The persistent need for a sustainable energy economy has led researchers to focus on novel energy conversion and storage technologies, inspiring the discovery of smart material designs such as hierarchical nanocomposi...The persistent need for a sustainable energy economy has led researchers to focus on novel energy conversion and storage technologies, inspiring the discovery of smart material designs such as hierarchical nanocomposites~ These nanocomposites have proven effective in the advancement of energy-based technologies. The synergistic properties of hierarchical nanocomposites composed of two types of two-dimensional layered materials, layered double hydroxides and graphene, have resulted in improved electrochemical as well as photocatalytic performance. Synthetic strategies and their effect on the electrochemical and photocatalytic performance of these nanocomposites as high-performance supercapacitors and water oxidation catalysts are discussed in detail in this review.展开更多
An efcient and simple in-situ growth strategy has been discovered for the preparation of highly reproducible and continuous symbiotic ZIF-8-based anticorrosion coating by using graphene oxide(GO)/Mg AlNO3layered doubl...An efcient and simple in-situ growth strategy has been discovered for the preparation of highly reproducible and continuous symbiotic ZIF-8-based anticorrosion coating by using graphene oxide(GO)/Mg AlNO3layered double hydroxides(G/LDHs) buffer layer as a new type of connecting carrier based on micro-arc oxide(MAO) coating of AZ31 magnesium alloy. The components of ZIF-8 were adsorbed and bounded to the surface of the G/LDHs buffer layer-modified substrates to promote the nucleation of ZIF-8,thus growing a phase-pure, uniform, and good symbiosis ZIF-8 membrane. ZIF-8 particles with different growth times compensate for the grain boundary defects of the G/LDHs coating precursor buffer layer to different degrees. The prepared ZIF-8-based coating has excellent stability and corrosion resistance. The results demonstrate that the G/LDHs buffer layer provides a new channel for the MOF-modified MAO substrate of AZ31 magnesium alloy. It also proves that it is feasible to build high-performance anticorrosive coatings with MOF materials.展开更多
The urgent need of high-performance of energy storage devices triggers us to design newly class of materials.Generally,the materials feature with high conductivity,abundant pore s and excellent stability.Here,a sandwi...The urgent need of high-performance of energy storage devices triggers us to design newly class of materials.Generally,the materials feature with high conductivity,abundant pore s and excellent stability.Here,a sandwiched hybrid composite containing reduced graphene oxide,polypyrrole and Ni-Co layered double hydroxides(RGO/PPy/NiCo-LDH) was prepared in a facile way.The polypyrrole was incorporated in the two dimensional(2D) nanosheets,which not only serve as the spacer to increase the surface area,but also enhance the conductivity of the nanocomposite.The obtained architecture was employed as an advanced electrode in a supercapacitor.The electrode shows an ultrahigh specific capacitance(2534 F g^-1 at 1 A g^-1) and good cycling efficiency(78 % after 5000 cycles).Moreover,an asymmetric cell based RGO/PPy/NiCo-LDH composite demonstrates excellent electrochemical properties and good prospect of practical use.展开更多
The development of novel single-atom catalysts is important for highly efficient electrochemical catalysis and sensing.In this work,a novel Pt single atoms(SAs)supported on Ni_(6)Co_(1)layered double hydroxides/nitrog...The development of novel single-atom catalysts is important for highly efficient electrochemical catalysis and sensing.In this work,a novel Pt single atoms(SAs)supported on Ni_(6)Co_(1)layered double hydroxides/nitrogen-doped graphene(Pt_(1)/Ni_(6)Co_(1)LDHs/NG)was constructed for electrochemical enzyme-free catalysis and sensing towards glucose.The loading of Pt single atoms increases with doping of Co atoms that generate more anchoring sites for Pt SAs.The resulting Pt_(1)/Ni_(6)Co_(1)LDHs/NG exhibits low oxidative potential of 0.440 V with high sensitivity of 273.78μA·mM^(−1)·cm^(−2)toward glucose,which are 85 mV lower and 15 times higher than those of Ni(OH)_(2),respectively.Pt_(1)/Ni_(6)Co_(1)LDHs/NG also shows excellent selectivity and great stability during 5-week testing.Theoretical and experimental results show that the boosted performance of Pt_(1)/Ni_(6)Co_(1)LDHs/NG originates from its stronger binding energy with glucose and the synergistic effect of Pt SAs,Co doping,and NG.This work provides a general strategy of designing highly active SACs for extending their application in electrochemical sensing.展开更多
The layered double hydroxide(LDH)is a kind of natural mineral,which can also be manually prepared.It has been practically applied in various fields due to its unique crystal structure and diversity of composition,size...The layered double hydroxide(LDH)is a kind of natural mineral,which can also be manually prepared.It has been practically applied in various fields due to its unique crystal structure and diversity of composition,size,and morphology.In this work,LDHs with different chemical compositions(Co^(2+),Mg^(2+),Zn^(2+),and Ni^(2+))and topographical features(flower‐like,spherical,and plate‐like)were successfully prepared by controlling the reaction conditions.Then,they were mechanically dispersed into base grease and their tribological properties were evaluated by a ball‐on‐disk tester under a contact pressure of 2.47 GPa.It was found that the variation of morphology,instead of chemical composition,had great influence on the tribological performance.The“flower‐like”LDH sample with high specific surface area(139 m^(2)/g)was demonstrated to show the best performance.With 1 wt%additive,the wear volume was only about 0.2%of that lubricated by base grease.The tribofilm with unique microscopic structure and uniform composition was derived from tribochemical reaction between LDH additives and sliding solid surfaces,effectively improving tribological properties of the lubrication system.This work provided the guidance for optimizing lubricant additives and held great potential in future applications.展开更多
Graphene(G),as a typical two-dimensional material,is often used as an additive for liquid lubricants.However,graphene is mostly added to liquid lubricants in a one-time manner in friction;it mainly exists in the form ...Graphene(G),as a typical two-dimensional material,is often used as an additive for liquid lubricants.However,graphene is mostly added to liquid lubricants in a one-time manner in friction;it mainly exists in the form of multilayer agglomerated structures due to theπ–πstacking between graphene sheets,making it unable to fully exert the synergistic lubrication function.Herein,we propose a new macroscopic superlubric system of graphene/potassium hydroxide(G/KOH)solution;and the graphene additive involved is exfoliated in-situ from graphene/epoxy(G/EP)friction pair by friction,continuously providing freshly-peeled graphene into KOH solution and minimizing the adverse effects of graphene agglomeration.Moreover,the in-situ produced graphene additive has thinner thickness and better anti-aggregation ability,which provide more graphene to accommodate OH−,form more stacked sandwich structures of OH−/graphene/OH−between friction pairs(i.e.,equivalent to a moving pulley block with more wheels),and finally realize superlubricity.This study develops a new liquid superlubric system suitable for alkaline environments,and at the same time proposes a new way to gradually release graphene additives in situ,rather than adding them all at once,deepening the understanding to liquid superlubricity mechanism,and paving the experimental foundation for the practical application of macroscopic superlubricity.展开更多
采用滴涂结合电化学沉积两步法制备了一种具有优良电活性的三维花状钴镍双金属氢氧化物/石墨烯(CoNi-LDH/G)杂化膜,用于电控离子交换过程(electrically switched ion exchange,ESIX)吸附水溶液中低浓度的磷酸根(PO_(4)^(3-))离子。结合...采用滴涂结合电化学沉积两步法制备了一种具有优良电活性的三维花状钴镍双金属氢氧化物/石墨烯(CoNi-LDH/G)杂化膜,用于电控离子交换过程(electrically switched ion exchange,ESIX)吸附水溶液中低浓度的磷酸根(PO_(4)^(3-))离子。结合X射线衍射(XRD)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)和透射电子显微镜(TEM)等对CoNi-LDH/G杂化膜进行形貌、组成及结构表征。采用电化学方法考察了该杂化膜在不同吸附电压、不同初始浓度、共存离子及不同pH值条件下对PO_(4)^(3-)吸附性能的影响。实验结果表明:通过调节氧化还原电位,即使在低浓度下,杂化膜对PO_(4)^(3-)也具有良好的吸附性能,且可以在较宽的pH值(4~10)范围内使用,同时受共存离子及其浓度变化影响甚小。此外,G对PO_(4)^(3-)的吸附容量为1.10 mg·g^(-1),CoNi-LDH对PO_(4)^(3-)的吸附容量为11.74 mg·g^(-1),二者吸附容量之和小于CoNi-LDH/G对PO_(4)^(3-)的吸附容量(16.25 mg·g^(-1))。同时,结合O1s的XPS数据分析发现,CoNi-LDH/G杂化膜对PO_(4)^(3-)的吸附过程除了层间阴离子交换、PO_(4)^(3-)与层板金属离子配位的配体交换外,还存在G与CoNi-LDH之间的协同效应。展开更多
文摘The persistent need for a sustainable energy economy has led researchers to focus on novel energy conversion and storage technologies, inspiring the discovery of smart material designs such as hierarchical nanocomposites~ These nanocomposites have proven effective in the advancement of energy-based technologies. The synergistic properties of hierarchical nanocomposites composed of two types of two-dimensional layered materials, layered double hydroxides and graphene, have resulted in improved electrochemical as well as photocatalytic performance. Synthetic strategies and their effect on the electrochemical and photocatalytic performance of these nanocomposites as high-performance supercapacitors and water oxidation catalysts are discussed in detail in this review.
基金financially supported by the National Natural Science Foundation of China (Nos.51971040,52171101)the Natural Science Foundation of Chongqing (No.cstc2021jcyj-msxm X0613)+1 种基金the National Natural Science Foundation of China (Nos.52001036,51971044)the Independent Research Project of State Key Laboratory of Mechanical Transmissions (No.SKLMT-ZZKT-2021M11)。
文摘An efcient and simple in-situ growth strategy has been discovered for the preparation of highly reproducible and continuous symbiotic ZIF-8-based anticorrosion coating by using graphene oxide(GO)/Mg AlNO3layered double hydroxides(G/LDHs) buffer layer as a new type of connecting carrier based on micro-arc oxide(MAO) coating of AZ31 magnesium alloy. The components of ZIF-8 were adsorbed and bounded to the surface of the G/LDHs buffer layer-modified substrates to promote the nucleation of ZIF-8,thus growing a phase-pure, uniform, and good symbiosis ZIF-8 membrane. ZIF-8 particles with different growth times compensate for the grain boundary defects of the G/LDHs coating precursor buffer layer to different degrees. The prepared ZIF-8-based coating has excellent stability and corrosion resistance. The results demonstrate that the G/LDHs buffer layer provides a new channel for the MOF-modified MAO substrate of AZ31 magnesium alloy. It also proves that it is feasible to build high-performance anticorrosive coatings with MOF materials.
基金This work was supported by the National Natural Science Foundation of China(Nos.51861005 and 51861004)the Innovation Project of Guangxi Graduate Education(No.YCSW2019149)Guangxi Natural Science Foundation(No.2017AD23029)。
文摘The urgent need of high-performance of energy storage devices triggers us to design newly class of materials.Generally,the materials feature with high conductivity,abundant pore s and excellent stability.Here,a sandwiched hybrid composite containing reduced graphene oxide,polypyrrole and Ni-Co layered double hydroxides(RGO/PPy/NiCo-LDH) was prepared in a facile way.The polypyrrole was incorporated in the two dimensional(2D) nanosheets,which not only serve as the spacer to increase the surface area,but also enhance the conductivity of the nanocomposite.The obtained architecture was employed as an advanced electrode in a supercapacitor.The electrode shows an ultrahigh specific capacitance(2534 F g^-1 at 1 A g^-1) and good cycling efficiency(78 % after 5000 cycles).Moreover,an asymmetric cell based RGO/PPy/NiCo-LDH composite demonstrates excellent electrochemical properties and good prospect of practical use.
基金C.S.S.thanks the support from the National Natural Science Foundation of China(No.21874031)“Chu-Tian Scholar”Program of Hubei Province.M.H.Z.acknowledges the support from the NSFC of China(No.22171075)+4 种基金Guangxi Province(No.2017GXNSFDA198040)the BAGUI talent program(No.2019AC26001)J.J.L.and X.F.G.acknowledge the support by the institutional funds and New Faculty Seed Grant from ORAP at WSUThis research used resources of the Advanced Photon Source,an Office of Science User Facility operated for the U.S.Department of Energy(DOE)Office of Science by Argonne National Laboratory under Contract(No.DE-AC02-06CH11357)Y.M.Z.thanks the support from the China Postdoctoral Science Foundation(No.2021M701133).
文摘The development of novel single-atom catalysts is important for highly efficient electrochemical catalysis and sensing.In this work,a novel Pt single atoms(SAs)supported on Ni_(6)Co_(1)layered double hydroxides/nitrogen-doped graphene(Pt_(1)/Ni_(6)Co_(1)LDHs/NG)was constructed for electrochemical enzyme-free catalysis and sensing towards glucose.The loading of Pt single atoms increases with doping of Co atoms that generate more anchoring sites for Pt SAs.The resulting Pt_(1)/Ni_(6)Co_(1)LDHs/NG exhibits low oxidative potential of 0.440 V with high sensitivity of 273.78μA·mM^(−1)·cm^(−2)toward glucose,which are 85 mV lower and 15 times higher than those of Ni(OH)_(2),respectively.Pt_(1)/Ni_(6)Co_(1)LDHs/NG also shows excellent selectivity and great stability during 5-week testing.Theoretical and experimental results show that the boosted performance of Pt_(1)/Ni_(6)Co_(1)LDHs/NG originates from its stronger binding energy with glucose and the synergistic effect of Pt SAs,Co doping,and NG.This work provides a general strategy of designing highly active SACs for extending their application in electrochemical sensing.
基金This work was financially supported by the National Natural Science Foundation of China(Nos.51905294,51905027,51527901,and 51875303)China Postdoc Innovation Talent Support Program(No.BX20180168)the China Postdoctoral Science Foundation(No.2019M650654).
文摘The layered double hydroxide(LDH)is a kind of natural mineral,which can also be manually prepared.It has been practically applied in various fields due to its unique crystal structure and diversity of composition,size,and morphology.In this work,LDHs with different chemical compositions(Co^(2+),Mg^(2+),Zn^(2+),and Ni^(2+))and topographical features(flower‐like,spherical,and plate‐like)were successfully prepared by controlling the reaction conditions.Then,they were mechanically dispersed into base grease and their tribological properties were evaluated by a ball‐on‐disk tester under a contact pressure of 2.47 GPa.It was found that the variation of morphology,instead of chemical composition,had great influence on the tribological performance.The“flower‐like”LDH sample with high specific surface area(139 m^(2)/g)was demonstrated to show the best performance.With 1 wt%additive,the wear volume was only about 0.2%of that lubricated by base grease.The tribofilm with unique microscopic structure and uniform composition was derived from tribochemical reaction between LDH additives and sliding solid surfaces,effectively improving tribological properties of the lubrication system.This work provided the guidance for optimizing lubricant additives and held great potential in future applications.
基金supported by the National Natural Science Foundation of China(52075224,21975109,51975252,and 52075225)Natural Science Foundation of Jiangsu Province(BK20201423)+1 种基金Foundation of State Key Laboratory of Solid Lubrication(LSL-1801)Tribology Science Fund of State Key Laboratory of Tribology(SKLTKF18B03).
文摘Graphene(G),as a typical two-dimensional material,is often used as an additive for liquid lubricants.However,graphene is mostly added to liquid lubricants in a one-time manner in friction;it mainly exists in the form of multilayer agglomerated structures due to theπ–πstacking between graphene sheets,making it unable to fully exert the synergistic lubrication function.Herein,we propose a new macroscopic superlubric system of graphene/potassium hydroxide(G/KOH)solution;and the graphene additive involved is exfoliated in-situ from graphene/epoxy(G/EP)friction pair by friction,continuously providing freshly-peeled graphene into KOH solution and minimizing the adverse effects of graphene agglomeration.Moreover,the in-situ produced graphene additive has thinner thickness and better anti-aggregation ability,which provide more graphene to accommodate OH−,form more stacked sandwich structures of OH−/graphene/OH−between friction pairs(i.e.,equivalent to a moving pulley block with more wheels),and finally realize superlubricity.This study develops a new liquid superlubric system suitable for alkaline environments,and at the same time proposes a new way to gradually release graphene additives in situ,rather than adding them all at once,deepening the understanding to liquid superlubricity mechanism,and paving the experimental foundation for the practical application of macroscopic superlubricity.
