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选出与其他两项发音不同的一项。
) 1. A. l oo k(
) 2. A. s ou th(
) 3. A. h o t(
) 4. A. r u n(
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选出与其他两项发音不同的一项。
(&&&& ) 1. A. l oo k(&&&& ) 2. A. s ou th(&&&& ) 3. A. h o t(&&&& ) 4. A. r u n(&&&& ) 5. A. s o me
B. t oo kB. l oa dB. r o seB. st u dent&& B. d o ctor
C. t oo thC. h ou seC. h o leC. c u pC. d o g
1. C& 2. B &3. A &4. B& 5. A曲良体课题组
&&& 先进功能材料、纳米材料、电化学、纳米器件等。主要围绕具有碳-碳共轭结构的石墨烯、碳纳米管和导电高分子展开，涉及新型功能纳米材料的控制合成、组装、结构调控、性能及应用研究。
&&& Research is involved in the advanced functional materials, nanomaterials, electrochemistry and nanodevices, and mainly focuses on the synthesis, functionalization and application of nanomaterials with carbon-carbon conjugated structures including carbon nanotubes, graphenes and conducting polymers.
发表论文(Full publication list)
Nanoscale, 35&3042.
hen Q,& Y,
L.T.*, &Three-Dimensional Graphitic Carbon Nitride Functionalized Graphene-Based High-Performance Supercapacitors&, Journal of Materials Chemistry A, 61&6766.
Nano Research,),
L.T.*,&&&Linear Graphene Edge Nanoelectrode&, Chem. Commun., 65&8768.
L.X.,& F,& Q,& C.G.,
N&and& L.T.*, &Spontaneous formation of Cu2O&g-C3N4 core&shell nanowires for photocurrent and humidity responses&, Nanoscale, 94&9702.
123. Zhao Y, Zhao F, Wang X.P., Xu C.Y., Zhang Z.P., Shi G.Q. and Qu L.T.*,&&&, Angew. Chem. Int. Ed., 934&13939.
J,& Y,& C.G.,& H.H.,& N,*& Z.H.,& Z.P.,&and L.T.*, &Preparation of Multifunctional Microchannel-Network Graphene Foams&, J. Mater. Chem. A, ), .
DOI: 10.409K
Phys. Chem. Chem. Phys., ), .
Energy Environ. Sci., 2014, 7, .
Wang L.X., Hu C.G., Zhao Y., Hu Y., Zhao F., Chen N., and Qu L.T.*, &A dually spontaneous reduction and assembly strategy for hybrid capsules of graphene quantum dots with platinum-copper nanoparticles for enhanced oxygen reduction reaction&,Carbon, 0&179.
, J. Mater. Chem. A, 2014, DOI: 10.230E.
101. Zhao Y., Song L., Zhang Z.P.* and Qu L.T.*,&Stimulus-responsive Graphene Systemstowards Actuator Applications&, Energy Environ. Sci, ), . (Review)
100. Cheng H.H., Liu J., Zhao Y., Hu H.G., Zhang Z.P., Chen N., Jiang L., Qu L.T.*, &Graphene Fibers with Predetermined Deformation as Moisture-Triggered Actuators and Robots&, Angew. Chem. Int. Ed., ), .
90. Hu C.G., Mou Z.Y., Lu G.W., Chen N.*, Dong Z.L., Hu M.J., Qu L.T.*, &3D Graphene-Fe3O4Nanocomposites with High-Performance Microwave Absorption&, Phys. Chem. Chem. Phys., ), .
89. Dong Z.L., Zhou C., Cheng H.H., Zhao Y., Hu C.G., Chen N., Zhang Z.P., Luo H.X., Qu L.T.*, &Carbon nanotube-nanopipe composite vertical arrays for enhanced electrochemical capacitance&, Carbon, 7&515.
88. Wang Y.H., Bian K., Hu C.G., Zhang Z.P.*, Chen N., Zhang H.M., Qu L.T.*, &Flexible and Wearable Graphene/Polypyrrole Fibers towards Multifunctional Actuator Applications&, Electrochem. Commun., &52.
, Cheng H.H., Hu Y., Shi G.Q., Dai L.M., Qu L.T.*, &Ternary Pd2/PtFe networks supported by 3D graphene for efficient and durable electrooxidation of formic acid&, Chem. Commun., ), .
, Zhao Y., Cheng L.T.*
, Hu Y., Cheng H.H., Shi G.Q., Qu L.T.*, &A Angew. Chem. Int. Ed., ), .
Energy Environ. Sci., ), . (Review)
. Mater., ), .
, Cheng H., Hu Y., Shi G.Q., Dai L.M., Qu L.T.*, &Nitrogen-doped graphene quantum dots with oxygen-rich functional groups&, J. Am. Chem. Soc., ), 15&18.
, Fan Y.Q., Xie X.J., Qu L.T.*, Shi G.Q.*, &Graphene-quantum-dot assembled nanotubes: a new platform for efficient Raman enhancement&, ACS Nano, ), .
, Zhang H.M.*, Qu L.T.*, &Direct electrochemistry and electrocatalysis of horseradish peroxidase immobilized in graphene oxide&Nafion nanocomposite film&, Electrochim. Acta, 2&126.
, Zhao Y., Li Y., Li H., Shao H.B., Qu L.T.*, &Defective super-long carbon nanotubes and polypyrrole composite for high-performance supercapacitor electrodes&, Electrochim. Acta, 9&286.
, Wang Z.,* Xie X.J., Cheng H., Zhao Y., Qu L.T.*, &A rationally-designed synergetic polypyrrole/graphene bilayer actuator&, J. Mater. Chem., ), .
Y.Q., Cheng H., Zhou C., Xie X.J., Liu Y., Dai L.M., Zhang J., Qu L.T.*, &Honeycomb architecture of carbon quantum dots: a new efficient substrate to support gold for stronger SERS&, Nanoscale, ), . (Hot article,
Qu L.T.*, &Electrochemical Introduction of Active Sites into Super-long Carbon Nanotubes for Enhanced Capacitance&, Chem. Res. Chin. Univ., ), 302&307.&&&
Qu L.T.*, &An electrochemical avenue to green-luminescent graphene quantum dots as potential electron-acceptors for photovoltaics&, Adv. Mater., ), 776&780.
&Multilevel, multicomponent microarchitectures of vertically-aligned carbon nanotubes for diverse applications&, ACS Nano, ), 994&1002.
Qu L.T.*, &Load-tolerant, highly strain-responsive graphene sheets&, J. Mater. Chem., ) 2057&2059.
&Electrochemical deposition of polyaniline nanosheets mediated by sulfonated polyaniline functionalized graphenes&, J. Mater. Chem., ), 13978&13983.
&Solvent-free functionalization and transfer of aligned carbon nanotubes with vapor-deposited polymer nanocoatings&, J. Mater. Chem., ), 837&842.
&Membranes of vertically aligned superlong carbon nanotubes&, Langmuir, ), 8437&8443.
&Self-assembly of gold nanowires along carbon nanotubes for ultrahigh-aspect-ratio hybrids&, Chem. Mater., ), 2760&2765.
&Nanocomposite electrodes for high-performance supercapacitors&, J. Phys. Chem. Lett., ), 655&660.
&Vertically aligned carbon nanotube electrodes for lithium-ion batteries&, J. Power Sources, ), 1455&1460.
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