1 CONTROLLED GROWING AND PATTERNING MULTIWALLED CARBON NANOTUBES (MWCNTS) ARRAYS FOR FLAT PANEL DISPLAY APPLICATION<br>1.1 Growth of vertical aligned MWCNTs on various substrates by CVD<br>1.2 Patterning technologies for aligned MWCNTs arrays<br>1.3 Surface modification on MWCNTs arrays for sensing applications<br> <br>2 CONTROLLED GROWTH AND ARCHITECTURE OF SINGLE-WALLED CARBON NANOTUBES (SWCNTS) ON SUBSTRATE FOR NANOELECTRONIC DEVICE APPLICATIONS<br>2.1 Challenges of carbon nanotubes for nano-electronic device applications <br>2.2 Controlled growth of SWCNTs on substrate<br>2.3 Constructing the architecture of SWCNTs<br>2.4 Controlling the chirality of carbon nanotubes<br>2.5 SWCNTs based device applications<br> <br>3 HETEROATOM-DOPED GRAPHENE AS METAL-FREE ELECTROCATALYST FOR OXYGEN REDUCTION REACTION (ORR) IN FUEL CELL<br>3.1 Challenges for full cell <br>3.2 Doping heteroatoms into graphene<br>3.3 Heteroatoms doped graphene as electrocatalyst for oxygen reduction reaction (ORR)<br>3.4 Prospect for heteroatom-doped graphene as electrocatalyst for ORR<br> <br>4 CARBON-BASED MATERIALS FOR ULTRAFAST AND LONG-LIFE LITHIUM SULFUR BATTERY<br>4.1 The advantages and disadvantage of lithium sulfur battery<br>4.2 Design and synthesis of carbon-based Materials for Li-S battery<br>4.3 Suppression of shuttle effect of polysulfide ions <br>4.4 Performance of Li-S battery<br>4.5 Prospect of carbon-based materials for Li-S battery application<br> <br>5 UNIQUE PROPERTIES AND APPLICATIONS OF ATOMICALLY THIN BORON NITRIDE<br>5.1 Preparation of atomically thin boron nitride<br>5.2 Unique properties of atomically thin boron nitride<br>5.3 Applications of atomically thin boron nitride<br> <br>6 METAL-ORGANIC-FRAMEWORK (MOFS) AND MOFS-DERIVED CARBONS FOR ENERGY STORAGE AND <br>CONVERSION APPLICATIONS<br>6.1. MOFs used as solid electrolyte in all solid battery <br>6.2 MOFs used as functional materials in Li-S<br>6.3 MOFs-derived carbons for energy storage and conversion applications<br> <br>7 CONTROLLED SYNTHESIS OF METAL HETEROSTRUCTURES AND THEIR CATALYTIC PROPERTIES<br>7.1 Basic principle of the nucleation and growth of metal heterostructures <br>7.2 Synthesis of metal nanocrystals and nanostructures<br>7.3 Catalytic applications of metal heterostructures<br> <br>8 DESIGN, SYNTHESIS AND APPLICATIONS OF BI-BASED PHOTOCATALYSTS<br>8.1 Basic principle of photocatalysis and the advantages of Bi-based photocatalysts<br>8.2 Controlled synthesis of various nanostructured Bi-based photocatalysts.<br>8.3 Strategies on enhancing photocatalytic activity of Bi-based photocatalysts<br>8.4 Applications of Bi-based photocatalysts<br>8.5 Summary and outlook<br> <br>9 FABRICATION OF 2D SEMICONDUCTING MATERIALS FOR PHOTO-ELECTRONIC DETECTION APPLICATIONS<br>9.1 The overview of 2D semiconductors and heterostructures<br>9.2 Controlled preparation, transfer and modulation of 2D semiconductors<br>9.3 van der Waals heterostructures<br>9.4 Summary and outlook<br> <br>10 SYNTHESIS AND MODIFICATION OF METAL AND OXIDE NANOSTRUCTURES FOR C-H SELECTIVE ACTIVATION<br>10.1 Metal nanostructures<br>10.2 Oxide nanostructures<br>10.3 Metal-oxide composite nanostructures <br>10.4 C-H selective activation<br>