)dendrites,resulting from poor ion desolvation and transport behavior at the anode/electrolyte interface during electrodeposition,severely impede the practicality of Li metal anodes.Inspired by the transmemb...Lithium(Li)dendrites,resulting from poor ion desolvation and transport behavior at the anode/electrolyte interface during electrodeposition,severely impede the practicality of Li metal anodes.Inspired by the transmembrane cascade transport mechanism of biological ion pumps,we design a biomimetic dual-cascade separator(BDS)based on gradient pore core–shell Gd_(2)O_(3)@ZIF-7 nanoparticles to stabilize Li metal anodes.The mesoporous Gd_(2)O_(3)core,via Lewis acidic surface,weakens Li^(+) -solvent interactions,thereby reconstructing the solvation structure and achieving pre-desolvation.The microporous ZIF-7 shell then promotes final desolvation through strong confinement effect and N-rich site coordination,while its nanochannels homogenize Li^(+) transport.This synergistic meso/microporous gradient creates a unique dual-cascade effect for ion desolvation and transport.Consequently,BDS achieves a low desolvation energy barrier,a high Li^(+) transference number(0.71),and dendrite-free Li deposition.The average Coulombic efficiency rises from 72.7%to 98.4%,the cycling performance of the Li||Li symmetrical cell improves by 3.2 times,and the capacity retention of LiFePO_4(LFP)||Li full cell increases from 38.3%to73.4%after 500 cycles.This work offers a novel separator design concept,deepens Li deposition understanding,and guides separators from passive protection to active regulation.展开更多
Lithium-sulfur batteries(LSBs)represent a next-generation energy storage technology,but widespread applications are restricted by the shuttle of lithium polysulfides(LiPSs).The rational design of separators has been d...Lithium-sulfur batteries(LSBs)represent a next-generation energy storage technology,but widespread applications are restricted by the shuttle of lithium polysulfides(LiPSs).The rational design of separators has been demonstrated to be one of the most efficient and cost-effective strategies to curb the shuttle effect,and tremendous research progress has been achieved.The efficiency of a separator depends on its interaction with LiPSs,which is governed by the surface energy and binding strength.Despite several review works that have been reported to advance the separators,most of them primarily focus on active material innovation and construction.The most crucial issues of surface binding energy have not been systematically reviewed,limiting the precise design of efficient separators.In this review,fundamentals related to surface energy and binding interactions with LiPSs are comprehensively analyzed and discussed.With surface binding and energy main lines,the advancements in separator engineering strategies are elaborately summarized and discussed.Moreover,techniques for evaluating affinity to LiPSs are thoroughly analyzed to avoid any ambiguities in measurement.Based on the research context,valuable research directions are suggested to construct efficient separators.This work provides guidelines to regulate the surface binding and energy of separators for high-performance LSBs.展开更多
Traditional fluorination strategies have attracted significant attention due to their ability to construct a fluorine-rich solid-electrolyte interphase(SEI)at the anode-electrolyte interface.However,the inhomogeneous ...Traditional fluorination strategies have attracted significant attention due to their ability to construct a fluorine-rich solid-electrolyte interphase(SEI)at the anode-electrolyte interface.However,the inhomogeneous distribution of LiF within the SEI layer remains a critical challenge that hinders the effective suppression of lithium dendrite growth.This work explores the synergy between HDBDPE(degradation products of decabromodiphenyl ethane)and MgF_(2),developing a fluorinated,flame-retardant separator with optimized ion channels,HDBDPE acts as both a low-toxicity flame retardant and an"F-element guide"through hydrogen bonding with MgF_(2),forming a uniform LiF SEI layer on the Li anode for rapid reaction kinetics.Moreover,under thermal runaway conditions,the MgF_(2)@HDBDPE/PP separator constructs a"high-efficiency flame-retardant barrier",effectively quenching free radicals and promoting the formation of MgBr_(2),thereby suppressing electrolyte combustion.As a result,both symmetric and full cells assembled with the MgF_(2)@HDBDPE/PP separator demonstrate superior cyclic stability and rate performance due to improved interfacial reactions.The MgF_(2)@HDBDPE/PP separator exhibits rapid flame retardancy under thermal runaway conditions.展开更多
The rapid decay of the surface wettability of plasma-treated polymers remains a critical limitation for their practical application in advanced materials.This study introduces a continuous atmospheric pressure plasma(...The rapid decay of the surface wettability of plasma-treated polymers remains a critical limitation for their practical application in advanced materials.This study introduces a continuous atmospheric pressure plasma(APP)technique for fabricating polyethylene(PE)separators with durable wettability,and elucidates the underlying mechanism.A systematic comparison of APP treatments with non-deposition and deposition gases,including Ar,Ar/O_(2),Ar/tetramethylcyclotetrasiloxane(TMCTS),and Ar/O_(2)/TMCTS,revealed the key impact factors in achieving durable wettability.Owing to the synergistic interactions of SiO_(x)C_(y)H_(z)nanoparticulate deposition,physical etching,and oxidative functionalization,the PE separator treated by Ar/O_(2)/TMCTS exhibited a 17.5-fold electrolyte wetting area compared to the original one.The improved surface energy and roughness of the SiO_(x)C_(y)H_(z)nanoparticle coating enhanced its electrochemical performance.The ionic conductivity increased by 1.9 times,while the charge transfer resistance decreased by 73.7%.Remarkably,owing to further oxidation of the SiO_(x)C_(y)H_(z)nanoparticle coating and the increase in its silica-like structure,the wetting area of the Ar/O_(2)/TMCTS-treated separator was still over 14-fold larger than that of the original separator after aging for 90 days.This study demonstrates an eco-friendly and scalable approach for fabricating high-performance battery separators and provides mechanistic insights into durable wettability by APP.展开更多
Zn-I_(2) batteries have emerged as promising next-generation energy storage systems owing to their inherent safety,environmental compatibility,rapid reaction kinetics,and small voltage hysteresis.Nevertheless,two crit...Zn-I_(2) batteries have emerged as promising next-generation energy storage systems owing to their inherent safety,environmental compatibility,rapid reaction kinetics,and small voltage hysteresis.Nevertheless,two critical challenges,i.e.,zinc dendrite growth and polyiodide shuttle effect,severely impede their commercial viability.To conquer these limitations,this study develops a multifunctional separator fabricated from straw-derived carboxylated nanocellulose,with its negative charge density further reinforced by anionic polyacrylamide incorporation.This modification simultaneously improves the separator’s mechanical properties,ionic conductivity,and Zn^(2+)ion transfer number.Remarkably,despite its ultrathin 20μm profile,the engineered separator demonstrates exceptional dendrite suppression and parasitic reaction inhibition,enabling Zn//Zn symmetric cells to achieve impressive cycle life(>1800 h at 2 m A cm^(-2)/2 m Ah cm^(-2))while maintaining robust performance even at ultrahigh areal capacities(25 m Ah cm^(-2)).Additionally,the separator’s anionic characteristic effectively blocks polyiodide migration through electrostatic repulsion,yielding Zn-I_(2) batteries with outstanding rate capability(120.7 m Ah g^(-1)at 5 A g^(-1))and excellent cyclability(94.2%capacity retention after 10,000 cycles).And superior cycling stability can still be achieved under zinc-deficient condition and pouch cell configuration.This work establishes a new paradigm for designing high-performance zinc-based energy storage systems through rational separator engineering.展开更多
Aqueous zinc-based batteries have emerged as promising candidates for large-scale energy storage owing to their inherent safety and cost-effectiveness.However,their widespread application is impeded by dendritic forma...Aqueous zinc-based batteries have emerged as promising candidates for large-scale energy storage owing to their inherent safety and cost-effectiveness.However,their widespread application is impeded by dendritic formation and parasitic reactions at zinc anodes.To address these issues,this study employs polyethyleneimine grafting and macropore filling to synergistically modify the cellulose separator.The zincophilic–NH_(2) and–NH–groups introduced by polyethyleneimine promote Zn^(2+)ion desolvation and nucleation processes.Concurrently,the nanocellulose incorporated into macropores not only significantly enhances mechanical properties but also compensates for macroporous defects within the cellulose separator.The optimized separator exhibits ultralow thickness(18μm),ultrahigh modulus(3.2 GPa),large ionic conductivity(19.0 mS cm^(-1)),high Zn^(2+)ion transfer number(0.63),and good biodegradability.Comprehensive experimental measurements and theoretical analysis reveal that the utilization of this separator contributes to significantly suppressed zinc dendrites and improved electrochemical kinetics.The assembled Zn//Zn cell demonstrates exceptional cycling stability(over 1000 h lifespan at10 m A cm^(-2)and 2 mAh cm^(-2)),and the Zn//MnO_(2) and Zn//I_(2) full batteries maintain excellent longterm cyclability under high cathode mass loadings.This work advances our understanding of multifunctional separator design for next-generation electrochemical energy storage systems.展开更多
The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms stil...The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms still face challenges in simultaneously improving the ion transport efficiency and thermal stability.Here,we report an in situ dynamic lithium compensation strategy for manufacturing a biobased furan aramid/ceramic diaphragm(BAS)with higher thermal stability and ion transport efficiency.Specifically,exchangeable carboxyl groups(–COOH)are introduced into the bio-based furan aramid(BA)framework,which are in situ converted into–COOLi groups to form lithium ions(Li^(+))transport channels,achieving dynamic compensation of active Li^(+).The dual transmission system of ion exchange and physical pore channels synergistically enhances the ionic conductivity of BAS to 1.536 mS cm^(-1).The high polarity structure of the furan ring and the electrolyte have excellent compatibility,significantly reducing the solid–liquid interfacial energy,making BAS have extremely high electrolyte wettability(contact angle of 0°).The BA amide group forms a multi-scale bonding network with the nano-ceramics.The BAS prepared by the water-coating process exhibits excellent thermal stability(with a thermal shrinkage rate of less than 1%after 1 h at 150℃).The LiFePO_(4)|Li half-cell assembled with BAS shows a capacity retention rate of up to 91.7%after 280 cycles at 1C,with a Coulomb efficiency of 99%,demonstrating excellent cycling stability.This design and development based on bio-materials provides a new approach for high safety and high energy density battery systems.展开更多
Aqueous zinc ion batteries(AZIBs)are considered promising candidates owing to their inherent safety and low cost.However,the conventional glass fiber(GF)separator used in AZIBs suffers from poor physicochemical proper...Aqueous zinc ion batteries(AZIBs)are considered promising candidates owing to their inherent safety and low cost.However,the conventional glass fiber(GF)separator used in AZIBs suffers from poor physicochemical properties,leading to uncontrolled zinc(Zn)dendrite formation and undesirable side reactions.To address these limitations and enhance the electrochemical performance of AZIBs,a precisely designed functional separator is developed by incorporating UiO-66-(COOH)_(2)into a poly(vinylidene fluoride)(PVDF)framework(U-PVDF)via a direct in situ growth method.This approach enables uniform distribution of UiO-66-(COOH)_(2)both on the surface and within the PVDF backbone,without increasing separator thickness.Owing to the strong interaction between Zn^(2+)and the abundant carboxyl groups in UiO-66-(COOH)_(2),the U-PVDF separator regulates the Zn^(2+)solvation structure toward a contact ion pair-dominated structure by reducing coordinated water molecules,which effectively mitigates water-induced parasitic reactions and promotes compact Zn deposition.Consequently,a Zn/Zn symmetric cell employing the U-PVDF separator demonstrates superior cycling stability over 1500 cycles without internal short-circuiting at a current density of 6 mA cm^(−2)and an areal capacity of 2 mAh cm^(−2).Moreover,Zn/NaV_(3)O_(8)·xH_(2)O(NVO)cell with the U-PVDF separator exhibits markedly improved cyclability and rate performance compared with those using conventional GF separator.展开更多
Three-phase centrifuge was used to process oily sludge,and the requirement of mud,oil and water three-phase separation was satisfied through the optimization of parameters. The results showed that when the input quant...Three-phase centrifuge was used to process oily sludge,and the requirement of mud,oil and water three-phase separation was satisfied through the optimization of parameters. The results showed that when the input quantity was lower than 5 m^3/h,the optimal operation parameters of the three-phase centrifuge are shown as follows: the frequency of the main motor and vice motor was 33 and 30 Hz respectively,and the flocculant flow was 0. 7 m^3/h,while the oily sludge temperature was 55 ℃. Water content in the separated sludge decreased from 98% to lower than 70%,and the goal of reduction and harmless treatment of oily sludge could be achieved,which could provide essential conditions for subsequent resource utilization and could be used to guide industrial production.展开更多
The growing demands for energy storage systems,electric vehicles,and portable electronics have significantly pushed forward the need for safe and reliable lithium batteries.It is essential to design functional separat...The growing demands for energy storage systems,electric vehicles,and portable electronics have significantly pushed forward the need for safe and reliable lithium batteries.It is essential to design functional separators with improved mechanical and electrochemical characteristics.This review covers the improved mechanical and electrochemical performances as well as the advancements made in the design of separators utilizing a variety of techniques.In terms of electrolyte wettability and adhesion of the coating materials,we provide an overview of the current status of research on coated separators,in situ modified separators,and grafting modified separators,and elaborate additional performance parameters of interest.The characteristics of inorganics coated separators,organic framework coated separators and inorganic-organic coated separators from different fabrication methods are compared.Future directions regarding new modified materials,manufacturing process,quantitative analysis of adhesion and so on are proposed toward next-generation advanced lithium batteries.展开更多
The thermal stability of lithium-ion battery separators is a critical determinant of battery safety and performance,especially in the context of rapidly expanding applications in electric vehicles and energy storage s...The thermal stability of lithium-ion battery separators is a critical determinant of battery safety and performance,especially in the context of rapidly expanding applications in electric vehicles and energy storage systems.While traditional polyolefin separators(PP/PE)dominate the market due to their cost-effectiveness and mechanical robustness,their inherent poor thermal stability poses significant safety risks under high-temperature conditions.This review provides a comprehensive analysis of recent advancements in enhancing separator thermal stability through coating materials(metal,ceramic,inorganic)and novel high-temperature-resistant polymers(e.g.,PVDF copolymers,PI,PAN).Notably,we critically evaluate the trade-offs between thermal resilience and electrochemical performance,such as the unintended increase in electronic conductivity from metal coatings(e.g.,Cu,MOFs)and reduced electrolyte wettability in ceramic coatings(e.g.,Al_(2)O_(3)).Innovations in hybrid coatings(e.g.,BN/PAN composites,gradient-structured MOFs)and scalable manufacturing techniques(e.g.,roll-to-roll electrospinning)are highlighted as promising strategies to balance these competing demands.Furthermore,a comparative analysis of next-generation high-temperature-resistant separators underscores their ionic conductivity,mechanical strength,and scalability,offering actionable insights for material selection.The review concludes with forward-looking perspectives on integrating machine learning for material discovery,optimizing interfacial adhesion in ceramic coatings,and advancing semi-/all-solid-state batteries to address both thermal and electrochemical challenges.This work aims to bridge the gap between laboratory innovations and industrial applications,fostering safer and more efficient lithium battery technologies.展开更多
Shuttle effect of polysulfides overshadows the superiorities of lithium-sulfur batteries.Size-sieving effect could address this thorny trouble rely on size differ in polysulfides and lithium ions.However,clogged polys...Shuttle effect of polysulfides overshadows the superiorities of lithium-sulfur batteries.Size-sieving effect could address this thorny trouble rely on size differ in polysulfides and lithium ions.However,clogged polysulfides pose some challenges for cathode and are rarely recycled during charging/discharging.Herein,an amino functionalized titanium-organic framework is designed for modifying lithium-sulfur batteries separator to address the aforementioned challenges.Wherein,the introduction of amino narrows titanium-organic framework pore size,enabling functional separator to selectively modulate lithium ions and polysulfides migration using size-sieving effect,thereby completely suppressing polysulfides shuttle.Furthermore,the blocked polysulfides will be adsorbed on the separator surface by positively charged amino leveraging electrostatic adsorption,ensuring polysulfides to redistribute and reuse,and boosting active materials utilization.Significantly,the migration of lithium ions is not hindered since there are lithium ions transfer channels formed via Lewis acid-base interaction with the help of amino.Combined with these virtues,the lithium-sulfur batteries with amino functionalized titanium-organic framework modified separator enjoy an ultralow attenuation rate of 0.045%per cycle over 1000 cycles at 1.0C.Electrostatic adsorption and Lewis acid-base interaction cover deficiencies existing in the inhibition of polysulfides shuttle by size-sieving effect,providing fresh insight into the advancement of lithium-sulfur batteries.展开更多
Separator modification is an effective approach to suppress dendrite growth to realize high-energy sodium metal batteries(SMBs)in practical applications,however,its success is mainly subject to surface modification.He...Separator modification is an effective approach to suppress dendrite growth to realize high-energy sodium metal batteries(SMBs)in practical applications,however,its success is mainly subject to surface modification.Herein,a separator with multifunctional layers composed of N-doped mesoporous hollow carbon spheres(HCS)as the inner layer and sodium fluoride(NaF)as the outer layer on commercial polypropylene separator(PP)is proposed(PP@HCS-NaF)to achieve stable cycling in SMB.At the molecular level,the inner HCS layer with a high content of pyrrolic-N induces the uniform Na^(+)flux as a potential Na^(+)redistributor for homogenous deposition,whereas its hollow mesoporous structure offers nanoporous buffers and ion channels to regulate Na^(+)ion distribution and uniform deposition.The outer layer(NaF)constructs the NaF-enriched robust solid electrolyte interphase layer,significantly lowering the Na^(+)ions diffusion barrier.Benefiting from these merits,higher electrochemical performances are achieved with multifunctional double-layered PP@HCS-NaF separators compared with single-layered separators(i.e.PP@HCS or PP@NaF)in SMBs.The Na‖Cu half-cell with PP@HCS-NaF offers stable cycling(280 cycles)with a high CE(99.6%),and Na‖Na symmetric cells demonstrate extended lifespans for over 6000 h at 1 mA cm^(-2)with a progressively stable overpotential of 9 mV.Remarkably,in Na‖NVP full-cells,the PP@HCS-NaF separator grants a stable capacity of~81 mA h g^(-1)after 3500 cycles at 1 C and an impressive rate capability performance(~70 mA h g^(-1)at 15 C).展开更多
Lithium-sulfur batteries(LSBs)have attracted widespread attention due to their high theoretical energy density.However,the dissolution of long-chain polysulfides into the electrolyte(the“shuttle effect”)leads to rap...Lithium-sulfur batteries(LSBs)have attracted widespread attention due to their high theoretical energy density.However,the dissolution of long-chain polysulfides into the electrolyte(the“shuttle effect”)leads to rapid capacity decay.Therefore,finding suitable materials to mitigate the shuttle effect of polysulfides is crucial for enhancing the electrochemical performance of lithium-sulfur batteries.In this study,LSBs’separator is modified with Ni_(3)V_(2)O_(8)nanoparticles@carboxylated carbon nanotubes(Ni_(3)V_(2)O_(8)@CNTs)composite.There are abundant oxygen vacancies in Ni_(3)V_(2)O_(8)@CNTs composite which plays a synergistic effect on shuttle effect.The Ni_(3)V_(2)O_(8)can tightly anchor soluble polysulfides through oxygen vacancies,while the CNTs not only facilitate the transport of ions and electrons but also weaken the migration of polysulfides,limiting shuttle effect.As a result,the cycling stability of LSBs using Ni_(3)V_(2)O_(8)@CNTs-modified separator has been significantly improved(with a capacity decay rate of only 0.0334%after 1500 cycles at 4.0C).This study proposes a strategy to design modified separator for high-performance LSBs.展开更多
To achieve high power rating and low current harmonics of motor drive,this paper develops a dual three-phase open-winding permanent magnet synchronous motor(DTP-OW-PMSM)drive with the DC-link voltage ratio of 2:1:1.Ba...To achieve high power rating and low current harmonics of motor drive,this paper develops a dual three-phase open-winding permanent magnet synchronous motor(DTP-OW-PMSM)drive with the DC-link voltage ratio of 2:1:1.Based on this topology,this paper proposes a DTP four-level space vector pulse width modulation(DTP-FL SVPWM)strategy.First,two identical three-phase four-level space vector diagrams are constructed and divided.Then,three adjacent vectors nearest to the reference vector in each diagram are selected for the vector synthesis to guarantee high modulation precision and low switching frequency.Furthermore,to avoid the modulation error caused by the voltage deviation,the proposed DTP-FL SVPWM strategy is further optimized through unified duty ratio compensation(UDRC).The effectiveness of the proposed strategy is verified through experiments.展开更多
基金This study was supported by the Natural Science Foundation of Shandong Province(Grant No.ZR2021QE030).
文摘In this study,the Stokes formula is used to analyze the separation effect of three-phase separators used in a Oilfield Central Processing Facility.The considered main influencing factors include(but are not limited to)the typical size of oil and water droplets,the residence time and temperature of fluid and the dosage of demulsifier.Using the“Specification for Oil and Gas Separators”as a basis,the control loops and operating parameters of each separator are optimized Considering the Halfaya Oilfield as a testbed,it is shown that the proposed approach can lead to good results in the production stage.
基金supported by the National Natural Science Foundation of China(Grant No.51878232)Science and technology project of Anhui provincial housing and urban rural development office(No.2017YF-05)CAS Key Laboratory of Urban Pollutant Conversion,University of Science and Technology of China(No.KF201702).
文摘The three-phase separator is a critical component of high-rate anaerobic bioreactors due to its significant contribution in separation of biomass,wastewater,and biogas.However,its role in an anaerobic membrane bioreactor is still not clear.In this study,the distinction between an external anaerobic ceramic membrane bioreactor(EAnCMBR)unequipped(R1)and equipped(R2)with a three-phase separator was investigated in terms of treatment performance,membrane fouling,extracellular polymers of sludge,and microbial community structure.The results indicate that the COD removal efficiencies of Rl and R2 were 98.2%±0.4%and 98.1%±0.4%,respectively,but the start-up period of R2 was slightly delayed.Moreover,the membrane fouling rate of R2(0.4 kPa/d)was higher than that of Rl(0.2 kPa/d).Interestingly,the methane leakage from R2(0.1 L/d)was 20 times higher than that from Rl(0.005 L/d).The results demonstrate that the three-phase separator aggravated the membrane fouling rate and methane leakage in the EAnCMBR.Therefore,this study provides a novel perspective on the effects of a three-phase separator in an EAnCMBR.
基金supported by the National Natural Science Foundation of China(51977069)the National Natural Science Foundation Youth Project of China(52107195)the First Key Research and JieBang Headed Program,Hunan Province,China(2021GK1250).
文摘Switched-capacitor/flying capacitor(FC)based multilevel converters have been gaining higher attention for their voltage-boosting ability.This feature makes them an attractive solution for renewable energy systems,such as low-voltage input photovoltaic power systems and electric vehicle systems.However,they usually require more high voltage rating switches and flying capacitors along with boosting capability.Furthermore,they suffer from high pulse currents at the switching transients.Aiming to solve these issues,this article proposes a new self-balancing three-phase five-level inverter based on the switched-capacitor(5L-SCTPNPC),which reduces the dc voltage requirement.The number of active switches is relatively smaller and seven active switches are required per phase.Especially,a soft-charging circuit for FC is designed to limit the impulse charging current.Compared to conventional multilevel inverters,the proposed five-level inverter reduces dc bus voltage by 50%.Significantly,the voltage stress of FC and the switches in parallel with FC are all reduced by 50%in comparison with some existing similar boosting five-level active-neutral-point-clamped(5L-BANPC)inverters.The operating principles,modulation strategy,and the design of the FC and charging inductor are provided in detailly.A comprehensive comparison study has been made to highlight the merits of the proposed inverter.Finally,the simulations and experiments validate the feasibility of the proposed topology.
基金supported by the National Natural Science Foundation of China(No.22278439 and 21776313).
文摘Renewable electricity-driven production of value-added sulfur and H_(2)via electrocatalytic H_(2)S decomposition represents a sustainable route to conventional thermocatalysis.Both the electrocatalyst and electrolyte solution strongly impact the H_(2)S decomposition performance.Despite significant progress in developing sophisticated electrocatalysts,a well-designed electrolyte solution in conjunction with industrial catalysts is an attractive strategy to advance the industrialization process of electrocatalytic H_(2)S decomposition,but remains unexplored.Here,for the first time,we design a solid-liquid-gas three-phase indirect electrolysis system based on a kind of CS_(2)-N electrolyte solution and Ni-Mo_(2)C that can efficiently enable H_(2)S decomposition into valuable H_(2)and sulfur.Specifically,the solid-phase Ni-Mo_(2)C as a heterogeneous redox mediator presents excellent electrocatalytic efficiency for the H_(2)S removal efficiency of up to 99%,and the formation of liquid-phase sulfur product(CS_(2)-N electrolyte solution dissolves sulfur,yield up to 95%)with the generation of gas-phase H_(2)product(~1.32 mL min^(-1)),resulting in an interesting three-phase indirect electrolysis system.Remarkably,it enables the scale-up production(~6 g in a batch experiment)of sulfur with continuous operation for 120 h without attenuation.This work may inaugurate a new electrocatalytic H_(2)S decomposition avenue to explore porous metal materials and electrolyte systems in simultaneous production of value-added sulfur and H_(2).
基金supported by the National Natural Science Foundation of China(Nos.52422408 and 52171031)the Liaoning Xingliao Talents-Top-notch Young Talents Project(No.XLYC2203064)+1 种基金the Excellent Youth Fund of Liaoning Natural Science Foundation(No.2023JH3/10200001)the Fundamental Research Funds for the Central Universities(No.N2425004).
文摘The transient phenomena of re-oxidation and slag entrapment occurring in the tundish during the ladle change-over process have been proven detrimental to clean steel production.Therefore,an unsteady three-phase turbulence model,coupling velocity,temperature,and phase field was established to study the effect of the ladle shroud immersion depth on the slag eye formation,slag entrainment,slag dragging,air dragging,and flow characteristics during the ladle change-over process of a two-strand tundish.The results showed that reducing the immersion depth decreases the high-velocity region area under the slag layer in the quasi-steady process.During the emptying stage,as the molten bath level gradually decreases,the outlet temperature exhibits a trend of initially decreasing and subsequently increasing across all three shroud immersion depths.However,under a 210 mm shroud immersion depth,molten slag and air are dragged into the shroud,forming slag droplets and causing significant fluctuations,with a maximum scalar velocity of 0.0764 m/s at the monitoring point.In the filling stage,air and molten slag are dragged into the molten bath,forming bubbles and slag droplets at an immersion depth of 210 mm.Bubbles are observed within the molten slag layer,which can readily cause an emulsification phenomenon,making it easier to be dragged as slag droplets.Additionally,the slag eye area measured under 210 mm immersion depth at 45 s is 0.303 m^(2),while the maximum scalar velocity of 2.4259 m/s is detected at 12 s.At an immersion depth of 360 mm,the average area of the slag eye is minimized to 0.06268 m2,with corresponding variances of 0.006753,representing the optimal immersion depth.
基金the financial support from the National Natural Science Foundation of China(22408182)the Young Talents of Science and Technology in Universities of Inner Mongolia Autonomous Region(NJYT24024)the Natural Science Foundation of Inner Mongolia Autonomous Region(2023QN02007 and 2025QN02009)。
文摘Lithium(Li)dendrites,resulting from poor ion desolvation and transport behavior at the anode/electrolyte interface during electrodeposition,severely impede the practicality of Li metal anodes.Inspired by the transmembrane cascade transport mechanism of biological ion pumps,we design a biomimetic dual-cascade separator(BDS)based on gradient pore core–shell Gd_(2)O_(3)@ZIF-7 nanoparticles to stabilize Li metal anodes.The mesoporous Gd_(2)O_(3)core,via Lewis acidic surface,weakens Li^(+) -solvent interactions,thereby reconstructing the solvation structure and achieving pre-desolvation.The microporous ZIF-7 shell then promotes final desolvation through strong confinement effect and N-rich site coordination,while its nanochannels homogenize Li^(+) transport.This synergistic meso/microporous gradient creates a unique dual-cascade effect for ion desolvation and transport.Consequently,BDS achieves a low desolvation energy barrier,a high Li^(+) transference number(0.71),and dendrite-free Li deposition.The average Coulombic efficiency rises from 72.7%to 98.4%,the cycling performance of the Li||Li symmetrical cell improves by 3.2 times,and the capacity retention of LiFePO_4(LFP)||Li full cell increases from 38.3%to73.4%after 500 cycles.This work offers a novel separator design concept,deepens Li deposition understanding,and guides separators from passive protection to active regulation.
基金supported by the National Natural Science Foundation of China (52172228)the Natural Science Foundation of Fujian Province (2024J01475 and 2023J05127)
文摘Lithium-sulfur batteries(LSBs)represent a next-generation energy storage technology,but widespread applications are restricted by the shuttle of lithium polysulfides(LiPSs).The rational design of separators has been demonstrated to be one of the most efficient and cost-effective strategies to curb the shuttle effect,and tremendous research progress has been achieved.The efficiency of a separator depends on its interaction with LiPSs,which is governed by the surface energy and binding strength.Despite several review works that have been reported to advance the separators,most of them primarily focus on active material innovation and construction.The most crucial issues of surface binding energy have not been systematically reviewed,limiting the precise design of efficient separators.In this review,fundamentals related to surface energy and binding interactions with LiPSs are comprehensively analyzed and discussed.With surface binding and energy main lines,the advancements in separator engineering strategies are elaborately summarized and discussed.Moreover,techniques for evaluating affinity to LiPSs are thoroughly analyzed to avoid any ambiguities in measurement.Based on the research context,valuable research directions are suggested to construct efficient separators.This work provides guidelines to regulate the surface binding and energy of separators for high-performance LSBs.
基金financially supported by the National Natural Science Foundation of China(52401283)National Natural Science Foundation of Jiangsu Province(BK20230933)+1 种基金Fundamental Research Funds for the Central Universities(No.30925010524)Young Faculty Development Fund of Nanjing University of Science and Technology。
文摘Traditional fluorination strategies have attracted significant attention due to their ability to construct a fluorine-rich solid-electrolyte interphase(SEI)at the anode-electrolyte interface.However,the inhomogeneous distribution of LiF within the SEI layer remains a critical challenge that hinders the effective suppression of lithium dendrite growth.This work explores the synergy between HDBDPE(degradation products of decabromodiphenyl ethane)and MgF_(2),developing a fluorinated,flame-retardant separator with optimized ion channels,HDBDPE acts as both a low-toxicity flame retardant and an"F-element guide"through hydrogen bonding with MgF_(2),forming a uniform LiF SEI layer on the Li anode for rapid reaction kinetics.Moreover,under thermal runaway conditions,the MgF_(2)@HDBDPE/PP separator constructs a"high-efficiency flame-retardant barrier",effectively quenching free radicals and promoting the formation of MgBr_(2),thereby suppressing electrolyte combustion.As a result,both symmetric and full cells assembled with the MgF_(2)@HDBDPE/PP separator demonstrate superior cyclic stability and rate performance due to improved interfacial reactions.The MgF_(2)@HDBDPE/PP separator exhibits rapid flame retardancy under thermal runaway conditions.
基金supported by the National Natural Science Foundation of China(No.12075054)the Fundamental Research Funds for the Central Universities(No.CUSF-DH-T-2024069)。
文摘The rapid decay of the surface wettability of plasma-treated polymers remains a critical limitation for their practical application in advanced materials.This study introduces a continuous atmospheric pressure plasma(APP)technique for fabricating polyethylene(PE)separators with durable wettability,and elucidates the underlying mechanism.A systematic comparison of APP treatments with non-deposition and deposition gases,including Ar,Ar/O_(2),Ar/tetramethylcyclotetrasiloxane(TMCTS),and Ar/O_(2)/TMCTS,revealed the key impact factors in achieving durable wettability.Owing to the synergistic interactions of SiO_(x)C_(y)H_(z)nanoparticulate deposition,physical etching,and oxidative functionalization,the PE separator treated by Ar/O_(2)/TMCTS exhibited a 17.5-fold electrolyte wetting area compared to the original one.The improved surface energy and roughness of the SiO_(x)C_(y)H_(z)nanoparticle coating enhanced its electrochemical performance.The ionic conductivity increased by 1.9 times,while the charge transfer resistance decreased by 73.7%.Remarkably,owing to further oxidation of the SiO_(x)C_(y)H_(z)nanoparticle coating and the increase in its silica-like structure,the wetting area of the Ar/O_(2)/TMCTS-treated separator was still over 14-fold larger than that of the original separator after aging for 90 days.This study demonstrates an eco-friendly and scalable approach for fabricating high-performance battery separators and provides mechanistic insights into durable wettability by APP.
基金the financial support from the Natural Science Foundation of Jiangsu Province(BK20231292)the Jiangsu Agricultural Science and Technology Innovation Fund(CX(24)3091)+6 种基金the Postgraduate Research&Practice Innovation Program of Jiangsu Province(KYCX25_1429)the National Key R&D Program of China(2024YFE0109200)the Fundamental Research Funds for the Central Universities(No.2024300440)Guangdong Basic and Applied Basic Research Foundation(2025A1515011098)the National Natural Science Foundation of China(12464032)the Natural Science Foundation of Jiangxi Province(20232BAB201032)Ji'an Science and Technology Plan Project(2024H-100301)。
文摘Zn-I_(2) batteries have emerged as promising next-generation energy storage systems owing to their inherent safety,environmental compatibility,rapid reaction kinetics,and small voltage hysteresis.Nevertheless,two critical challenges,i.e.,zinc dendrite growth and polyiodide shuttle effect,severely impede their commercial viability.To conquer these limitations,this study develops a multifunctional separator fabricated from straw-derived carboxylated nanocellulose,with its negative charge density further reinforced by anionic polyacrylamide incorporation.This modification simultaneously improves the separator’s mechanical properties,ionic conductivity,and Zn^(2+)ion transfer number.Remarkably,despite its ultrathin 20μm profile,the engineered separator demonstrates exceptional dendrite suppression and parasitic reaction inhibition,enabling Zn//Zn symmetric cells to achieve impressive cycle life(>1800 h at 2 m A cm^(-2)/2 m Ah cm^(-2))while maintaining robust performance even at ultrahigh areal capacities(25 m Ah cm^(-2)).Additionally,the separator’s anionic characteristic effectively blocks polyiodide migration through electrostatic repulsion,yielding Zn-I_(2) batteries with outstanding rate capability(120.7 m Ah g^(-1)at 5 A g^(-1))and excellent cyclability(94.2%capacity retention after 10,000 cycles).And superior cycling stability can still be achieved under zinc-deficient condition and pouch cell configuration.This work establishes a new paradigm for designing high-performance zinc-based energy storage systems through rational separator engineering.
基金the financial support from the Natural Science Foundation of Jiangsu Province(BK20231292)the Jiangsu Agricultural Science and Technology Innovation Fund(CX(24)3091)+7 种基金the National Key R&D Program of China(2024YFE0109200)the Fundamental Research Funds for the Central Universities(No.2024300440)the Guangdong Basic and Applied Basic Research Foundation(2025A1515011098)the Postgraduate Research&Practice Innovation Program of Jiangsu Province(KYCX24_1299)the National Natural Science Foundation of China(12464032)the Natural Science Foundation of Jiangxi Province(20232BAB201032)the Ji’an Science and Technology Plan Project(2024H-100301)supported by the high-performance computing campus level public platform of Jinggangshan University。
文摘Aqueous zinc-based batteries have emerged as promising candidates for large-scale energy storage owing to their inherent safety and cost-effectiveness.However,their widespread application is impeded by dendritic formation and parasitic reactions at zinc anodes.To address these issues,this study employs polyethyleneimine grafting and macropore filling to synergistically modify the cellulose separator.The zincophilic–NH_(2) and–NH–groups introduced by polyethyleneimine promote Zn^(2+)ion desolvation and nucleation processes.Concurrently,the nanocellulose incorporated into macropores not only significantly enhances mechanical properties but also compensates for macroporous defects within the cellulose separator.The optimized separator exhibits ultralow thickness(18μm),ultrahigh modulus(3.2 GPa),large ionic conductivity(19.0 mS cm^(-1)),high Zn^(2+)ion transfer number(0.63),and good biodegradability.Comprehensive experimental measurements and theoretical analysis reveal that the utilization of this separator contributes to significantly suppressed zinc dendrites and improved electrochemical kinetics.The assembled Zn//Zn cell demonstrates exceptional cycling stability(over 1000 h lifespan at10 m A cm^(-2)and 2 mAh cm^(-2)),and the Zn//MnO_(2) and Zn//I_(2) full batteries maintain excellent longterm cyclability under high cathode mass loadings.This work advances our understanding of multifunctional separator design for next-generation electrochemical energy storage systems.
基金the financial support from the National Natural Science Foundation of China(22293011,T2341001)the Major Science and Technology Project of Anhui Province(202203a06020010)+1 种基金the Horizontal Project Provided by Jiangsu Zhuogao New Materials Technology Co.,Ltd.(Td00923003H)Joint Laboratory by China Power Investment Ronghe New Energy Technology Co.,Ltd.and the Central Government Guiding Special Fund Project for Local Science and Technology Development(202407a12020008)。
文摘The structural design and performance characteristics of the diaphragm have a decisive impact on the safety and electrochemical performance of lithium-ion batteries(LIBs).However,traditional polyolefin diaphragms still face challenges in simultaneously improving the ion transport efficiency and thermal stability.Here,we report an in situ dynamic lithium compensation strategy for manufacturing a biobased furan aramid/ceramic diaphragm(BAS)with higher thermal stability and ion transport efficiency.Specifically,exchangeable carboxyl groups(–COOH)are introduced into the bio-based furan aramid(BA)framework,which are in situ converted into–COOLi groups to form lithium ions(Li^(+))transport channels,achieving dynamic compensation of active Li^(+).The dual transmission system of ion exchange and physical pore channels synergistically enhances the ionic conductivity of BAS to 1.536 mS cm^(-1).The high polarity structure of the furan ring and the electrolyte have excellent compatibility,significantly reducing the solid–liquid interfacial energy,making BAS have extremely high electrolyte wettability(contact angle of 0°).The BA amide group forms a multi-scale bonding network with the nano-ceramics.The BAS prepared by the water-coating process exhibits excellent thermal stability(with a thermal shrinkage rate of less than 1%after 1 h at 150℃).The LiFePO_(4)|Li half-cell assembled with BAS shows a capacity retention rate of up to 91.7%after 280 cycles at 1C,with a Coulomb efficiency of 99%,demonstrating excellent cycling stability.This design and development based on bio-materials provides a new approach for high safety and high energy density battery systems.
基金supported by the Basic Science Research Program(RS-2024-00455177)through the National Research Foundation of Korea(NRF)funded by the Ministry of Science,ICT.
文摘Aqueous zinc ion batteries(AZIBs)are considered promising candidates owing to their inherent safety and low cost.However,the conventional glass fiber(GF)separator used in AZIBs suffers from poor physicochemical properties,leading to uncontrolled zinc(Zn)dendrite formation and undesirable side reactions.To address these limitations and enhance the electrochemical performance of AZIBs,a precisely designed functional separator is developed by incorporating UiO-66-(COOH)_(2)into a poly(vinylidene fluoride)(PVDF)framework(U-PVDF)via a direct in situ growth method.This approach enables uniform distribution of UiO-66-(COOH)_(2)both on the surface and within the PVDF backbone,without increasing separator thickness.Owing to the strong interaction between Zn^(2+)and the abundant carboxyl groups in UiO-66-(COOH)_(2),the U-PVDF separator regulates the Zn^(2+)solvation structure toward a contact ion pair-dominated structure by reducing coordinated water molecules,which effectively mitigates water-induced parasitic reactions and promotes compact Zn deposition.Consequently,a Zn/Zn symmetric cell employing the U-PVDF separator demonstrates superior cycling stability over 1500 cycles without internal short-circuiting at a current density of 6 mA cm^(−2)and an areal capacity of 2 mAh cm^(−2).Moreover,Zn/NaV_(3)O_(8)·xH_(2)O(NVO)cell with the U-PVDF separator exhibits markedly improved cyclability and rate performance compared with those using conventional GF separator.
文摘Three-phase centrifuge was used to process oily sludge,and the requirement of mud,oil and water three-phase separation was satisfied through the optimization of parameters. The results showed that when the input quantity was lower than 5 m^3/h,the optimal operation parameters of the three-phase centrifuge are shown as follows: the frequency of the main motor and vice motor was 33 and 30 Hz respectively,and the flocculant flow was 0. 7 m^3/h,while the oily sludge temperature was 55 ℃. Water content in the separated sludge decreased from 98% to lower than 70%,and the goal of reduction and harmless treatment of oily sludge could be achieved,which could provide essential conditions for subsequent resource utilization and could be used to guide industrial production.
基金the Center of Lithium Battery Membrane Materials jointly established by School of Chemistry and Chemical Engineering of Huazhong University of Science and Technology and Shenzhen Senior Technology Material Co.Ltd.,the National Natural Science Foundation of China(52020105012,52303084)the Young Scientists Fund of Natural Science Foundation of Hubei Province(2023AFB220)for the support of this work.
文摘The growing demands for energy storage systems,electric vehicles,and portable electronics have significantly pushed forward the need for safe and reliable lithium batteries.It is essential to design functional separators with improved mechanical and electrochemical characteristics.This review covers the improved mechanical and electrochemical performances as well as the advancements made in the design of separators utilizing a variety of techniques.In terms of electrolyte wettability and adhesion of the coating materials,we provide an overview of the current status of research on coated separators,in situ modified separators,and grafting modified separators,and elaborate additional performance parameters of interest.The characteristics of inorganics coated separators,organic framework coated separators and inorganic-organic coated separators from different fabrication methods are compared.Future directions regarding new modified materials,manufacturing process,quantitative analysis of adhesion and so on are proposed toward next-generation advanced lithium batteries.
基金supported by Beijing Institute of Technology Student Innovation Training Program(BIT2024LH013).
文摘The thermal stability of lithium-ion battery separators is a critical determinant of battery safety and performance,especially in the context of rapidly expanding applications in electric vehicles and energy storage systems.While traditional polyolefin separators(PP/PE)dominate the market due to their cost-effectiveness and mechanical robustness,their inherent poor thermal stability poses significant safety risks under high-temperature conditions.This review provides a comprehensive analysis of recent advancements in enhancing separator thermal stability through coating materials(metal,ceramic,inorganic)and novel high-temperature-resistant polymers(e.g.,PVDF copolymers,PI,PAN).Notably,we critically evaluate the trade-offs between thermal resilience and electrochemical performance,such as the unintended increase in electronic conductivity from metal coatings(e.g.,Cu,MOFs)and reduced electrolyte wettability in ceramic coatings(e.g.,Al_(2)O_(3)).Innovations in hybrid coatings(e.g.,BN/PAN composites,gradient-structured MOFs)and scalable manufacturing techniques(e.g.,roll-to-roll electrospinning)are highlighted as promising strategies to balance these competing demands.Furthermore,a comparative analysis of next-generation high-temperature-resistant separators underscores their ionic conductivity,mechanical strength,and scalability,offering actionable insights for material selection.The review concludes with forward-looking perspectives on integrating machine learning for material discovery,optimizing interfacial adhesion in ceramic coatings,and advancing semi-/all-solid-state batteries to address both thermal and electrochemical challenges.This work aims to bridge the gap between laboratory innovations and industrial applications,fostering safer and more efficient lithium battery technologies.
基金supported by the National Natural Science Foundation of China(52463013 and 52073133)Key Talent Project Foundation of Gansu Province+3 种基金Joint fund between Shenyang National Laboratory for Materials ScienceState Key Laboratory of Advanced Processing and Recycling of Nonferrous Metals(18LHPY002)the Program for Hongliu Distinguished Young Scholars in Lanzhou University of Technologythe Incubation Program of Excellent Doctoral Dissertation–Lanzhou University of Technology
文摘Shuttle effect of polysulfides overshadows the superiorities of lithium-sulfur batteries.Size-sieving effect could address this thorny trouble rely on size differ in polysulfides and lithium ions.However,clogged polysulfides pose some challenges for cathode and are rarely recycled during charging/discharging.Herein,an amino functionalized titanium-organic framework is designed for modifying lithium-sulfur batteries separator to address the aforementioned challenges.Wherein,the introduction of amino narrows titanium-organic framework pore size,enabling functional separator to selectively modulate lithium ions and polysulfides migration using size-sieving effect,thereby completely suppressing polysulfides shuttle.Furthermore,the blocked polysulfides will be adsorbed on the separator surface by positively charged amino leveraging electrostatic adsorption,ensuring polysulfides to redistribute and reuse,and boosting active materials utilization.Significantly,the migration of lithium ions is not hindered since there are lithium ions transfer channels formed via Lewis acid-base interaction with the help of amino.Combined with these virtues,the lithium-sulfur batteries with amino functionalized titanium-organic framework modified separator enjoy an ultralow attenuation rate of 0.045%per cycle over 1000 cycles at 1.0C.Electrostatic adsorption and Lewis acid-base interaction cover deficiencies existing in the inhibition of polysulfides shuttle by size-sieving effect,providing fresh insight into the advancement of lithium-sulfur batteries.
基金supported by the National Natural Science Foundation of China(Grant Number 22350410379)Zhejiang Provincial Natural Science Foundation of China(LZ23B030003)+1 种基金the Fundamental Research Funds for the Central Universities(226-202400075)Ten Thousand Talent Program of Zhejiang Province.
文摘Separator modification is an effective approach to suppress dendrite growth to realize high-energy sodium metal batteries(SMBs)in practical applications,however,its success is mainly subject to surface modification.Herein,a separator with multifunctional layers composed of N-doped mesoporous hollow carbon spheres(HCS)as the inner layer and sodium fluoride(NaF)as the outer layer on commercial polypropylene separator(PP)is proposed(PP@HCS-NaF)to achieve stable cycling in SMB.At the molecular level,the inner HCS layer with a high content of pyrrolic-N induces the uniform Na^(+)flux as a potential Na^(+)redistributor for homogenous deposition,whereas its hollow mesoporous structure offers nanoporous buffers and ion channels to regulate Na^(+)ion distribution and uniform deposition.The outer layer(NaF)constructs the NaF-enriched robust solid electrolyte interphase layer,significantly lowering the Na^(+)ions diffusion barrier.Benefiting from these merits,higher electrochemical performances are achieved with multifunctional double-layered PP@HCS-NaF separators compared with single-layered separators(i.e.PP@HCS or PP@NaF)in SMBs.The Na‖Cu half-cell with PP@HCS-NaF offers stable cycling(280 cycles)with a high CE(99.6%),and Na‖Na symmetric cells demonstrate extended lifespans for over 6000 h at 1 mA cm^(-2)with a progressively stable overpotential of 9 mV.Remarkably,in Na‖NVP full-cells,the PP@HCS-NaF separator grants a stable capacity of~81 mA h g^(-1)after 3500 cycles at 1 C and an impressive rate capability performance(~70 mA h g^(-1)at 15 C).
基金supported by the Key Research and Development Projects of Anhui Province(No.202304a05020031).
文摘Lithium-sulfur batteries(LSBs)have attracted widespread attention due to their high theoretical energy density.However,the dissolution of long-chain polysulfides into the electrolyte(the“shuttle effect”)leads to rapid capacity decay.Therefore,finding suitable materials to mitigate the shuttle effect of polysulfides is crucial for enhancing the electrochemical performance of lithium-sulfur batteries.In this study,LSBs’separator is modified with Ni_(3)V_(2)O_(8)nanoparticles@carboxylated carbon nanotubes(Ni_(3)V_(2)O_(8)@CNTs)composite.There are abundant oxygen vacancies in Ni_(3)V_(2)O_(8)@CNTs composite which plays a synergistic effect on shuttle effect.The Ni_(3)V_(2)O_(8)can tightly anchor soluble polysulfides through oxygen vacancies,while the CNTs not only facilitate the transport of ions and electrons but also weaken the migration of polysulfides,limiting shuttle effect.As a result,the cycling stability of LSBs using Ni_(3)V_(2)O_(8)@CNTs-modified separator has been significantly improved(with a capacity decay rate of only 0.0334%after 1500 cycles at 4.0C).This study proposes a strategy to design modified separator for high-performance LSBs.
基金supported in part by the National Natural Science Foundation of China under Grant 62303333in part by the Project of Hetao Shenzhen-Hong Kong Science and Technology Innovation Cooperation Zone under Grant HZQB-KCZYB-2020083.
文摘To achieve high power rating and low current harmonics of motor drive,this paper develops a dual three-phase open-winding permanent magnet synchronous motor(DTP-OW-PMSM)drive with the DC-link voltage ratio of 2:1:1.Based on this topology,this paper proposes a DTP four-level space vector pulse width modulation(DTP-FL SVPWM)strategy.First,two identical three-phase four-level space vector diagrams are constructed and divided.Then,three adjacent vectors nearest to the reference vector in each diagram are selected for the vector synthesis to guarantee high modulation precision and low switching frequency.Furthermore,to avoid the modulation error caused by the voltage deviation,the proposed DTP-FL SVPWM strategy is further optimized through unified duty ratio compensation(UDRC).The effectiveness of the proposed strategy is verified through experiments.
