National Center for Nanoscience and Technology(NCNST),China,established in December 2003,is co-founded by the Chinese Academy of Sciences(CAS)and the Ministry of Education as an institution dedicated to fundamental an...National Center for Nanoscience and Technology(NCNST),China,established in December 2003,is co-founded by the Chinese Academy of Sciences(CAS)and the Ministry of Education as an institution dedicated to fundamental and applied researches in the field of nanoscience and technology,especially those with important potential applications.NCNST is operated under the supervision of the Governing Board and aims to become a world-class research center,as well as public technological platform and young talents training center in the field,and to act as an important bridge for international academic exchange and collaboration.The NCNST currently has three CAS Key Laboratories:the CAS Key Laboratory for Biological Effects of Nanomaterials and Nanosafety,the CAS Key Laboratory for Standardization and Measurement for Nanotechnology and the CAS Key Laboratory for Nanosystem and Hierarchical Fabrication.In 2020,the CAS Key Laboratory of Nanophotonic Materials and Devices started construction.Besides,there are Division of Nanotechnology Development,Nanofabrication Laboratory,Intelligent Nanosensing Laboratory and Theoretical Laboratory.展开更多
Drug-resistant bacteria,using their dense cell membranes as strong barrier,significantly reduce the efficacy of conventional antibacterial treatments.Phototriggered 2D catalytic nanomaterials have emerged as promising...Drug-resistant bacteria,using their dense cell membranes as strong barrier,significantly reduce the efficacy of conventional antibacterial treatments.Phototriggered 2D catalytic nanomaterials have emerged as promising candidates against drug-resistant bacteria by inducing membrane mechanical damage and generating reactive oxygen species(ROS).However,the practical antibacterial efficacy of typical 2D graphitic carbon nitride(g-C_(3)N_(4))is severely limited due to the low ROS production.Herein,we report an interfacial band-engineered lamellar heterojunctions(MnCN LHJs)through in situ Mn_(2)O_(3)growth on g-C_(3)N_(4).The charges generated in g-C_(3)N_(4)are stabilized by Mn_(2)O_(3),minimizing electron-hole recombination and boosting ROS production.Meanwhile,the photocatalytic effect of MnCN LHJs works synergistically with photothermal effects of Mn_(2)O_(3)to induce a robust“melee attack”against drug-resistant bacteria.High-resolution synchrotron radiation X-ray tomography directly visualized that MnCN LHJs possessed bacterial trapping capabilities,revealing their ability to induce mechanical damage to bacteria membrane for the first time.Additionally,MnCN LHJs can deplete endogenous glutathione,thereby enhancing ROS generation and weakening the bacterial antioxidant defense system.These combined effects achieve a remarkable bactericidal rate exceeding 98% against methicillin-resistant Staphylococcus aureus(MRSA).Notably,MnCN LHJs demonstrate prolonged retention at wound sites,helping to reduce inflammation and promote angiogenesis in infected wounds.This work not only advances interfacial band engineering approach to enhance the photocatalytic performance of g-C_(3)N_(4)but also underscores the significance of nanomaterial-bacteria interaction in design of next-generation antibacterial materials.展开更多
Spinal cord injuries lead to significant loss of motor, sensory, and autonomic functions, presenting major challenges in neural regeneration. Achieving effective therapeutic concentrations at injury sites has been a s...Spinal cord injuries lead to significant loss of motor, sensory, and autonomic functions, presenting major challenges in neural regeneration. Achieving effective therapeutic concentrations at injury sites has been a slow process, partly due to the difficulty of delivering drugs effectively. Nanoparticles, with their targeted delivery capabilities, biocompatibility, and enhanced bioavailability over conventional drugs, are garnering attention for spinal cord injury treatment. This review explores the current mechanisms and shortcomings of existing treatments, highlighting the benefits and progress of nanoparticle-based approaches. We detail nanoparticle delivery methods for spinal cord injury, including local and intravenous injections, oral delivery, and biomaterial-assisted implantation, alongside strategies such as drug loading and surface modification. The discussion extends to how nanoparticles aid in reducing oxidative stress, dampening inflammation, fostering neural regeneration, and promoting angiogenesis. We summarize the use of various types of nanoparticles for treating spinal cord injuries, including metallic, polymeric, protein-based, inorganic non-metallic, and lipid nanoparticles. We also discuss the challenges faced, such as biosafety, effectiveness in humans, precise dosage control, standardization of production and characterization, immune responses, and targeted delivery in vivo. Additionally, we explore future directions, such as improving biosafety, standardizing manufacturing and characterization processes, and advancing human trials. Nanoparticles have shown considerable progress in targeted delivery and enhancing treatment efficacy for spinal cord injuries, presenting significant potential for clinical use and drug development.展开更多
Aluminum-water(Al-H_(2)O)propellants represent an innovative class of solid propellants characterized by low cost and minimal signal signature.However,conventional formulations are hindered by significant aluminum(Al)...Aluminum-water(Al-H_(2)O)propellants represent an innovative class of solid propellants characterized by low cost and minimal signal signature.However,conventional formulations are hindered by significant aluminum(Al)agglomeration,leading to reduced combustion efficiency and substantial residues.This study introduces a method for modifying Al powder with Polyvinylidene Fluoride(PVDF)to enhance the performance of Al-H_(2)O propellants by mitigating agglomeration during combustion.Experimental methodologies,including thermogravimetric analysis under ambient-pressure nitrogen atmosphere and laser ignition tests,were employed to investigate the influence of varying PVDF content on the combustion characteristics of the propellants.Furthermore,the effect of PVDF on motor performance was systematically evaluated through laboratoryscale Solid Rocket Motor(SRM)tests.The results demonstrate that the addition of 7.5%PVDF significantly enhances the burning rate from 1.12 mm/s to 3.78 mm/s and reduces the mean particle size of condensed combustion products from 699μm to 527μm.Combustion efficiency rises from88.57%to 94.51%,while injection efficiency improves significantly from 30.45%to 70.45%.SRM tests further demonstrate an increase in combustion chamber pressure from 0.17 MPa to 0.58 MPa.A dynamic agglomeration model explains these improvements,attributing reduced agglomeration to enhanced aerodynamic forces and a thinner melting layer,while increased gas yield improves injection performance.This study highlights PVDF's potential in advancing Al-H_(2)O propellants by improving combustion and injection efficiency.展开更多
In the context of the global pursuit of sustainable energy,dual-atom catalysts(DACs)have attracted widespread attention due to their unique structural and excellent catalytic performance.Unlike the single-atom catalys...In the context of the global pursuit of sustainable energy,dual-atom catalysts(DACs)have attracted widespread attention due to their unique structural and excellent catalytic performance.Unlike the single-atom catalysts,DACs possess two active metal centers,exhibiting intriguing synergistic effects that significantly enhance their efficiency in various electrochemical reactions.This comprehensive review provides an overview of the recent advances in the field of dual-atom catalysts,focusing on their innovative preparation methods and strategies.It further delves into the intrinsic connections between structure and performance,discussing the applications of DACs in hydrogen evolution reaction,oxygen evolution reaction,oxygen reduction reaction,photocatalysis,carbon dioxide reduction reaction,and batteries.Lastly,a forward-looking perspective addresses the current challenges and outlines future directions.This review aims to deepen our understanding of DACs and stimulate further innovation in advanced catalysts for energy conversion systems.展开更多
Bacterial infections have seriously impaired the wound healing.Despite numerous antibiotics have been developed to inhibit bacteria,the emergence of antibiotic resistance necessitates a rethinking of the public health...Bacterial infections have seriously impaired the wound healing.Despite numerous antibiotics have been developed to inhibit bacteria,the emergence of antibiotic resistance necessitates a rethinking of the public health crisis.In this study,we introduce the carbon dots derived from metformin and dopamine(MD-CDs)as a novel approach to promote the healing of bacterial-infected wound.Through a hydrothermal reaction,the regularly spherical MD-CDs were prepared.Owing to their inherent antibacterial property,MD-CDs effectively inhibited the wound infection and expedited the transition from the inflammation phase to the healing phase in infected wound.Additionally,MD-CDs enhanced the proliferation and migration of L929 cells,which is crucial for wound tissue regeneration.Following the treatment of infected fullthickness skin wounds,MD-CDs effectively promoted the collagen deposition and regeneration of hair follicle in the healing phase.Consequently,MD-CDs represent a bioactive nanomaterial exhibiting inherent antibacterial,offering a promising alternative for the treatment of infected wounds.展开更多
Benzotriazole(BTA)-based A_(2)-A_1-D-A_1-A_(2)type wide-bandgap(WBG)non-fullerene acceptors(NFAs)have shown promising potential in indoor photovoltaic,and in-depth investigation of their structure-property relationshi...Benzotriazole(BTA)-based A_(2)-A_1-D-A_1-A_(2)type wide-bandgap(WBG)non-fullerene acceptors(NFAs)have shown promising potential in indoor photovoltaic,and in-depth investigation of their structure-property relationship is of great significance.Herein,we explored the chlorination effect of the side chain on the terminals.We introduced Cl atoms into the benzyl side chains in parent BTA5 to synthesize two NFAs,BTA5-Cl with mono-chlorinated benzyl groups and BTA5-2Cl containing bi-chlorinated benzyl groups.We chose D18-Cl with deep-energy levels and strong crystallinity to pair with these three acceptors,affording high photovoltage and photocurrent.With the stepwise chlorination,the open-circuit voltage(V_(OC))values decrease from 1.28,1.22,to 1.20 V,while the corresponding power conversion efficiencies(PCEs)improve from 5.07%,9.15%,to 10.96%.Compared with BTA5-based OSCs,introducing Cl atoms downshifts the energy levels and slightly increases the non-radiative energy loss(0.14<0.17<0.19 e V),resulting in a sequential decrease in VO C.However,more chlorine atom replacements produce more effective exciton dissociation,higher charge transfer,and balanced carrier mobility in the blend films,ultimately achieving better PCEs.This work indicates that chlorination of the benzyl group on the terminals can improve the device's performance,implying good application potential in indoor photovoltaics.展开更多
Research interest in the electrochemical reduction reaction of carbon dioxide(CO_(2)RR)into multicarbon(C_(2+))compounds has been growing significantly with numerous theoretical and experimental studies employing a va...Research interest in the electrochemical reduction reaction of carbon dioxide(CO_(2)RR)into multicarbon(C_(2+))compounds has been growing significantly with numerous theoretical and experimental studies employing a variety of surface modification techniques,such as strong support interactions,heteroatom doping,surface functionalization,and morphology and defect engineering.The collective goal of these strategies is to fine-tune the electrochemical properties of catalysts,thereby breaking the C-C coupling barrier to achieve efficient and selective formation of C_(2+)products.In this review,we critically examine these research efforts,with a particular focus on achieving a comprehensive understanding of the innovative catalyst surface that dictates pathways for electrochemical CO_(2)RR to C_(2+)compounds.We begin by discussing the essential characteristics of catalyst surfaces that demonstrate superior catalytic activity and selectivity.Next,we explore the range of strategies used to create conducive catalyst surfaces.Finally,we provide an overview of catalytic performance and selectivity of materials in synthesizing C_(2+)products based on some high-throughput density functional theory and machine learning screening techniques.展开更多
The assembly behaviors of two low-symmetric carboxylic acid molecules(50-(6-carboxynaphthalen-2-yl)-[1,10:30,100-triphenyl]-3,400,5-tricarboxylic acid(CTTA)and 30,50-bis(6-carboxynaphthalen-2-yl)-[1,10-biphenyl]-3,5-d...The assembly behaviors of two low-symmetric carboxylic acid molecules(50-(6-carboxynaphthalen-2-yl)-[1,10:30,100-triphenyl]-3,400,5-tricarboxylic acid(CTTA)and 30,50-bis(6-carboxynaphthalen-2-yl)-[1,10-biphenyl]-3,5-dicarboxylic acid(BCBDA))containing naphthalene rings on graphite surfaces have been investigated using scanning tunneling microscopy(STM).The transformation of nanostructures induced by the second components(EDA and PEBP-C4)have been also examined.Both CTTA and BCBDA molecules self-assemble at the 1-heptanoic acid(HA)/HOPG interface,forming porous network structures.The dimer represents the most elementary building unit due to the formation of double hydrogen bonds.Moreover,the flipping of naphthalene ring results in the isomerization of BCBDA molecule.The introduction of carboxylic acid derivative EDA disrupts the dimer,which subsequently undergoes a structural conformation to form a novel porous structure.Furthermore,upon the addition of pyridine derivative PEBP-C4,N–H⋯O hydrogen bonds are the dominant forces driving the three coassembled structures.We have also conducted density functional theory(DFT)calculations to determine the molecular conformation and analyze the mechanisms underlying the formation of nanostructures.展开更多
Bacterial pollution poses a serious threat to human health,making it essential to design and utilize efficient non-antibiotic antibacterial materials.Here,ZIF-8 with different metal-N sites is successfully prepared by...Bacterial pollution poses a serious threat to human health,making it essential to design and utilize efficient non-antibiotic antibacterial materials.Here,ZIF-8 with different metal-N sites is successfully prepared by introducing divalent metals(Mg^(2+),Mn^(2+),Co^(2+)and Cu^(2+))directly into the ZIF-8 framework.ZIF-8 with Cu-Nx sites has the best antibacterial activity,with antibacterial rates of 99.8%and 81.1%against Escherichia coli and Staphylococcus aureus after 1 h at a concentration of 10μg/mL,respectively.More importantly,an antibacterial rate of more than 86.7%can be achieved against multidrug-resistant bacteria MRSA,much higher than Vancomycin.The results show that the introduction of copper could significantly improve the electron transfer,the generation of reactive oxygen species(ROS),the binding affinity with bacteria,and eventually achieve excellent antibacterial activity.DFT calculations show easier oxygen activation at the unsaturated Cu-Nx site.The revealed oxygen activation mechanism sheds light on understanding the high antibacterial activity of the active site of the nanoparticles.Cu-ZIF-8 offers significant advantages in the field of air disinfection.展开更多
The 2D/3D heterojunction perovskites have garnered increasing attention due to their exceptional moisture and thermal stability.However,few works have paid attention to the influence of the subsequent change process o...The 2D/3D heterojunction perovskites have garnered increasing attention due to their exceptional moisture and thermal stability.However,few works have paid attention to the influence of the subsequent change process of 2D/3D heterojunction PSC on the stability of PSCs.Moreover,the evolution of the interface and carrier dynamic behavior of the 2D/3D perovskite films with long-term operation has not been systematically developed befo re.In this work,the effects of 2D/3 D heterojunction evolution on the interface of perovskite films and different carrier dynamics during 2D/3D evolution are systematically analyzed for the first time.The decomposition of 2D/3D heterojunction in the perovskite film will have a certain impact on the surface and carrier dynamics behavior of perovskite.During the evolution of 2D/3D heterojunction,PbI_(2)crystals will appear,which will improve the interfacial energy level matching between the electron transport layer and perovskite film.With a long evolution time,some holes will appear on the surface of perovskite film.The open circuit voltage(V_(OC))of PSCs increased from 1.14 to1.18 V and the PCE increased to 23.21%after 300 h storage in the nitrogen atmosphere,and maintained 89%initial performance for with 3000 h stability test in N_(2)box.This discovery has a significant role in promoting the development of inverted heterojunction PSCs and constructing the revolution mechanism of charge carrier dynamic.展开更多
The continuous increase in petroleum-based plastic food packaging has led to numerous environmental concerns.One effort to reduce the use of plastic packaging in food is through preservation using biopolymer-based pac...The continuous increase in petroleum-based plastic food packaging has led to numerous environmental concerns.One effort to reduce the use of plastic packaging in food is through preservation using biopolymer-based packaging.Among the many types of biopolymers,chitosan is widely used and researched due to its non-toxic,antimicrobial,and antifungal properties.Chitosan is widely available since it is a compound extracted from seafood waste,especially shrimps and crabs.The biodegradability and biocompatibility of chitosan also showed good potential for various applications.These characteristics and propertiesmake chitosan an attractive biopolymer to be implemented as food packaging in films and coatings.Chitosan has been tested in maintaining and increasing the shelf life of food,especially seafood such as fish and shrimp,and post-harvest products such as fruits and vegetables.In addition to its various advantages,the properties and characteristics of chitosan need to be improved to produce optimal preservation.The properties and characteristics of chitosan are improved by adding various types of additive materials such as biopolymers,plant extracts,essential oils,and metal nanoparticles.Research shows that material additives and nanotechnology can improve the quality of chitosan-based food packaging for various types of food by enhancing mechanical properties,thermal stability,antimicrobial activity,and antioxidant activity.This review provides a perspective on the recent development and properties enhancement of chitosan composite with additives and nanotechnology,as well as this material’s challenges and prospects as food packaging.展开更多
The rational design of Ni-based catalysts is essential due to their abundance and low cost for advancing sustainable energy technologies,particularly for water splitting and fuel cells.This study employs spinpolarized...The rational design of Ni-based catalysts is essential due to their abundance and low cost for advancing sustainable energy technologies,particularly for water splitting and fuel cells.This study employs spinpolarized density functional theory(DFT)to examine the influence of anchoring rare-earth elements on the γ-NiOOH lattice surface,aiming to identify the optimal catalytic site for the oxygen evolution reaction(OER)and oxygen reduction reaction(ORR).Following the identification of an appropriate active site through Ni vacancy,a rare earth element(REE_(1))is introduced as a dopant for single-atom catalysis(SACs).The structural,thermodynamic,and catalytic characteristics of all newly designed REE_(1)/γ-NiOOH catalysts have been extensively studied.Among the newly developed catalysts,Tb_(1)/γ-NiOOH exhibits the lowest OER overpotential of(0.36 V),while Ce_(1)/γ-NiOOH and Pr_(1)/γ-NiOOH also demonstrate excellent OER performance(0.51 and 0.41 V),respectively.Notably,Nd_(1)/γ-NiOOH and Pm_(1)/γ-NiOOH exhibit efficient ORR activity,with low overpotentials of(0.63 and 0.61 V)due to their balanced adsorption and desorption energies of intermediates.Bader charge analysis reveals strong electron donation from doped REE1to the surface.This study identified Ce_(1),Pr_(1),Nd_(1),and Tb_(1) anchoring catalysts as highly promising for water-splitting applications.Moreover,Nd_(1) and Pm_(1) doping markedly improve ORR performance,underscoring their promise for enhanced electrochemical applications in metal-air batteries.The catalytic performance of all newly developed catalysts was further evaluated using electronic descriptors.The catalytic performance was further assessed using the volcano curve and scaling relationships for the adsorbed intermediates.This study offers an extensive theoretical foundation for designing cost-effective and high-performance REE_(1)/γ-NiOOH electrocatalysts.展开更多
Environmental catalysis has been considered one of the important research topics.Some technologies(e.g.,photocatalysis and electrocatalysis)have been intensively developed with the advance of synthetic technologies of...Environmental catalysis has been considered one of the important research topics.Some technologies(e.g.,photocatalysis and electrocatalysis)have been intensively developed with the advance of synthetic technologies of catalytical materials.In 2019,we discussed the development trend of this field,and wrote a roadmap on this topic in Chinese Chemical Letters(30(2019)2065-2088).Nowadays,we discuss it again from a new viewpoint along this road.In this paper,several subtopics are discussed,e.g.,photocatalysis based on titanium dioxide,violet phosphorus,graphitic carbon and covalent organic frameworks,electrocatalysts based on carbon,metal-and covalent-organic framework.Finally,we hope that this roadmap can enrich the development of two-dimensional materials in environmental catalysis with novel understanding,and give useful inspiration to explore new catalysts for practical applications.展开更多
Perovskite materials have emerged as highly promising frontier materials for a wide range of optoelectronic applications,including solar cells,light-emitting diodes(LEDs),lasers,and photodetectors(PDs).Taking perovski...Perovskite materials have emerged as highly promising frontier materials for a wide range of optoelectronic applications,including solar cells,light-emitting diodes(LEDs),lasers,and photodetectors(PDs).Taking perovskite-based solar cells(PSCs)as a representative example,these devices demonstrate significant advantages over traditional silicon-based solar cells,such as low costs,high power conversion efficiency(PCE),and exceptional light absorption capabilities.However,residual strain inherent to the fabrication process unavoidably degrades the device performance and consistency.This review comprehensively presents the latest developments in strain regulation techniques at the nanoscale in perovskite materials,first elucidating the concept of residual strain and its intricate relationship with various physicochemical properties.The discussion then delves into the underlying mechanisms of residual strain regulation at the nanoscale.This review discusses specific engineering strategies for residual strain regulation in perovskite-based optoelectronic devices,including solar cells,LEDs,lasers,and PDs.By systematically examining the definition,mechanisms,and methodologies of strain regulation in nanoscale perovskite materials,the review provides a comprehensive framework for understanding its critical role in device performance.Furthermore,this review also identifies and clarifies the key challenges hindering the advancement of high-performance perovskite-based devices,laying a solid foundation for future research directions in this rapidly evolving field.展开更多
Inspired by sophisticated biological structures and their physiological processes, supramolecular chemistry has been developed for understanding and mimicking the behaviors of natural species. Through spontaneous self...Inspired by sophisticated biological structures and their physiological processes, supramolecular chemistry has been developed for understanding and mimicking the behaviors of natural species. Through spontaneous self-assembly of functional building blocks, we are able to control the structures and regulate the functions of resulting supramolecular assemblies. Up to now, numerous functional supramolecular assemblies have been constructed and successfully employed as molecular devices, machines and biological diagnostic platforms. This review will focus on molecular structures of functional molecular building blocks and their assembled superstructures for biological detection and delivery.展开更多
In the fight against cancer, controlled drug delivery systems have emerged to enhance the therapeutic efficacy and safety of anti-cancer drugs. Among these systems, mesoporous silica nanoparticles (MSNs) with a func...In the fight against cancer, controlled drug delivery systems have emerged to enhance the therapeutic efficacy and safety of anti-cancer drugs. Among these systems, mesoporous silica nanoparticles (MSNs) with a functional surface possess obvious advantages and were thus rapidly developed for cancer treatment. Many stimuli-responsive materials, such as nanopartides, polymers, and inorganic materials, have been applied as caps and gatekeepers to control drug release from MSNs. This review presents an overview of the recent progress in the production of pH-responsive MSNs based on the pH gradient between normal tissues and the tumor microenvironment. Four main categories of gatekeepers can respond to acidic conditions. These categories will be described in detail.展开更多
SnO2-reduced graphene oxide (SnO2-rGO) composites were prepared via a hydro-thermal reaction of graphene oxide (GO) and SnCI2·2H2O in the mixed solvent of ethylene glycol and water. During the redox reaction,...SnO2-reduced graphene oxide (SnO2-rGO) composites were prepared via a hydro-thermal reaction of graphene oxide (GO) and SnCI2·2H2O in the mixed solvent of ethylene glycol and water. During the redox reaction, GO was reduced to rGO while Sn2+ was oxidized to Sn02, uniformly depositing on the surface of rGO sheets. The composites were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), thermogravimetric analysis (TGA), infrared spectra analysis (IR) and transmission electron microscopy (TEM), respectively, and their gas sensing properties were further investigated. Compared with pure SnO2 nanoparticles, the as-prepared SnO2-rGO gas sensor and response-recovery time to ethanol and H2S at responding and low cost SnO2-rGO gas sensor could showed much better gas sensing behavior in sensitivity ow concentrations. Overall, the highly sensitive, quick- be potentially applied in environmental monitoring area.展开更多
superstructures has enormous potential in material sciences and engineering. Despite the potential,controlled assembly of different kinds of NPs into spatially addressable hybrid configurations still remains a formida...superstructures has enormous potential in material sciences and engineering. Despite the potential,controlled assembly of different kinds of NPs into spatially addressable hybrid configurations still remains a formidable challenge. Herein, we report a simple and universal strategy for DNA-mediated assembly of CdTe quantum dots(QDs) and lanthanide-doped upconversion nanoparticles(UCNPs). Such DNA-QD/UCNPs heterostructures not only maintains both fluorescent properties of QDs and upconversion luminescence behaviors of UCNPs, but also offers a polyvalent DNA surface, allowing for targeted dual-modality imaging of cancer cells using an aptamer. The hetero-assembly mediated by the DNA à inorganic interfacial interaction may provide a scalable way to fabricate hybrid superstructures of both theoretical and practical interests.展开更多
In this research highlight,recent significant advances with hot-assisted blade-coating or air knife-assisted blade-coating of different perovskite compositions with bandgaps ranging from 1.3 eV to 1.9 eV(i.e.widebandg...In this research highlight,recent significant advances with hot-assisted blade-coating or air knife-assisted blade-coating of different perovskite compositions with bandgaps ranging from 1.3 eV to 1.9 eV(i.e.widebandgap or small-bandgap perovskites with mixed cations and anions,2D/3D perovskites,Pb/Sn binary perovskites,and all-inorganic perovskites)for single-junction or tandem PSCs are discussed,with an emphasis on elucidating the distinct ink formulation engineering strategies,crystal growth mechanisms,crystallization kinetics,and optoelectronic properties of the different perovskite compositions.展开更多
文摘National Center for Nanoscience and Technology(NCNST),China,established in December 2003,is co-founded by the Chinese Academy of Sciences(CAS)and the Ministry of Education as an institution dedicated to fundamental and applied researches in the field of nanoscience and technology,especially those with important potential applications.NCNST is operated under the supervision of the Governing Board and aims to become a world-class research center,as well as public technological platform and young talents training center in the field,and to act as an important bridge for international academic exchange and collaboration.The NCNST currently has three CAS Key Laboratories:the CAS Key Laboratory for Biological Effects of Nanomaterials and Nanosafety,the CAS Key Laboratory for Standardization and Measurement for Nanotechnology and the CAS Key Laboratory for Nanosystem and Hierarchical Fabrication.In 2020,the CAS Key Laboratory of Nanophotonic Materials and Devices started construction.Besides,there are Division of Nanotechnology Development,Nanofabrication Laboratory,Intelligent Nanosensing Laboratory and Theoretical Laboratory.
基金financially supported by the National Basic Research Program of China(Nos.2022YFA1603701,2024YFC2310502,and 2024YFC2310503)the National Natural Science Foundation of China(Nos.22422403,82341044,and 22027810)+1 种基金the New Cornerstone Science Foundation(No.NCI202318)the Basic Science Center Project of the National Natural Science Foundation of China(No.22388101).
文摘Drug-resistant bacteria,using their dense cell membranes as strong barrier,significantly reduce the efficacy of conventional antibacterial treatments.Phototriggered 2D catalytic nanomaterials have emerged as promising candidates against drug-resistant bacteria by inducing membrane mechanical damage and generating reactive oxygen species(ROS).However,the practical antibacterial efficacy of typical 2D graphitic carbon nitride(g-C_(3)N_(4))is severely limited due to the low ROS production.Herein,we report an interfacial band-engineered lamellar heterojunctions(MnCN LHJs)through in situ Mn_(2)O_(3)growth on g-C_(3)N_(4).The charges generated in g-C_(3)N_(4)are stabilized by Mn_(2)O_(3),minimizing electron-hole recombination and boosting ROS production.Meanwhile,the photocatalytic effect of MnCN LHJs works synergistically with photothermal effects of Mn_(2)O_(3)to induce a robust“melee attack”against drug-resistant bacteria.High-resolution synchrotron radiation X-ray tomography directly visualized that MnCN LHJs possessed bacterial trapping capabilities,revealing their ability to induce mechanical damage to bacteria membrane for the first time.Additionally,MnCN LHJs can deplete endogenous glutathione,thereby enhancing ROS generation and weakening the bacterial antioxidant defense system.These combined effects achieve a remarkable bactericidal rate exceeding 98% against methicillin-resistant Staphylococcus aureus(MRSA).Notably,MnCN LHJs demonstrate prolonged retention at wound sites,helping to reduce inflammation and promote angiogenesis in infected wounds.This work not only advances interfacial band engineering approach to enhance the photocatalytic performance of g-C_(3)N_(4)but also underscores the significance of nanomaterial-bacteria interaction in design of next-generation antibacterial materials.
基金supported by the Key Research Projects of Universities of Henan Province,No.21A320064 (to XS)the National Key Research and Development Program of China,No.2021YFA1201504 (to LZ)+1 种基金the Strategic Priority Research Program of the Chinese Academy of Science,No.XDB36000000 (to CW)the National Natural Science Foundation of China,Nos.31971295,12374406 (both to LZ)。
文摘Spinal cord injuries lead to significant loss of motor, sensory, and autonomic functions, presenting major challenges in neural regeneration. Achieving effective therapeutic concentrations at injury sites has been a slow process, partly due to the difficulty of delivering drugs effectively. Nanoparticles, with their targeted delivery capabilities, biocompatibility, and enhanced bioavailability over conventional drugs, are garnering attention for spinal cord injury treatment. This review explores the current mechanisms and shortcomings of existing treatments, highlighting the benefits and progress of nanoparticle-based approaches. We detail nanoparticle delivery methods for spinal cord injury, including local and intravenous injections, oral delivery, and biomaterial-assisted implantation, alongside strategies such as drug loading and surface modification. The discussion extends to how nanoparticles aid in reducing oxidative stress, dampening inflammation, fostering neural regeneration, and promoting angiogenesis. We summarize the use of various types of nanoparticles for treating spinal cord injuries, including metallic, polymeric, protein-based, inorganic non-metallic, and lipid nanoparticles. We also discuss the challenges faced, such as biosafety, effectiveness in humans, precise dosage control, standardization of production and characterization, immune responses, and targeted delivery in vivo. Additionally, we explore future directions, such as improving biosafety, standardizing manufacturing and characterization processes, and advancing human trials. Nanoparticles have shown considerable progress in targeted delivery and enhancing treatment efficacy for spinal cord injuries, presenting significant potential for clinical use and drug development.
基金supported by the National Natural Science Foundation of China(Nos.U2441284 and 22375164)the Innovation Foundation for Doctor Dissertation of Northwestern Polytechnical University,China(No.CX2024042)。
文摘Aluminum-water(Al-H_(2)O)propellants represent an innovative class of solid propellants characterized by low cost and minimal signal signature.However,conventional formulations are hindered by significant aluminum(Al)agglomeration,leading to reduced combustion efficiency and substantial residues.This study introduces a method for modifying Al powder with Polyvinylidene Fluoride(PVDF)to enhance the performance of Al-H_(2)O propellants by mitigating agglomeration during combustion.Experimental methodologies,including thermogravimetric analysis under ambient-pressure nitrogen atmosphere and laser ignition tests,were employed to investigate the influence of varying PVDF content on the combustion characteristics of the propellants.Furthermore,the effect of PVDF on motor performance was systematically evaluated through laboratoryscale Solid Rocket Motor(SRM)tests.The results demonstrate that the addition of 7.5%PVDF significantly enhances the burning rate from 1.12 mm/s to 3.78 mm/s and reduces the mean particle size of condensed combustion products from 699μm to 527μm.Combustion efficiency rises from88.57%to 94.51%,while injection efficiency improves significantly from 30.45%to 70.45%.SRM tests further demonstrate an increase in combustion chamber pressure from 0.17 MPa to 0.58 MPa.A dynamic agglomeration model explains these improvements,attributing reduced agglomeration to enhanced aerodynamic forces and a thinner melting layer,while increased gas yield improves injection performance.This study highlights PVDF's potential in advancing Al-H_(2)O propellants by improving combustion and injection efficiency.
基金supported by the China Postdoctoral Science Foundation(Nos.2021M700981,2022M711787,2021M691759 and 2021TQ0169)Shuimu Tsinghua Scholar program(No.2021SM071)Beijing Natural Science Foundation(No.2224103).
文摘In the context of the global pursuit of sustainable energy,dual-atom catalysts(DACs)have attracted widespread attention due to their unique structural and excellent catalytic performance.Unlike the single-atom catalysts,DACs possess two active metal centers,exhibiting intriguing synergistic effects that significantly enhance their efficiency in various electrochemical reactions.This comprehensive review provides an overview of the recent advances in the field of dual-atom catalysts,focusing on their innovative preparation methods and strategies.It further delves into the intrinsic connections between structure and performance,discussing the applications of DACs in hydrogen evolution reaction,oxygen evolution reaction,oxygen reduction reaction,photocatalysis,carbon dioxide reduction reaction,and batteries.Lastly,a forward-looking perspective addresses the current challenges and outlines future directions.This review aims to deepen our understanding of DACs and stimulate further innovation in advanced catalysts for energy conversion systems.
基金financially supported by the National Natural Science Foundation of China(No.52122308)the Joint Fund of Science and Technology R&D Plan of Henan Province(No.232301420042)
文摘Bacterial infections have seriously impaired the wound healing.Despite numerous antibiotics have been developed to inhibit bacteria,the emergence of antibiotic resistance necessitates a rethinking of the public health crisis.In this study,we introduce the carbon dots derived from metformin and dopamine(MD-CDs)as a novel approach to promote the healing of bacterial-infected wound.Through a hydrothermal reaction,the regularly spherical MD-CDs were prepared.Owing to their inherent antibacterial property,MD-CDs effectively inhibited the wound infection and expedited the transition from the inflammation phase to the healing phase in infected wound.Additionally,MD-CDs enhanced the proliferation and migration of L929 cells,which is crucial for wound tissue regeneration.Following the treatment of infected fullthickness skin wounds,MD-CDs effectively promoted the collagen deposition and regeneration of hair follicle in the healing phase.Consequently,MD-CDs represent a bioactive nanomaterial exhibiting inherent antibacterial,offering a promising alternative for the treatment of infected wounds.
基金support from the National Natural Science Foundation of China(Nos.52373176,52073067)。
文摘Benzotriazole(BTA)-based A_(2)-A_1-D-A_1-A_(2)type wide-bandgap(WBG)non-fullerene acceptors(NFAs)have shown promising potential in indoor photovoltaic,and in-depth investigation of their structure-property relationship is of great significance.Herein,we explored the chlorination effect of the side chain on the terminals.We introduced Cl atoms into the benzyl side chains in parent BTA5 to synthesize two NFAs,BTA5-Cl with mono-chlorinated benzyl groups and BTA5-2Cl containing bi-chlorinated benzyl groups.We chose D18-Cl with deep-energy levels and strong crystallinity to pair with these three acceptors,affording high photovoltage and photocurrent.With the stepwise chlorination,the open-circuit voltage(V_(OC))values decrease from 1.28,1.22,to 1.20 V,while the corresponding power conversion efficiencies(PCEs)improve from 5.07%,9.15%,to 10.96%.Compared with BTA5-based OSCs,introducing Cl atoms downshifts the energy levels and slightly increases the non-radiative energy loss(0.14<0.17<0.19 e V),resulting in a sequential decrease in VO C.However,more chlorine atom replacements produce more effective exciton dissociation,higher charge transfer,and balanced carrier mobility in the blend films,ultimately achieving better PCEs.This work indicates that chlorination of the benzyl group on the terminals can improve the device's performance,implying good application potential in indoor photovoltaics.
基金financial support from the National Natural Science Foundation of China(grant no.22373027)。
文摘Research interest in the electrochemical reduction reaction of carbon dioxide(CO_(2)RR)into multicarbon(C_(2+))compounds has been growing significantly with numerous theoretical and experimental studies employing a variety of surface modification techniques,such as strong support interactions,heteroatom doping,surface functionalization,and morphology and defect engineering.The collective goal of these strategies is to fine-tune the electrochemical properties of catalysts,thereby breaking the C-C coupling barrier to achieve efficient and selective formation of C_(2+)products.In this review,we critically examine these research efforts,with a particular focus on achieving a comprehensive understanding of the innovative catalyst surface that dictates pathways for electrochemical CO_(2)RR to C_(2+)compounds.We begin by discussing the essential characteristics of catalyst surfaces that demonstrate superior catalytic activity and selectivity.Next,we explore the range of strategies used to create conducive catalyst surfaces.Finally,we provide an overview of catalytic performance and selectivity of materials in synthesizing C_(2+)products based on some high-throughput density functional theory and machine learning screening techniques.
基金financially supported by the National Natural Science Foundation of China(No.22272039)the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDB36000000)+1 种基金the Youth Program of the Liaoning Education Department(No.LJKQZ20222280)the Jilin Chinese Academy of Sciences-Yanshen Technology Co.,Ltd.
文摘The assembly behaviors of two low-symmetric carboxylic acid molecules(50-(6-carboxynaphthalen-2-yl)-[1,10:30,100-triphenyl]-3,400,5-tricarboxylic acid(CTTA)and 30,50-bis(6-carboxynaphthalen-2-yl)-[1,10-biphenyl]-3,5-dicarboxylic acid(BCBDA))containing naphthalene rings on graphite surfaces have been investigated using scanning tunneling microscopy(STM).The transformation of nanostructures induced by the second components(EDA and PEBP-C4)have been also examined.Both CTTA and BCBDA molecules self-assemble at the 1-heptanoic acid(HA)/HOPG interface,forming porous network structures.The dimer represents the most elementary building unit due to the formation of double hydrogen bonds.Moreover,the flipping of naphthalene ring results in the isomerization of BCBDA molecule.The introduction of carboxylic acid derivative EDA disrupts the dimer,which subsequently undergoes a structural conformation to form a novel porous structure.Furthermore,upon the addition of pyridine derivative PEBP-C4,N–H⋯O hydrogen bonds are the dominant forces driving the three coassembled structures.We have also conducted density functional theory(DFT)calculations to determine the molecular conformation and analyze the mechanisms underlying the formation of nanostructures.
基金supported by the National Key R&D Program of China(No.2022YFC3702800).
文摘Bacterial pollution poses a serious threat to human health,making it essential to design and utilize efficient non-antibiotic antibacterial materials.Here,ZIF-8 with different metal-N sites is successfully prepared by introducing divalent metals(Mg^(2+),Mn^(2+),Co^(2+)and Cu^(2+))directly into the ZIF-8 framework.ZIF-8 with Cu-Nx sites has the best antibacterial activity,with antibacterial rates of 99.8%and 81.1%against Escherichia coli and Staphylococcus aureus after 1 h at a concentration of 10μg/mL,respectively.More importantly,an antibacterial rate of more than 86.7%can be achieved against multidrug-resistant bacteria MRSA,much higher than Vancomycin.The results show that the introduction of copper could significantly improve the electron transfer,the generation of reactive oxygen species(ROS),the binding affinity with bacteria,and eventually achieve excellent antibacterial activity.DFT calculations show easier oxygen activation at the unsaturated Cu-Nx site.The revealed oxygen activation mechanism sheds light on understanding the high antibacterial activity of the active site of the nanoparticles.Cu-ZIF-8 offers significant advantages in the field of air disinfection.
基金financial support provided by the Sichuan Science and Technology Program(No.2022NSFSC0226)Sichuan Science and Technology Program(No.2023ZYD0163)+6 种基金the Production-Education Integration Demonstration Project of Sichuan Provincethe Photovoltaic Industry Production-Education Integration Comprehensive Demonstration Base of Sichuan Province(Sichuan Financial Education[2022]No.106)China Tianfu Yongxing Laboratory Science and Technology Key Project(2023KJGG15)National Key Research and Development Program of China(2022YFB3803300)Beijing Natural Science Foundation(IS23037)the Department for Energy Security and Net Zero(project ID:NEXTCCUS)the ACT program(Accelerating CCS Technologies,Horizon2020 project NO.691712)。
文摘The 2D/3D heterojunction perovskites have garnered increasing attention due to their exceptional moisture and thermal stability.However,few works have paid attention to the influence of the subsequent change process of 2D/3D heterojunction PSC on the stability of PSCs.Moreover,the evolution of the interface and carrier dynamic behavior of the 2D/3D perovskite films with long-term operation has not been systematically developed befo re.In this work,the effects of 2D/3 D heterojunction evolution on the interface of perovskite films and different carrier dynamics during 2D/3D evolution are systematically analyzed for the first time.The decomposition of 2D/3D heterojunction in the perovskite film will have a certain impact on the surface and carrier dynamics behavior of perovskite.During the evolution of 2D/3D heterojunction,PbI_(2)crystals will appear,which will improve the interfacial energy level matching between the electron transport layer and perovskite film.With a long evolution time,some holes will appear on the surface of perovskite film.The open circuit voltage(V_(OC))of PSCs increased from 1.14 to1.18 V and the PCE increased to 23.21%after 300 h storage in the nitrogen atmosphere,and maintained 89%initial performance for with 3000 h stability test in N_(2)box.This discovery has a significant role in promoting the development of inverted heterojunction PSCs and constructing the revolution mechanism of charge carrier dynamic.
基金Penelitian Tesis Magister(PTM)Research Grant from Indonesian Government Kemdikbudristek with contract number 036/E5/PG.02.00.PL/2024.PPM1 2024 Research Grant from Faculty of Industrial Technology,ITB.
文摘The continuous increase in petroleum-based plastic food packaging has led to numerous environmental concerns.One effort to reduce the use of plastic packaging in food is through preservation using biopolymer-based packaging.Among the many types of biopolymers,chitosan is widely used and researched due to its non-toxic,antimicrobial,and antifungal properties.Chitosan is widely available since it is a compound extracted from seafood waste,especially shrimps and crabs.The biodegradability and biocompatibility of chitosan also showed good potential for various applications.These characteristics and propertiesmake chitosan an attractive biopolymer to be implemented as food packaging in films and coatings.Chitosan has been tested in maintaining and increasing the shelf life of food,especially seafood such as fish and shrimp,and post-harvest products such as fruits and vegetables.In addition to its various advantages,the properties and characteristics of chitosan need to be improved to produce optimal preservation.The properties and characteristics of chitosan are improved by adding various types of additive materials such as biopolymers,plant extracts,essential oils,and metal nanoparticles.Research shows that material additives and nanotechnology can improve the quality of chitosan-based food packaging for various types of food by enhancing mechanical properties,thermal stability,antimicrobial activity,and antioxidant activity.This review provides a perspective on the recent development and properties enhancement of chitosan composite with additives and nanotechnology,as well as this material’s challenges and prospects as food packaging.
基金supported by the BRICS STI Framework Programme(No.52261145703)the Higher Education Discipline Innovation Project(National 111 Project,No.B16016)。
文摘The rational design of Ni-based catalysts is essential due to their abundance and low cost for advancing sustainable energy technologies,particularly for water splitting and fuel cells.This study employs spinpolarized density functional theory(DFT)to examine the influence of anchoring rare-earth elements on the γ-NiOOH lattice surface,aiming to identify the optimal catalytic site for the oxygen evolution reaction(OER)and oxygen reduction reaction(ORR).Following the identification of an appropriate active site through Ni vacancy,a rare earth element(REE_(1))is introduced as a dopant for single-atom catalysis(SACs).The structural,thermodynamic,and catalytic characteristics of all newly designed REE_(1)/γ-NiOOH catalysts have been extensively studied.Among the newly developed catalysts,Tb_(1)/γ-NiOOH exhibits the lowest OER overpotential of(0.36 V),while Ce_(1)/γ-NiOOH and Pr_(1)/γ-NiOOH also demonstrate excellent OER performance(0.51 and 0.41 V),respectively.Notably,Nd_(1)/γ-NiOOH and Pm_(1)/γ-NiOOH exhibit efficient ORR activity,with low overpotentials of(0.63 and 0.61 V)due to their balanced adsorption and desorption energies of intermediates.Bader charge analysis reveals strong electron donation from doped REE1to the surface.This study identified Ce_(1),Pr_(1),Nd_(1),and Tb_(1) anchoring catalysts as highly promising for water-splitting applications.Moreover,Nd_(1) and Pm_(1) doping markedly improve ORR performance,underscoring their promise for enhanced electrochemical applications in metal-air batteries.The catalytic performance of all newly developed catalysts was further evaluated using electronic descriptors.The catalytic performance was further assessed using the volcano curve and scaling relationships for the adsorbed intermediates.This study offers an extensive theoretical foundation for designing cost-effective and high-performance REE_(1)/γ-NiOOH electrocatalysts.
基金supported by the National Natural Science Foundation of China(Nos.52272290,21972030,52073119,and 52373210)the Natural Science Foundation of Jilin Province(No.20230101029JC)+1 种基金the Fundamental Research Program of Shanxi Province(No.202303021212159)the Monash University Malaysia–ASEAN grant(No.ASE-000010)。
文摘Environmental catalysis has been considered one of the important research topics.Some technologies(e.g.,photocatalysis and electrocatalysis)have been intensively developed with the advance of synthetic technologies of catalytical materials.In 2019,we discussed the development trend of this field,and wrote a roadmap on this topic in Chinese Chemical Letters(30(2019)2065-2088).Nowadays,we discuss it again from a new viewpoint along this road.In this paper,several subtopics are discussed,e.g.,photocatalysis based on titanium dioxide,violet phosphorus,graphitic carbon and covalent organic frameworks,electrocatalysts based on carbon,metal-and covalent-organic framework.Finally,we hope that this roadmap can enrich the development of two-dimensional materials in environmental catalysis with novel understanding,and give useful inspiration to explore new catalysts for practical applications.
基金supported by the National Natural Science Foundation of China(Nos.62205011,52302189,62104090,and 11604133)the Fundamental Research Funds for the Central Universities(No.PY2507)+5 种基金the Natural Science Foundation of Shandong Province(No.ZR2017QA013)the Science and Technology Plan of Youth Innovation Team for Universities of Shandong Province(No.2019KJJ019)Wuhu science and technology program(No.2023yf024)the Research and Development Program of Beijing Municipal Education Commission(No.KM202310028013)National Key Research and Development Program of China(No.2023YFF0719400)the support of Qian Xuesen Youth Innovation Fund of CASC.
文摘Perovskite materials have emerged as highly promising frontier materials for a wide range of optoelectronic applications,including solar cells,light-emitting diodes(LEDs),lasers,and photodetectors(PDs).Taking perovskite-based solar cells(PSCs)as a representative example,these devices demonstrate significant advantages over traditional silicon-based solar cells,such as low costs,high power conversion efficiency(PCE),and exceptional light absorption capabilities.However,residual strain inherent to the fabrication process unavoidably degrades the device performance and consistency.This review comprehensively presents the latest developments in strain regulation techniques at the nanoscale in perovskite materials,first elucidating the concept of residual strain and its intricate relationship with various physicochemical properties.The discussion then delves into the underlying mechanisms of residual strain regulation at the nanoscale.This review discusses specific engineering strategies for residual strain regulation in perovskite-based optoelectronic devices,including solar cells,LEDs,lasers,and PDs.By systematically examining the definition,mechanisms,and methodologies of strain regulation in nanoscale perovskite materials,the review provides a comprehensive framework for understanding its critical role in device performance.Furthermore,this review also identifies and clarifies the key challenges hindering the advancement of high-performance perovskite-based devices,laying a solid foundation for future research directions in this rapidly evolving field.
基金supported by National Basic Research Program of China(973 Program,No.2013CB932701 )the 100-Talent program of the Chinese Academy of Sciences,Beijing Natural Science Foundation(No.2132053)Young Scientists Fund of National Natural Science Foundation(No.51102014)
文摘Inspired by sophisticated biological structures and their physiological processes, supramolecular chemistry has been developed for understanding and mimicking the behaviors of natural species. Through spontaneous self-assembly of functional building blocks, we are able to control the structures and regulate the functions of resulting supramolecular assemblies. Up to now, numerous functional supramolecular assemblies have been constructed and successfully employed as molecular devices, machines and biological diagnostic platforms. This review will focus on molecular structures of functional molecular building blocks and their assembled superstructures for biological detection and delivery.
基金supported by the Chinese Natural Science Foundation Project (Grant No. 30970784 and 81171455)a National Distinguished Young Scholars Grant (Grant No. 31225009) from the National Natural Science Foundation of China+5 种基金the National Key Basic Research Program of China (Grant No. 2009CB930200)the Chinese Academy of Sciences (CAS) ‘Hundred Talents Program’ (Grant No. 07165111ZX)the CAS Knowledge Innovation Program, and the State HighTech Development Plan (Grant No. 2012AA020804)the ‘Strategic Priority Research Program’ of the Chinese Academy of Sciences (Grant No. XDA09030301)NIH/NIMHD 8 G12 MD007597USAMRMC W81XWH-10-1-0767 grants
文摘In the fight against cancer, controlled drug delivery systems have emerged to enhance the therapeutic efficacy and safety of anti-cancer drugs. Among these systems, mesoporous silica nanoparticles (MSNs) with a functional surface possess obvious advantages and were thus rapidly developed for cancer treatment. Many stimuli-responsive materials, such as nanopartides, polymers, and inorganic materials, have been applied as caps and gatekeepers to control drug release from MSNs. This review presents an overview of the recent progress in the production of pH-responsive MSNs based on the pH gradient between normal tissues and the tumor microenvironment. Four main categories of gatekeepers can respond to acidic conditions. These categories will be described in detail.
基金supported by the University of Science and Technology BeijingNational Center for Nanoscience and Technology Beijingthe National Basic Research Program of China (No.2007CB714304)
文摘SnO2-reduced graphene oxide (SnO2-rGO) composites were prepared via a hydro-thermal reaction of graphene oxide (GO) and SnCI2·2H2O in the mixed solvent of ethylene glycol and water. During the redox reaction, GO was reduced to rGO while Sn2+ was oxidized to Sn02, uniformly depositing on the surface of rGO sheets. The composites were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), thermogravimetric analysis (TGA), infrared spectra analysis (IR) and transmission electron microscopy (TEM), respectively, and their gas sensing properties were further investigated. Compared with pure SnO2 nanoparticles, the as-prepared SnO2-rGO gas sensor and response-recovery time to ethanol and H2S at responding and low cost SnO2-rGO gas sensor could showed much better gas sensing behavior in sensitivity ow concentrations. Overall, the highly sensitive, quick- be potentially applied in environmental monitoring area.
基金supported financially by the National Natural Science Foundation of China (Nos. 21822401, 21771044)the Young Thousand Talented Program
文摘superstructures has enormous potential in material sciences and engineering. Despite the potential,controlled assembly of different kinds of NPs into spatially addressable hybrid configurations still remains a formidable challenge. Herein, we report a simple and universal strategy for DNA-mediated assembly of CdTe quantum dots(QDs) and lanthanide-doped upconversion nanoparticles(UCNPs). Such DNA-QD/UCNPs heterostructures not only maintains both fluorescent properties of QDs and upconversion luminescence behaviors of UCNPs, but also offers a polyvalent DNA surface, allowing for targeted dual-modality imaging of cancer cells using an aptamer. The hetero-assembly mediated by the DNA à inorganic interfacial interaction may provide a scalable way to fabricate hybrid superstructures of both theoretical and practical interests.
基金the financial supports from the National Key R&D Program of China(2019YFB1503200)the GDUPS(2016)+4 种基金the NSF of Guangdong Province(2019B1515120050)the Fundamental Research Funds for the Central Universities(19lgjc07)the financial support from the Guangdong Basic and Applied Basic Research Foundation(2019A1515110770)National Key Research and Development Program of China(2017YFA0206600)National Natural Science Foundation of China(51773045,21772030,51922032,21961160720)for financial support
文摘In this research highlight,recent significant advances with hot-assisted blade-coating or air knife-assisted blade-coating of different perovskite compositions with bandgaps ranging from 1.3 eV to 1.9 eV(i.e.widebandgap or small-bandgap perovskites with mixed cations and anions,2D/3D perovskites,Pb/Sn binary perovskites,and all-inorganic perovskites)for single-junction or tandem PSCs are discussed,with an emphasis on elucidating the distinct ink formulation engineering strategies,crystal growth mechanisms,crystallization kinetics,and optoelectronic properties of the different perovskite compositions.
