Lithium-sulfur(Li-S)batteries require efficient catalysts to accelerate polysulfide conversion and mitigate the shuttle effect.However,the rational design of catalysts remains challenging due to the lack of a systemat...Lithium-sulfur(Li-S)batteries require efficient catalysts to accelerate polysulfide conversion and mitigate the shuttle effect.However,the rational design of catalysts remains challenging due to the lack of a systematic strategy that rationally optimizes electronic structures and mesoscale transport properties.In this work,we propose an autogenously transformed CoWO_(4)/WO_(2) heterojunction catalyst,integrating a strong polysulfide-adsorbing intercalation catalyst with a metallic-phase promoter for enhanced activity.CoWO_(4) effectively captures polysulfides,while the CoWO_(4)/WO_(2) interface facilitates their S-S bond activation on heterogenous catalytic sites.Benefiting from its directional intercalation channels,CoWO_(4) not only serves as a dynamic Li-ion reservoir but also provides continuous and direct pathways for rapid Li-ion transport.Such synergistic interactions across the heterojunction interfaces enhance the catalytic activity of the composite.As a result,the CoWO_(4)/WO_(2) heterostructure demonstrates significantly enhanced catalytic performance,delivering a high capacity of 1262 mAh g^(−1) at 0.1 C.Furthermore,its rate capability and high sulfur loading performance are markedly improved,surpassing the limitations of its single-component counterparts.This study provides new insights into the catalytic mechanisms governing Li-S chemistry and offers a promising strategy for the rational design of high-performance Li-S battery catalysts.展开更多
Ferroptosis has exhibited great potential in therapies and intracellular reducing agents of sulfur species(RSSs) in the thiol-dependent redox systems are crucial in ferroptosis.This makes the simultaneous detection of...Ferroptosis has exhibited great potential in therapies and intracellular reducing agents of sulfur species(RSSs) in the thiol-dependent redox systems are crucial in ferroptosis.This makes the simultaneous detection of multiple RSSs significant for evaluating ferroptosis therapy.However,the traditional techniques,including fluorescent(FL) imaging and electrospray ionization-based mass spectrometry(MS) detection,cannot achieve the discrimination of different RSSs.Herein,simultaneous MS detection of multiple RSSs,including cysteine(Cys),homocysteine(Hcy),glutathione(GSH) and hydrogen sulfide(H_(2)S),was obtained upon enhancing ionization efficiency by a fluorescent probe(NBD-O-1).Based on the interaction between NBD-O-1 and RSSs,the complex of RSSs with a fragment of NBD-O-1 can be generated,which can be easily ionized for MS detection in the negative mode.Therefore,the intracellular RSSs can be well detected upon the incubation of He La cells with the probe of NBD-O-1,exhibiting the total RSS levels by the FL imaging and further providing expression of each RSS by enhanced MS detection.Furthermore,the RSSs during ferroptosis in He La cells have been evaluated using the present strategy,demonstrating the potential for ferroptosis examinations.This work has made an unconventional application of a fluorescent probe to enhance the detection of multiple RSSs by MS,providing significant molecular information for addressing the ferroptosis mechanism.展开更多
The development of catalytic multicomponent reactions for constructing complex organic scaffolds from readily accessible commodity chemicals is a key pursuit in contemporary synthetic chemistry.Current methods for syn...The development of catalytic multicomponent reactions for constructing complex organic scaffolds from readily accessible commodity chemicals is a key pursuit in contemporary synthetic chemistry.Current methods for synthesizing thioesters primarily rely on the acylation of thiols,which produces substantial waste and requires malodorous,unstable sulfur sources.In this work,we introduce a photocatalyzed hydrogen transfer strategy that enables a three-component synthesis of thioesters using abundant primary alcohols,easily available alkenes and elemental sulfur under mild conditions.This protocol demonstrates broad applicability and high chemo-and regioselectivity for both primary alcohols and alkenes,highlighting the advantage and potential of photo-mediated hydrogen transfer in facilitating multicomponent reactions using primary alcohol and elemental sulfur feedstocks.展开更多
Photo-assisted lithium–sulfur batteries(PALSBs)offer an eco-friendly solution to address the issue of sluggish reaction kinetics of conventional LSBs.However,designing an efficient photoelectrode for practical implem...Photo-assisted lithium–sulfur batteries(PALSBs)offer an eco-friendly solution to address the issue of sluggish reaction kinetics of conventional LSBs.However,designing an efficient photoelectrode for practical implementation remains a significant challenge.Herein,we construct a free-standing polymer–inorganic hybrid photoelectrode with a direct Z-scheme heterostructure to develop high-efficiency PALSBs.Specifically,polypyrrole(PPy)is in situ vapor-phase polymerized on the surface of N-doped TiO_(2) nanorods supported on carbon cloth(N-TiO_(2)/CC),thereby forming a well-defined p–n heterojunction.This architecture efficiently facilitates the carrier separation of photo-generated electron–hole pairs and significantly enhances carrier transport by creating a built-in electric field.Thus,the PPy@N-TiO_(2)/CC can simultaneously act as a photocatalyst and an electrocatalyst to accelerate the reduction and evolution of sulfur,enabling ultrafast sulfur redox dynamics,as convincingly validated by both theoretical simulations and experimental results.Consequently,the PPy@N-TiO_(2)/CC PALSB achieves a high discharge capacity of 1653 mAh g^(−1),reaching 98.7%of the theoretical value.Furthermore,5 h of photo-charging without external voltage enables the PALSB to deliver a discharge capacity of 333 mAh g^(−1),achieving dual-mode energy harvesting capabilities.This work successfully integrates solar energy conversion and storage within a rechargeable battery system,providing a promising strategy for sustainable energy storage technologies.展开更多
In this work,ofloxacin(OFL),a kind of frequently detected antibiotic in groundwater,was selected to explore its impact(at ng/L-μg/L-level)on denitrification performance in an autotrophic denitrification system driven...In this work,ofloxacin(OFL),a kind of frequently detected antibiotic in groundwater,was selected to explore its impact(at ng/L-μg/L-level)on denitrification performance in an autotrophic denitrification system driven by pyrite/sulfur(FeS2/S0).Results showed that OFL restrained nitrate removal efficiency,and the inhibition degree was positively related to the concentration of OFL.After being exposed to increased OFL(200 ng/L-100μg/L)for 69 days,higher inhibition of electron transport activity(ETSA),enzyme activities of nitrate reductase(NAR),and nitrite reductase(NIR)were acquired.Meanwhile,the extracellular protein(PN)content of sludge samples was remarkably stimulated by OFL to resist the augmented toxicity.OFL contributed to increased microbial diversity and sulfur/sulfide oxidation functional genes in ng/L-level bioreactors,whereas led to a decline inμg/L level experiments.With OFL at concentrations of 200 ng/L and 100μg/L,the whole expression of 10 key denitrification functional genes was depressed,and the higher the OFL concentration,the lower the expression level.However,no significant proliferation of antibiotic resistance genes(ARGs)either in 200 ng/L-OFL or 100μg/L-OFL groups was observed.Two-factor correlation analysis results indicated that Thiobacillus,Anaerolineae,Anaerolineales,and Nitrospirae might be the main hosts of existing ARGs in this system.展开更多
Lithium-sulfur (Li-S) batteries have gained great attention due to the high theoretical energy density and low cost,yet their further commercialization has been obstructed by the notorious shuttle effect and sluggish ...Lithium-sulfur (Li-S) batteries have gained great attention due to the high theoretical energy density and low cost,yet their further commercialization has been obstructed by the notorious shuttle effect and sluggish redox dynamics.Herein,we supply a strategy to optimize the electron structure of Ni_(2)P by concurrently introducing B-doped atoms and P vacancies in Ni_(2)P (Vp-B-Ni_(2)P),thereby enhancing the bidirectional sulfur conversion.The study indicates that the simultaneous introduction of B-doped atoms and P vacancies in Ni_(2)P causes the redistribution of electron around Ni atoms,bringing about the upward shift of d-band center of Ni atoms and effective d-p orbital hybridization between Ni atoms and sulfur species,thus strengthening the chemical anchoring for lithium polysulfides (LiPSs) as well as expediting the bidirectional conversion kinetics of sulfur species.Meanwhile,theoretical calculations reveal that the incorporation of B-doped atoms and P vacancies in Ni_(2)P selectively promotes Li2S dissolution and nucleation processes.Thus,the Li-S batteries with Vp-B-Ni_(2)P-separators present outstanding rate ability of 777 m A h g^(-1)at 5 C and high areal capacity of 8.03 mA h cm^(-2)under E/S of 5μL mg^(-1)and sulfur loading of 7.20 mg cm^(-2).This work elucidates that introducing heteroatom and vacancy in metal phosphide collaboratively regulates the electron structure to accelerate bidirectional sulfur conversion.展开更多
The use of lithium-sulfur(Li-S)batteries is limited by sulfur redox reactions involving multi-phase transformations,especially at low-temperatures.To address this issue,we report a material(FCNS@NCFs)consisting of nit...The use of lithium-sulfur(Li-S)batteries is limited by sulfur redox reactions involving multi-phase transformations,especially at low-temperatures.To address this issue,we report a material(FCNS@NCFs)consisting of nitrogen-doped carbon fibers loaded with a ternary metal sulf-ide((Fe,Co,Ni)_(9)S_(8))for use as the sulfur host in Li-S batteries.This materi-al was prepared using transfer blot filter paper as the carbon precursor,thiourea as the source of nitrogen and sulfur,and FeCl_(3)·6H_(2)O,CoCl_(2)·6H_(2)O and NiCl_(2)·6H_(2)O as the metal ion sources.It was synthesized by an impreg-nation method followed by calcination.The nitrogen doping significantly in-creased the conductivity of the host,and the metal sulfides have excellent catalytic activities.Theoretical calculations,and adsorption and deposition experiments show that active sites on the surface of FCNS@NCFs selectively adsorb polysulfides,facilitate rapid adsorption and conversion,prevent cathode passivation and inhib-it the polysulfide shuttling.The FCNS@NCFs used as the sulfur host has excellent electrochemical properties.Its initial dis-charge capacity is 1639.0 mAh g^(−1) at 0.2 C and room temperature,and it remains a capacity of 1255.1 mAh g^(−1) after 100 cycles.At−20~C,it has an initial discharge capacity of 1578.5 mAh g^(−1) at 0.2 C,with a capacity of 867.5 mAh g^(−1) after 100 cycles.Its excellent performance at both ambient and low temperatures suggests a new way to produce high-performance low-temper-ature Li-S batteries.展开更多
In this work,a new process for achieving the recovery of elemental sulfur by utilizing a fluidized catalytic cracking(FCC) riser reactor for SOxtreatment(FCC-DeSOx) is proposed.The process leverages the high temperatu...In this work,a new process for achieving the recovery of elemental sulfur by utilizing a fluidized catalytic cracking(FCC) riser reactor for SOxtreatment(FCC-DeSOx) is proposed.The process leverages the high temperatures and hydrocarbon concentrations in the FCC riser reactor to convert SOxinto H_(2)S.Subsequently,H_(2)S,along with the cracked gas,is processed downstream to produce sulfur.Thermodynamic analysis of the key reduction reactions in the FCC-DeSOxprocess revealed that complete conversion of SOxto H_(2)S is feasible in the dry gas(hydrogen-rich) prelift zone,as well as the upper and lower zones of the riser,upon achieving thermodynamic equilibrium.Experimental studies were conducted to replicate the conditions of these reaction zones using a low concentration of hydrogen gas as the reducing agent.Through process optimization,investigation of the minimum reaction time,and kinetic studies,the potential of this method for the complete reduction of SOxwas further confirmed.展开更多
High-entropy oxides(HEOs)have sparked scientific interest recently as a potential material technology for lithium-sulfur(Li–S)batteries.This interest stems from their simultaneous roles as sulfur hosts and electrocat...High-entropy oxides(HEOs)have sparked scientific interest recently as a potential material technology for lithium-sulfur(Li–S)batteries.This interest stems from their simultaneous roles as sulfur hosts and electrocatalysts,which provide enhancements to the performance of sulfur cathode composites.Nonetheless,their incorporation into the active material blend results in compromised energy density,particularly when their gravimetric proportion is substantial(≥10 wt.%,in the sulfur-based cathode).展开更多
Despite significant progress has been achieved regarding the shuttle-effect of lithium polysulfides,the suppressed specific capacity and retarded redox kinetics under high sulfur loading still threat the actual energy...Despite significant progress has been achieved regarding the shuttle-effect of lithium polysulfides,the suppressed specific capacity and retarded redox kinetics under high sulfur loading still threat the actual energy density and power density of lithium-sulfur batteries.In this study,a graham condenser-inspired carbon@WS_(2)host with coil-in-tube structure was designed and synthesized using anodic aluminum oxide(AAO)membrane with vertically aligned nanopores as template.The vertical array of carbon nanotubes with internal carbon coils not only leads to efficient charge transfer across through the thickness of the cathode,but also provides significant confinement to polysulfide diffusion towards both the lateral and longitudinal directions.Few-layer WS_(2)in the carbon coils perform a synergistic role in suppressing the shuttle-effect as well as boosting the cathodic kinetics.As a result,high specific capacity(1180 m Ah/g at 0.1 C)and long-cycling stability at 0.5 C for 500 cycles has been achieved at 3 mgS/cm^(2).Impressive areal capacity of 7.4 m Ah/cm^(2)has been demonstrated when the sulfur loading reaches 8.4 mg/cm^(2).The unique coil-in-tube structure developed in this work provides a new solution for high sulfur loading cathode towards practical lithium-sulfur batteries.展开更多
Lithium metal batteries(LMBs)have attracted great intention due to the high energy density[1].Among various battery technologies,lithium-sulfur(Li-S)batteries are also very unique but important due to its high energy ...Lithium metal batteries(LMBs)have attracted great intention due to the high energy density[1].Among various battery technologies,lithium-sulfur(Li-S)batteries are also very unique but important due to its high energy density,low cost and available sources[2].Although Li-s batteries exhibit high energy density,the cycling life is poor,especially for large-capacity pouch cells[3].The cycling performance of Li-s batteries is crucially determined by 16-electron complex sulfur reduction reaction(SRR)from S_(8)molecules to Li_(2)S,solid,which involves the multiple potential interwoven branches among lithium polysulfide intermediates(LiPS,e.g.,S_(8),Li_(2)S_(8),Li_(2)S_(6),Li_(2)S_(4)and Li_(2)S)[4].The obvious shuttle for soluble Lips across the cathode and anode leads to the battery capacity fading.Thus,it is necessary to decrease the accumulation of soluble Lips in the electrolyte through catalysts fastening the key conversion step from high-order polysulfides to insoluble Li_(2)S_(2)/Li_(2)S.Although some effort has been devoted to catalyze SRR,the complex mechanism remains unclear.To address this issue,Duan et al.tried to solve it based on nitrogen,sulfur,dualdoped holey graphene framework(N,S-HGF)electrocatalyst in Nature[5].展开更多
Many catalysts have shown excellent activity for the sulfur reduction reaction(SRR),but sluggish electrochemistry kinetics have hindered the development of lithium-sulfur batteries.It has been found that the activity ...Many catalysts have shown excellent activity for the sulfur reduction reaction(SRR),but sluggish electrochemistry kinetics have hindered the development of lithium-sulfur batteries.It has been found that the activity of catalysts for the sulfur evolution reaction(SER)plays a crucial role in determining the overall reaction kinetics.To address this issue,the rational design of catalysts is crucial.Here,we proposed a popular rule to accelerate SER by using chip-like high-entropy perovskite oxide La_(0.7)Sr_(0.3)(Fe_(0.2)Co_(0.2)Ni_(0.2)Zn_(0.2)Mn_(0.2))O_(3-δ)(LMO-HEO)as advanced electrocatalysts.The strong interaction between the adjacent metal atoms in different metals of LMO-HEO electrocatalysts could lead to a"cocktail effect",which not only greatly improved the catalytic capacity toward sulfur species,but also accelerated the oxidation reaction kinetics of Li_2S.As a result,the S/La_(0.7)Sr_(0.3)(Fe_(0.2)Co_(0.2)Ni_(0.2)Zn_(0.2))Mn_(0.2)O_(3-δ)cathodes delivered excellent cyclic stability with a capacity decay of only 0.025%after 1200 cycles at 2 C.This work has provided a rational design idea for new multifunctional electrocatalysts with high catalytic capacity.展开更多
Sulfur was typically regarded as a poison to precious metal complex catalysts in hydroformylation of olefins.However,the combination of sulfur and phosphine may present an intriguing interaction with heterogeneous mon...Sulfur was typically regarded as a poison to precious metal complex catalysts in hydroformylation of olefins.However,the combination of sulfur and phosphine may present an intriguing interaction with heterogeneous mononuclear complex due to the difference of their electronegativities,and coordination capabilities.Herein,we report a novel sulfur-phosphine co-coordinated heterogeneous Rh mononuclear complex catalyst(Rh_(1)/POPs-PPh_(3)&S),which exhibits an unexpected 1.5–2.0 times catalytic activity for hydroformylation of olefins(C_(3)=,C_(5)=–C_(8)=),in comparison with the solely phosphine-coordinated Rh mononuclear complex catalyst(Rh_(1)/POPs-PPh_(3)).In contrast,sulfur coordination alone leads to severe sulfur poisoning with significantly inhibited catalytic performance.Experimental and theoretical analyses reveal that phosphine coordination promotes catalytic activity via its strong electron-donating ability,while sulfur occupies a coordination site and reduces the electronic density of Rh ions.The synergistical coordination of sulfur and phosphine optimizes the electronic density of active Rh ions and decreases the energy barrier of the rate-determining step of olefin insertion,thus enhancing the hydroformylation activity,regioselectivity and stability of Rh_(1)/POPs-PPh_(3)&S.展开更多
Despite sulfurization offers the advantage of improving the photovoltaic performance in preparing Cu(In,Ga)Se2(CIGS)absorbers,deep level defects in the absorber and poor energy level alignment on the front surface are...Despite sulfurization offers the advantage of improving the photovoltaic performance in preparing Cu(In,Ga)Se2(CIGS)absorbers,deep level defects in the absorber and poor energy level alignment on the front surface are still main obstacles limiting the improvement of power co nversion efficiency(PCE)in sulfided CIGS solar cells.Herein,an in-situ Na doping strategy is proposed,in which the tailing effect of crystal growth is used to promote the sulfurization of CIGS absorbers.It is found that the grain growth is supported by Na incorporating due to the enrichment of NaSe_(x)near the upper surface.The high soluble Na during grain growth can not only suppress intrinsic In_(Cu) donor defects in the absorber,but also tailor S distribution in bulk and the band alignment at the heterojunction,which are both beneficial for the effective electron carriers.Meanwhile,the Na aggregation near the bottom of the absorber also contributes to the crystalline quality increasing and favorable ultra-thin MoSe_(2) formation at back contact,resulting in a reduced barrier height conducive to hole transport.PCE of the champion device is as high as 16.76%with a 28%increase.This research offers new insights into synthesizing CIGS solar cells and other chalcogenide solar cells with superior cell performance when using an intense sulfurization process.展开更多
Contaminants in the water environment of different pyritemines have varying characteristics due to different geological origins.Sulfur isotope(δ^(34)S)is an effective tool to reveal the mechanism of water environment...Contaminants in the water environment of different pyritemines have varying characteristics due to different geological origins.Sulfur isotope(δ^(34)S)is an effective tool to reveal the mechanism of water environment contamination,but no investigations have yet analyzed the characteristics and environmental significance of the δ^(34)S in the water environment of different pyritemines.This study involved a field investigation of four typical pyritemines in China(representing volcanic,skarn,sedimentary-metamorphic,and coal-deposited types)and the analysis of the hydrochemistry of aqueous samples and the δ^(34)S of both pyrite and dissolved sulfates.The S isotopes in minerals of different types of mines were associated with the deposit genesis,and S isotopes in the water environment were affected by sulfide minerals and indicative of the contaminant sources,types of contaminants,and contaminant transport processes.The environmental significance of δ^(34)S in the water environment was further explored and a contamination model for pyrite mines established based on S isotope data.The study offers a theoretical foundation for further research on the prevention,control,and management of water pollution at various types of pyrite mines.展开更多
Atmospheric dimethyl sulfide(DMS,CH_(3)SCH_(3))and methanethiol(MeSH,CH_(3)SH)have been widely studied and recognized to significantly constrain the atmospheric sulfur budget.Nevertheless,while the role of DMS and MeS...Atmospheric dimethyl sulfide(DMS,CH_(3)SCH_(3))and methanethiol(MeSH,CH_(3)SH)have been widely studied and recognized to significantly constrain the atmospheric sulfur budget.Nevertheless,while the role of DMS and MeSH remains largely uncertain in inland regions,learning about dimethyl disulfide(DMDS,CH_(3)SSCH_(3))is also limited.In this study,we measured atmospheric DMS,MeSH and DMDS in winter,from 19 December 2022 to 30 January 2023,and spring,from 24 April to 2 June 2023 with a Vocus proton-transfer-reaction time-offlightmass spectrometer(Vocus PTR-TOF)at the Dianshan Lake(DSL)Air QualityMonitoring Supersite in a suburban area of Shanghai,China.The mixing ratios of DMS,MeSH and DMDS exhibited clear diurnal cycles,and were characterized by average and interquartile range values of 22.6(10.1-29.7),14.9(6.5-19.4)and 9.8(6.0-10.7)pptv,respectively,in the spring campaign,which are approximately twice as high as those in winter.MeSH and DMDS were found to be well correlated with DMS in the two campaigns.Wind analysis suggests that three reduced-sulfur compounds owned common sources from the DSL.Furthermore,the sulfur dioxide(SO_(2))production quantity fromthe three reduced-sulfur compounds over the DSL inMay 2023 was estimated to be 1.42±0.74 t with 84.8%originating fromDMDS,which was comparable to the monthly SO_(2) emissions fromships over the DSL.Our results highlight the prominent role of atmospheric DMDS in SO_(2) production when compared to DMS and MeSH in the suburban area of Shanghai,soliciting further investigation and consideration of DMDS in the sulfur budget.展开更多
Lithium-sulfur(Li–S) battery has become one of the most promising next-generation electrical storage systems because of its exceptional energy density of 2600 Wh kg^(-1). However, their commercialization is hindered ...Lithium-sulfur(Li–S) battery has become one of the most promising next-generation electrical storage systems because of its exceptional energy density of 2600 Wh kg^(-1). However, their commercialization is hindered by several key obstacles, notably the polysulfide shuttle effect,poor electrical conductance of sulfur, and considerable volumetric change during cycling. This review addresses current advancements in microstructural innovations aimed at improving Li–S battery performance, focusing on modifying cathode materials. The strategies discussed primarily revolve around enhancing the conductivity of sulfur and effectively confining polysulfides to reduce the dissolving of lithium polysulfides in organic electrolytes. Key findings highlight the effectiveness of porous carbon structures and metal compounds in stabilizing polysulfides and enhancing electrochemical performances. Additionally, the roles of advanced synthesis techniques that facilitate the creation of hybrid cathodes with superior mechanical properties and cycling stability are summarized. By addressing the inherent limitations of traditional Li–S battery designs, these innovations pave the way for more efficient and reliable energy storage systems, positioning Li–S technology as a viable alternative to conventional lithium-ion batteries in future applications.展开更多
Lithium-sulfur(Li-S)batteries hold great promise for next-generation energy storage,yet suffer from sluggish redox kinetics and polysulfide shuttling.Herein,a novel Ni_(3)S_(2)/Ni_(2)B heterostructure is developed to ...Lithium-sulfur(Li-S)batteries hold great promise for next-generation energy storage,yet suffer from sluggish redox kinetics and polysulfide shuttling.Herein,a novel Ni_(3)S_(2)/Ni_(2)B heterostructure is developed to improve sulfur electrochemistry by synergistically enhancing polysulfide fixation and catalytic conversions.Fabricated through mild sequential boronation and sulfurization,this hybrid nanocatalyst integrates the strong polysulfide adsorbability and high conductivity of Ni_(2)B with the high catalytic activity of Ni_(3)S_(2).More importantly,the as-constructed heterointerface inspires new,highly catalytic sites that smooth consecutive sulfur conversions with lower energy barriers,while the built-in electric fields promote directional charge transfer,collectively contributing to fast-kinetic and highly efficient sulfur redox reactions.As a result,Li-S cells incorporating the Ni_(3)S_(2)/Ni_(2)B nanocatalyst exhibit excellent cyclability,with minimal capacity decay of 0.017%per cycle over 900 cycles at 1 C and a superb rate capability of up to 5 C.Even under demanding conditions,such as a high sulfur loading of 5.0 mg cm^(-2)and a low electrolyte-to-sulfur(E/S)ratio of 4.8 mL g^(-1),high capacity and cyclability are maintained,highlighting the great potential of this unique heterointerface engineering in advancing high-performance and practically viable Li-S batteries.展开更多
Sulfuric acid slag,a common byproduct with high iron content,poses challenges due to its high levels of harmful impurities and is often discarded as solid waste,leading to significant environmental and water pollution...Sulfuric acid slag,a common byproduct with high iron content,poses challenges due to its high levels of harmful impurities and is often discarded as solid waste,leading to significant environmental and water pollution.To address this issue and improve resource utilization,the preparation process of oxidized pellets from sulfuric acid slag was studied,exploring suitable pelletizing systems and thermal parameters.Additionally,the removal of harmful elements and the consolidation mechanism were established during the oxidation roasting process.The findings revealed that sulfuric acid slag along with specific processing conditions,such as using two high-pressure grinding rolls and adding 1.25 wt.%bentonite,resulted in the production of qualified green pellets with desirable physical properties.Through a thermal treatment process involving preheating and roasting,the desulfurization rate of the pellets reached 95.55%and the removal efficiency of arsenic achieved 27.11%.Hematite recrystallizes,shrinks,and forms a reticulated structure with Fe2O3 recrystallization as the backbone,resulting in higher consolidation strength.展开更多
The absorption of air pollutants is an indicator for studying the value of forest land.It plays an important role in compiling resource balance sheets by studying the absorption of air pollutants by forest land.This p...The absorption of air pollutants is an indicator for studying the value of forest land.It plays an important role in compiling resource balance sheets by studying the absorption of air pollutants by forest land.This paper focused on sulfur dioxide,an air pollutant.Through on-site air sample collection and laboratory testing,using the calculation method of the UFORE model issued by the US Forestry Administration,the annual absorption data of sulfur dioxide in different forest lands in Dapeng New Area were obtained.The results showed that there was not much difference in the absorption capacity of sulfur dioxide among the three types of forest lands in the new area:shrubland,broad-leaved forest,and artificial forest.The amount of sulfur dioxide absorbed per unit area ranged from 11.80 to 13.62 kg/(hm^(2)·a).However,coniferous forests had a lower absorption capacity for sulfur dioxide,with an absorption per unit area of 5.39 kg/(hm^(2)·a).展开更多
基金support of the National Natural Science Foundation of China(22075131 and 22078265)the Shaanxi Fundamental Science Research Project for Mathematics and Physics under Grants(No.22JSZ005)the State-Key Laboratory of Multiphase Complex Systems(No.MPCS-2021-A).
文摘Lithium-sulfur(Li-S)batteries require efficient catalysts to accelerate polysulfide conversion and mitigate the shuttle effect.However,the rational design of catalysts remains challenging due to the lack of a systematic strategy that rationally optimizes electronic structures and mesoscale transport properties.In this work,we propose an autogenously transformed CoWO_(4)/WO_(2) heterojunction catalyst,integrating a strong polysulfide-adsorbing intercalation catalyst with a metallic-phase promoter for enhanced activity.CoWO_(4) effectively captures polysulfides,while the CoWO_(4)/WO_(2) interface facilitates their S-S bond activation on heterogenous catalytic sites.Benefiting from its directional intercalation channels,CoWO_(4) not only serves as a dynamic Li-ion reservoir but also provides continuous and direct pathways for rapid Li-ion transport.Such synergistic interactions across the heterojunction interfaces enhance the catalytic activity of the composite.As a result,the CoWO_(4)/WO_(2) heterostructure demonstrates significantly enhanced catalytic performance,delivering a high capacity of 1262 mAh g^(−1) at 0.1 C.Furthermore,its rate capability and high sulfur loading performance are markedly improved,surpassing the limitations of its single-component counterparts.This study provides new insights into the catalytic mechanisms governing Li-S chemistry and offers a promising strategy for the rational design of high-performance Li-S battery catalysts.
基金supported by the National Key Research and Development Program of China (No.2024YFA1509600)National Natural Science Foundation of China (Nos.22474010 and 22274012)the Fundamental Research Funds for the Central Universities (No.2233300007)。
文摘Ferroptosis has exhibited great potential in therapies and intracellular reducing agents of sulfur species(RSSs) in the thiol-dependent redox systems are crucial in ferroptosis.This makes the simultaneous detection of multiple RSSs significant for evaluating ferroptosis therapy.However,the traditional techniques,including fluorescent(FL) imaging and electrospray ionization-based mass spectrometry(MS) detection,cannot achieve the discrimination of different RSSs.Herein,simultaneous MS detection of multiple RSSs,including cysteine(Cys),homocysteine(Hcy),glutathione(GSH) and hydrogen sulfide(H_(2)S),was obtained upon enhancing ionization efficiency by a fluorescent probe(NBD-O-1).Based on the interaction between NBD-O-1 and RSSs,the complex of RSSs with a fragment of NBD-O-1 can be generated,which can be easily ionized for MS detection in the negative mode.Therefore,the intracellular RSSs can be well detected upon the incubation of He La cells with the probe of NBD-O-1,exhibiting the total RSS levels by the FL imaging and further providing expression of each RSS by enhanced MS detection.Furthermore,the RSSs during ferroptosis in He La cells have been evaluated using the present strategy,demonstrating the potential for ferroptosis examinations.This work has made an unconventional application of a fluorescent probe to enhance the detection of multiple RSSs by MS,providing significant molecular information for addressing the ferroptosis mechanism.
基金National Natural Science Foundation of China (Nos.22071185 and 22271224)the Fundamental Research Funds for the Central Universities (No.2042019kf0008)Wuhan University startup funding for financial support。
文摘The development of catalytic multicomponent reactions for constructing complex organic scaffolds from readily accessible commodity chemicals is a key pursuit in contemporary synthetic chemistry.Current methods for synthesizing thioesters primarily rely on the acylation of thiols,which produces substantial waste and requires malodorous,unstable sulfur sources.In this work,we introduce a photocatalyzed hydrogen transfer strategy that enables a three-component synthesis of thioesters using abundant primary alcohols,easily available alkenes and elemental sulfur under mild conditions.This protocol demonstrates broad applicability and high chemo-and regioselectivity for both primary alcohols and alkenes,highlighting the advantage and potential of photo-mediated hydrogen transfer in facilitating multicomponent reactions using primary alcohol and elemental sulfur feedstocks.
基金the financial support from the National Natural Science Foundation of China (22109127)the Chinese Postdoctoral Science Foundation (2021M702666)+2 种基金the Research Fund of the State Key Laboratory of Solidification Processing (NPU),China (Grant No.2023-TS-02)The financial support from the Youth Project of"Shaanxi High-level Talents Introduction Plan"the Key Laboratory of Advanced Energy Materials Chemistry (Ministry of Education) are also sincerely appreciated
文摘Photo-assisted lithium–sulfur batteries(PALSBs)offer an eco-friendly solution to address the issue of sluggish reaction kinetics of conventional LSBs.However,designing an efficient photoelectrode for practical implementation remains a significant challenge.Herein,we construct a free-standing polymer–inorganic hybrid photoelectrode with a direct Z-scheme heterostructure to develop high-efficiency PALSBs.Specifically,polypyrrole(PPy)is in situ vapor-phase polymerized on the surface of N-doped TiO_(2) nanorods supported on carbon cloth(N-TiO_(2)/CC),thereby forming a well-defined p–n heterojunction.This architecture efficiently facilitates the carrier separation of photo-generated electron–hole pairs and significantly enhances carrier transport by creating a built-in electric field.Thus,the PPy@N-TiO_(2)/CC can simultaneously act as a photocatalyst and an electrocatalyst to accelerate the reduction and evolution of sulfur,enabling ultrafast sulfur redox dynamics,as convincingly validated by both theoretical simulations and experimental results.Consequently,the PPy@N-TiO_(2)/CC PALSB achieves a high discharge capacity of 1653 mAh g^(−1),reaching 98.7%of the theoretical value.Furthermore,5 h of photo-charging without external voltage enables the PALSB to deliver a discharge capacity of 333 mAh g^(−1),achieving dual-mode energy harvesting capabilities.This work successfully integrates solar energy conversion and storage within a rechargeable battery system,providing a promising strategy for sustainable energy storage technologies.
基金supported by the National Natural Science Foundation of China(No.42377083)the Natural Science Foundation of Sichuan Province,China(No.2025 ZNSFSC0433).
文摘In this work,ofloxacin(OFL),a kind of frequently detected antibiotic in groundwater,was selected to explore its impact(at ng/L-μg/L-level)on denitrification performance in an autotrophic denitrification system driven by pyrite/sulfur(FeS2/S0).Results showed that OFL restrained nitrate removal efficiency,and the inhibition degree was positively related to the concentration of OFL.After being exposed to increased OFL(200 ng/L-100μg/L)for 69 days,higher inhibition of electron transport activity(ETSA),enzyme activities of nitrate reductase(NAR),and nitrite reductase(NIR)were acquired.Meanwhile,the extracellular protein(PN)content of sludge samples was remarkably stimulated by OFL to resist the augmented toxicity.OFL contributed to increased microbial diversity and sulfur/sulfide oxidation functional genes in ng/L-level bioreactors,whereas led to a decline inμg/L level experiments.With OFL at concentrations of 200 ng/L and 100μg/L,the whole expression of 10 key denitrification functional genes was depressed,and the higher the OFL concentration,the lower the expression level.However,no significant proliferation of antibiotic resistance genes(ARGs)either in 200 ng/L-OFL or 100μg/L-OFL groups was observed.Two-factor correlation analysis results indicated that Thiobacillus,Anaerolineae,Anaerolineales,and Nitrospirae might be the main hosts of existing ARGs in this system.
基金Institute of Technology Research Fund Program for Young Scholars21C Innovation Laboratory Contemporary Amperex Technology Co.,Limited,Ninde, 352100, China (21C–OP-202314)。
文摘Lithium-sulfur (Li-S) batteries have gained great attention due to the high theoretical energy density and low cost,yet their further commercialization has been obstructed by the notorious shuttle effect and sluggish redox dynamics.Herein,we supply a strategy to optimize the electron structure of Ni_(2)P by concurrently introducing B-doped atoms and P vacancies in Ni_(2)P (Vp-B-Ni_(2)P),thereby enhancing the bidirectional sulfur conversion.The study indicates that the simultaneous introduction of B-doped atoms and P vacancies in Ni_(2)P causes the redistribution of electron around Ni atoms,bringing about the upward shift of d-band center of Ni atoms and effective d-p orbital hybridization between Ni atoms and sulfur species,thus strengthening the chemical anchoring for lithium polysulfides (LiPSs) as well as expediting the bidirectional conversion kinetics of sulfur species.Meanwhile,theoretical calculations reveal that the incorporation of B-doped atoms and P vacancies in Ni_(2)P selectively promotes Li2S dissolution and nucleation processes.Thus,the Li-S batteries with Vp-B-Ni_(2)P-separators present outstanding rate ability of 777 m A h g^(-1)at 5 C and high areal capacity of 8.03 mA h cm^(-2)under E/S of 5μL mg^(-1)and sulfur loading of 7.20 mg cm^(-2).This work elucidates that introducing heteroatom and vacancy in metal phosphide collaboratively regulates the electron structure to accelerate bidirectional sulfur conversion.
基金partially supported by National Natural Science Foundation of China(52172250)Institute of Process Engineering(IPE)Project for Frontier Basic Research(QYJC-2023-06)。
文摘The use of lithium-sulfur(Li-S)batteries is limited by sulfur redox reactions involving multi-phase transformations,especially at low-temperatures.To address this issue,we report a material(FCNS@NCFs)consisting of nitrogen-doped carbon fibers loaded with a ternary metal sulf-ide((Fe,Co,Ni)_(9)S_(8))for use as the sulfur host in Li-S batteries.This materi-al was prepared using transfer blot filter paper as the carbon precursor,thiourea as the source of nitrogen and sulfur,and FeCl_(3)·6H_(2)O,CoCl_(2)·6H_(2)O and NiCl_(2)·6H_(2)O as the metal ion sources.It was synthesized by an impreg-nation method followed by calcination.The nitrogen doping significantly in-creased the conductivity of the host,and the metal sulfides have excellent catalytic activities.Theoretical calculations,and adsorption and deposition experiments show that active sites on the surface of FCNS@NCFs selectively adsorb polysulfides,facilitate rapid adsorption and conversion,prevent cathode passivation and inhib-it the polysulfide shuttling.The FCNS@NCFs used as the sulfur host has excellent electrochemical properties.Its initial dis-charge capacity is 1639.0 mAh g^(−1) at 0.2 C and room temperature,and it remains a capacity of 1255.1 mAh g^(−1) after 100 cycles.At−20~C,it has an initial discharge capacity of 1578.5 mAh g^(−1) at 0.2 C,with a capacity of 867.5 mAh g^(−1) after 100 cycles.Its excellent performance at both ambient and low temperatures suggests a new way to produce high-performance low-temper-ature Li-S batteries.
基金supported by General Program of National Natural Science Foundation of China (22178385)。
文摘In this work,a new process for achieving the recovery of elemental sulfur by utilizing a fluidized catalytic cracking(FCC) riser reactor for SOxtreatment(FCC-DeSOx) is proposed.The process leverages the high temperatures and hydrocarbon concentrations in the FCC riser reactor to convert SOxinto H_(2)S.Subsequently,H_(2)S,along with the cracked gas,is processed downstream to produce sulfur.Thermodynamic analysis of the key reduction reactions in the FCC-DeSOxprocess revealed that complete conversion of SOxto H_(2)S is feasible in the dry gas(hydrogen-rich) prelift zone,as well as the upper and lower zones of the riser,upon achieving thermodynamic equilibrium.Experimental studies were conducted to replicate the conditions of these reaction zones using a low concentration of hydrogen gas as the reducing agent.Through process optimization,investigation of the minimum reaction time,and kinetic studies,the potential of this method for the complete reduction of SOxwas further confirmed.
基金financially supported by the National Natural Science Foundation of China(52372289 and 52102368)Guangdong Special Fund for Key Areas(20237DZX3042)+2 种基金State Key Laboratory of New Ceramic Materials Tsinghua University(No.KF202415)Shenzhen Stable Support Projectsupported by the Centre for Advances in Reliability and Safety(CAiRS)admitted under AIR@Inno HK Research Cluster and HK Poly U Postdoc Matching Fund Scheme(1-W28H)。
文摘High-entropy oxides(HEOs)have sparked scientific interest recently as a potential material technology for lithium-sulfur(Li–S)batteries.This interest stems from their simultaneous roles as sulfur hosts and electrocatalysts,which provide enhancements to the performance of sulfur cathode composites.Nonetheless,their incorporation into the active material blend results in compromised energy density,particularly when their gravimetric proportion is substantial(≥10 wt.%,in the sulfur-based cathode).
基金the National Natural Science Foundation of China(Nos.22075027,52003030)Starting Grant from Beijing Institute of Technology and financial support from the State Key Laboratory of Explosion Science and Safety Protection(Nos.YBKT2106,YBKT23-05)Beijing Institute of Technology Research Fund Program for Young Scholars。
文摘Despite significant progress has been achieved regarding the shuttle-effect of lithium polysulfides,the suppressed specific capacity and retarded redox kinetics under high sulfur loading still threat the actual energy density and power density of lithium-sulfur batteries.In this study,a graham condenser-inspired carbon@WS_(2)host with coil-in-tube structure was designed and synthesized using anodic aluminum oxide(AAO)membrane with vertically aligned nanopores as template.The vertical array of carbon nanotubes with internal carbon coils not only leads to efficient charge transfer across through the thickness of the cathode,but also provides significant confinement to polysulfide diffusion towards both the lateral and longitudinal directions.Few-layer WS_(2)in the carbon coils perform a synergistic role in suppressing the shuttle-effect as well as boosting the cathodic kinetics.As a result,high specific capacity(1180 m Ah/g at 0.1 C)and long-cycling stability at 0.5 C for 500 cycles has been achieved at 3 mgS/cm^(2).Impressive areal capacity of 7.4 m Ah/cm^(2)has been demonstrated when the sulfur loading reaches 8.4 mg/cm^(2).The unique coil-in-tube structure developed in this work provides a new solution for high sulfur loading cathode towards practical lithium-sulfur batteries.
文摘Lithium metal batteries(LMBs)have attracted great intention due to the high energy density[1].Among various battery technologies,lithium-sulfur(Li-S)batteries are also very unique but important due to its high energy density,low cost and available sources[2].Although Li-s batteries exhibit high energy density,the cycling life is poor,especially for large-capacity pouch cells[3].The cycling performance of Li-s batteries is crucially determined by 16-electron complex sulfur reduction reaction(SRR)from S_(8)molecules to Li_(2)S,solid,which involves the multiple potential interwoven branches among lithium polysulfide intermediates(LiPS,e.g.,S_(8),Li_(2)S_(8),Li_(2)S_(6),Li_(2)S_(4)and Li_(2)S)[4].The obvious shuttle for soluble Lips across the cathode and anode leads to the battery capacity fading.Thus,it is necessary to decrease the accumulation of soluble Lips in the electrolyte through catalysts fastening the key conversion step from high-order polysulfides to insoluble Li_(2)S_(2)/Li_(2)S.Although some effort has been devoted to catalyze SRR,the complex mechanism remains unclear.To address this issue,Duan et al.tried to solve it based on nitrogen,sulfur,dualdoped holey graphene framework(N,S-HGF)electrocatalyst in Nature[5].
基金partially supported by grants from the National Natural Science Foundation of China(No.52072099)Team program of the Natural Science Foundation of Heilongjiang Province,China(No.TD2021E005)Joint Guidance Project of the Natural Science Foundation of Heilongjiang Province,China(No.LH2022E093)。
文摘Many catalysts have shown excellent activity for the sulfur reduction reaction(SRR),but sluggish electrochemistry kinetics have hindered the development of lithium-sulfur batteries.It has been found that the activity of catalysts for the sulfur evolution reaction(SER)plays a crucial role in determining the overall reaction kinetics.To address this issue,the rational design of catalysts is crucial.Here,we proposed a popular rule to accelerate SER by using chip-like high-entropy perovskite oxide La_(0.7)Sr_(0.3)(Fe_(0.2)Co_(0.2)Ni_(0.2)Zn_(0.2)Mn_(0.2))O_(3-δ)(LMO-HEO)as advanced electrocatalysts.The strong interaction between the adjacent metal atoms in different metals of LMO-HEO electrocatalysts could lead to a"cocktail effect",which not only greatly improved the catalytic capacity toward sulfur species,but also accelerated the oxidation reaction kinetics of Li_2S.As a result,the S/La_(0.7)Sr_(0.3)(Fe_(0.2)Co_(0.2)Ni_(0.2)Zn_(0.2))Mn_(0.2)O_(3-δ)cathodes delivered excellent cyclic stability with a capacity decay of only 0.025%after 1200 cycles at 2 C.This work has provided a rational design idea for new multifunctional electrocatalysts with high catalytic capacity.
文摘Sulfur was typically regarded as a poison to precious metal complex catalysts in hydroformylation of olefins.However,the combination of sulfur and phosphine may present an intriguing interaction with heterogeneous mononuclear complex due to the difference of their electronegativities,and coordination capabilities.Herein,we report a novel sulfur-phosphine co-coordinated heterogeneous Rh mononuclear complex catalyst(Rh_(1)/POPs-PPh_(3)&S),which exhibits an unexpected 1.5–2.0 times catalytic activity for hydroformylation of olefins(C_(3)=,C_(5)=–C_(8)=),in comparison with the solely phosphine-coordinated Rh mononuclear complex catalyst(Rh_(1)/POPs-PPh_(3)).In contrast,sulfur coordination alone leads to severe sulfur poisoning with significantly inhibited catalytic performance.Experimental and theoretical analyses reveal that phosphine coordination promotes catalytic activity via its strong electron-donating ability,while sulfur occupies a coordination site and reduces the electronic density of Rh ions.The synergistical coordination of sulfur and phosphine optimizes the electronic density of active Rh ions and decreases the energy barrier of the rate-determining step of olefin insertion,thus enhancing the hydroformylation activity,regioselectivity and stability of Rh_(1)/POPs-PPh_(3)&S.
基金supported by the National Natural Science Foundation of China(62204074)the Hebei Natural Science Foundation(F2022201061,F2023201025)+2 种基金the Open bidding for selecting the best candidates of Baoding(2023chuang206)the High-level Talent Research Startup Project of Hebei University(521100221085)the Post-graduate's Innovation Fund Project of Hebei University(HBU2024BS030).
文摘Despite sulfurization offers the advantage of improving the photovoltaic performance in preparing Cu(In,Ga)Se2(CIGS)absorbers,deep level defects in the absorber and poor energy level alignment on the front surface are still main obstacles limiting the improvement of power co nversion efficiency(PCE)in sulfided CIGS solar cells.Herein,an in-situ Na doping strategy is proposed,in which the tailing effect of crystal growth is used to promote the sulfurization of CIGS absorbers.It is found that the grain growth is supported by Na incorporating due to the enrichment of NaSe_(x)near the upper surface.The high soluble Na during grain growth can not only suppress intrinsic In_(Cu) donor defects in the absorber,but also tailor S distribution in bulk and the band alignment at the heterojunction,which are both beneficial for the effective electron carriers.Meanwhile,the Na aggregation near the bottom of the absorber also contributes to the crystalline quality increasing and favorable ultra-thin MoSe_(2) formation at back contact,resulting in a reduced barrier height conducive to hole transport.PCE of the champion device is as high as 16.76%with a 28%increase.This research offers new insights into synthesizing CIGS solar cells and other chalcogenide solar cells with superior cell performance when using an intense sulfurization process.
基金supported by the National Key R&D Program of China(No.2022YFC3702203)the National Natural Science Foundation of China(Nos.42030706,and 42277405).
文摘Contaminants in the water environment of different pyritemines have varying characteristics due to different geological origins.Sulfur isotope(δ^(34)S)is an effective tool to reveal the mechanism of water environment contamination,but no investigations have yet analyzed the characteristics and environmental significance of the δ^(34)S in the water environment of different pyritemines.This study involved a field investigation of four typical pyritemines in China(representing volcanic,skarn,sedimentary-metamorphic,and coal-deposited types)and the analysis of the hydrochemistry of aqueous samples and the δ^(34)S of both pyrite and dissolved sulfates.The S isotopes in minerals of different types of mines were associated with the deposit genesis,and S isotopes in the water environment were affected by sulfide minerals and indicative of the contaminant sources,types of contaminants,and contaminant transport processes.The environmental significance of δ^(34)S in the water environment was further explored and a contamination model for pyrite mines established based on S isotope data.The study offers a theoretical foundation for further research on the prevention,control,and management of water pollution at various types of pyrite mines.
基金supported by the National Natural Science Foundation of China(Nos.21925601 and 22127811).
文摘Atmospheric dimethyl sulfide(DMS,CH_(3)SCH_(3))and methanethiol(MeSH,CH_(3)SH)have been widely studied and recognized to significantly constrain the atmospheric sulfur budget.Nevertheless,while the role of DMS and MeSH remains largely uncertain in inland regions,learning about dimethyl disulfide(DMDS,CH_(3)SSCH_(3))is also limited.In this study,we measured atmospheric DMS,MeSH and DMDS in winter,from 19 December 2022 to 30 January 2023,and spring,from 24 April to 2 June 2023 with a Vocus proton-transfer-reaction time-offlightmass spectrometer(Vocus PTR-TOF)at the Dianshan Lake(DSL)Air QualityMonitoring Supersite in a suburban area of Shanghai,China.The mixing ratios of DMS,MeSH and DMDS exhibited clear diurnal cycles,and were characterized by average and interquartile range values of 22.6(10.1-29.7),14.9(6.5-19.4)and 9.8(6.0-10.7)pptv,respectively,in the spring campaign,which are approximately twice as high as those in winter.MeSH and DMDS were found to be well correlated with DMS in the two campaigns.Wind analysis suggests that three reduced-sulfur compounds owned common sources from the DSL.Furthermore,the sulfur dioxide(SO_(2))production quantity fromthe three reduced-sulfur compounds over the DSL inMay 2023 was estimated to be 1.42±0.74 t with 84.8%originating fromDMDS,which was comparable to the monthly SO_(2) emissions fromships over the DSL.Our results highlight the prominent role of atmospheric DMDS in SO_(2) production when compared to DMS and MeSH in the suburban area of Shanghai,soliciting further investigation and consideration of DMDS in the sulfur budget.
基金Songshan Lake Materials Laboratory(2022SLABFN26)National Natural Science Foundation of China(21773024).
文摘Lithium-sulfur(Li–S) battery has become one of the most promising next-generation electrical storage systems because of its exceptional energy density of 2600 Wh kg^(-1). However, their commercialization is hindered by several key obstacles, notably the polysulfide shuttle effect,poor electrical conductance of sulfur, and considerable volumetric change during cycling. This review addresses current advancements in microstructural innovations aimed at improving Li–S battery performance, focusing on modifying cathode materials. The strategies discussed primarily revolve around enhancing the conductivity of sulfur and effectively confining polysulfides to reduce the dissolving of lithium polysulfides in organic electrolytes. Key findings highlight the effectiveness of porous carbon structures and metal compounds in stabilizing polysulfides and enhancing electrochemical performances. Additionally, the roles of advanced synthesis techniques that facilitate the creation of hybrid cathodes with superior mechanical properties and cycling stability are summarized. By addressing the inherent limitations of traditional Li–S battery designs, these innovations pave the way for more efficient and reliable energy storage systems, positioning Li–S technology as a viable alternative to conventional lithium-ion batteries in future applications.
基金supported by the National Natural Science Foundation of China(22379069,22109072)the Fundamental Research Funds for the Central Universities(30922010304)。
文摘Lithium-sulfur(Li-S)batteries hold great promise for next-generation energy storage,yet suffer from sluggish redox kinetics and polysulfide shuttling.Herein,a novel Ni_(3)S_(2)/Ni_(2)B heterostructure is developed to improve sulfur electrochemistry by synergistically enhancing polysulfide fixation and catalytic conversions.Fabricated through mild sequential boronation and sulfurization,this hybrid nanocatalyst integrates the strong polysulfide adsorbability and high conductivity of Ni_(2)B with the high catalytic activity of Ni_(3)S_(2).More importantly,the as-constructed heterointerface inspires new,highly catalytic sites that smooth consecutive sulfur conversions with lower energy barriers,while the built-in electric fields promote directional charge transfer,collectively contributing to fast-kinetic and highly efficient sulfur redox reactions.As a result,Li-S cells incorporating the Ni_(3)S_(2)/Ni_(2)B nanocatalyst exhibit excellent cyclability,with minimal capacity decay of 0.017%per cycle over 900 cycles at 1 C and a superb rate capability of up to 5 C.Even under demanding conditions,such as a high sulfur loading of 5.0 mg cm^(-2)and a low electrolyte-to-sulfur(E/S)ratio of 4.8 mL g^(-1),high capacity and cyclability are maintained,highlighting the great potential of this unique heterointerface engineering in advancing high-performance and practically viable Li-S batteries.
基金financially supported by the Fundamental Research Funds for the Central Universities of Central South University(2023ZZTS0506).
文摘Sulfuric acid slag,a common byproduct with high iron content,poses challenges due to its high levels of harmful impurities and is often discarded as solid waste,leading to significant environmental and water pollution.To address this issue and improve resource utilization,the preparation process of oxidized pellets from sulfuric acid slag was studied,exploring suitable pelletizing systems and thermal parameters.Additionally,the removal of harmful elements and the consolidation mechanism were established during the oxidation roasting process.The findings revealed that sulfuric acid slag along with specific processing conditions,such as using two high-pressure grinding rolls and adding 1.25 wt.%bentonite,resulted in the production of qualified green pellets with desirable physical properties.Through a thermal treatment process involving preheating and roasting,the desulfurization rate of the pellets reached 95.55%and the removal efficiency of arsenic achieved 27.11%.Hematite recrystallizes,shrinks,and forms a reticulated structure with Fe2O3 recrystallization as the backbone,resulting in higher consolidation strength.
基金Supported by the Fourth Batch of Innovative Research Team Project at Zhaoqing University(TD202408)the 2024 Zhaoqing University Quality Engineering and Teaching Reform Project(zlgc2024002,zlgc2024092)+3 种基金the Ideological and Political Reform Demonstration Project of School-level Course at Zhaoqing College in 2024(Zhaoqing University[2024]83)the Zhaoqing University s"Double Hundred Project"Special General Project in 2025(SD202508)the 2025 Guangdong Province Graduate Education Innovation Plan Project(2025JGXM_177)the 2025 Guangdong Provincial Project for Young Innovative Talents in Ordinary Universities(2025KQNCX098).
文摘The absorption of air pollutants is an indicator for studying the value of forest land.It plays an important role in compiling resource balance sheets by studying the absorption of air pollutants by forest land.This paper focused on sulfur dioxide,an air pollutant.Through on-site air sample collection and laboratory testing,using the calculation method of the UFORE model issued by the US Forestry Administration,the annual absorption data of sulfur dioxide in different forest lands in Dapeng New Area were obtained.The results showed that there was not much difference in the absorption capacity of sulfur dioxide among the three types of forest lands in the new area:shrubland,broad-leaved forest,and artificial forest.The amount of sulfur dioxide absorbed per unit area ranged from 11.80 to 13.62 kg/(hm^(2)·a).However,coniferous forests had a lower absorption capacity for sulfur dioxide,with an absorption per unit area of 5.39 kg/(hm^(2)·a).
