{"id":99,"date":"2017-08-04T14:46:32","date_gmt":"2017-08-04T06:46:32","guid":{"rendered":"http:\/\/183.173.129.25\/wp\/?page_id=99"},"modified":"2021-04-21T22:19:35","modified_gmt":"2021-04-21T14:19:35","slug":"paper","status":"publish","type":"page","link":"https:\/\/www.qianggroup.com\/wp\/en\/paper\/","title":{"rendered":"PAPER"},"content":{"rendered":"

2020<\/strong><\/p>\n

    \n
  1. Zhao CZ, Zhao BC, Yan C, Zhang XQ, Huang JQ, Mo Y, Xu X, Li H, Zhang Q<\/u><\/strong>. Liquid Phase Therapy to Solid Electrolyte\u2013Electrode Interface in Solid-State Li Metal Batteries: A Review. Energy Storage Materials<\/em><\/strong> 2020, 24, 75, doi:10.1016\/j.ensm.2019.07.026.[PDF]<\/a><\/li>\n
  2. Zhang XQ, Li T, Li BQ, Zhang R, Shi P, Yan C, Huang JQ, Zhang Q<\/u><\/strong>. A Sustainable Solid Electrolyte Interphase for High-Energy-Density Lithium Metal Batteries under Practical Conditions. Angew Chem Int Ed Engl<\/em><\/strong> 2020, 59, doi:10.1002\/anie.201911724.[PDF]<\/a><\/li>\n
  3. Yao YX, Zhang XQ, Li BQ, Yan C, Chen PY, Huang JQ, Zhang Q<\/u><\/strong>. A Compact Inorganic Layer for Robust Anode Protection in Lithium\u2010Sulfur Batteries. InfoMat<\/em><\/strong> 2020, 2, 379, doi:10.1002\/inf2.12046.[PDF]<\/a><\/li>\n
  4. Liu JN, Li BQ, Zhao CX, Yu J, Zhang Q<\/u><\/strong>. A Composite Bifunctional Oxygen Electrocatalyst for High-Performance Rechargeable Zinc-Air Batteries. ChemSusChem<\/em><\/strong> 2020, 13, doi:10.1002\/cssc.201903071.[PDF]<\/a><\/li>\n<\/ol>\n

    2019<\/strong><\/p>\n

      \n
    1. Zhao M, Peng HJ, Wei JY, Huang JQ, Li BQ, Yuan H, Zhang Q<\/u><\/strong>. Dictating High\u2010Capacity Lithium\u2013Sulfur Batteries through Redox\u2010Mediated Lithium Sulfide Growth. Small Methods<\/em><\/strong> 2019, 4, 1900344, doi:10.1002\/smtd.201900344.[PDF]<\/a><\/li>\n
    2. Zhao CZ, Duan H, Huang JQ, Zhang J, Zhang Q<\/u><\/strong>, Guo YG, Wan LJ. Designing Solid-State Interfaces on Lithium-Metal Anodes: A Review. Science China Chemistry<\/em><\/strong> 2019, 62, 1286, doi:10.1007\/s11426-019-9519-9.[PDF]<\/a><\/li>\n
    3. Zhao CX, Li BQ, Zhang Q<\/u><\/strong>. Advanced Electrosynthesis of Hydrogen Peroxide on Oxidized Carbon Electrocatalyst. Journal of Energy Chemistry<\/em><\/strong> 2019, 34, 10, doi:10.1016\/j.jechem.2018.09.002.[PDF]<\/a><\/li>\n
    4. Yan C, Zhang XQ, Huang JQ, Liu Q, Zhang Q<\/u><\/strong>. Lithium-Anode Protection in Lithium\u2013Sulfur Batteries. Trends in Chemistry<\/em><\/strong> 2019, 1, 693, doi:10.1016\/j.trechm.2019.06.007.[PDF]<\/a><\/li>\n
    5. Xie J, Li BQ, Song YW, Peng HJ, Zhang Q<\/u><\/strong>. A Supramolecular Electrolyte for Lithium\u2010Metal Batteries. Batteries & Supercaps<\/em><\/strong> 2019, 3, 47, doi:10.1002\/batt.201900112.[PDF]<\/a><\/li>\n
    6. Xie J, Li BQ, Peng HJ, Song YW, Zhao M, Chen X, Zhang Q<\/u><\/strong>, Huang JQ. Implanting Atomic Cobalt within Mesoporous Carbon toward Highly Stable Lithium-Sulfur Batteries. Advanced Materials<\/em><\/strong> 2019, 31, doi:10.1002\/adma.201903813.[PDF]<\/a><\/li>\n
    7. Wang B, Tang C, Wang HF, Chen X, Cao R, Zhang Q<\/u><\/strong>. Core-Branch Coni Hydroxysulfides with Versatilely Regulated Electronic and Surface Structures for Superior Oxygen Evolution Electrocatalysis. Journal of Energy Chemistry<\/em><\/strong> 2019, 38, 8, doi:10.1016\/j.jechem.2018.12.006.[PDF]<\/a><\/li>\n
    8. Song Y, Cai W, Kong L, Cai J, Zhang Q<\/u><\/strong>, Sun J. Rationalizing Electrocatalysis of Li\u2013S Chemistry by Mediator Design: Progress and Prospects. Advanced Energy Materials<\/em><\/strong> 2019, 10, 1901075, doi:10.1002\/aenm.201901075.[PDF]<\/a><\/li>\n
    9. Shi P, Zhang XQ, Shen X, Zhang R, Liu H, Zhang Q<\/u><\/strong>. A Review of Composite Lithium Metal Anode for Practical Applications. Advanced Materials Technologies<\/em><\/strong> 2019, 5, 1900806, doi:10.1002\/admt.201900806.[PDF]<\/a><\/li>\n
    10. Shi P, Cheng XB, Li T, Zhang R, Liu H, Yan C, Zhang XQ, Huang JQ, Zhang Q<\/u><\/strong>. Electrochemical Diagram of an Ultrathin Lithium Metal Anode in Pouch Cells. Advanced Materials<\/em><\/strong> 2019, 31, doi:10.1002\/adma.201902785.[PDF]<\/a><\/li>\n
    11. Liu J, Yuan H, Cheng XB, Chen WJ, Titirici MM, Huang JQ, Yuan TQ, Zhang Q<\/u><\/strong>. A Review of Naturally Derived Nanostructured Materials for Safe Lithium Metal Batteries. Materials Today Nano<\/em><\/strong> 2019, 8, 100049, doi:10.1016\/j.mtnano.2019.100049.[PDF]<\/a><\/li>\n
    12. Liu H, Cheng XB, Huang JQ, Kaskel S, Chou S, Park HS, Zhang Q<\/u><\/strong>. Alloy Anodes for Rechargeable Alkali-Metal Batteries: Progress and Challenge. ACS Materials Letters<\/em><\/strong> 2019, 1, 217, doi:10.1021\/acsmaterialslett.9b00118.[PDF]<\/a><\/li>\n
    13. Li T, Zhang XQ, Shi P, Zhang Q<\/u><\/strong>. Fluorinated Solid-Electrolyte Interphase in High-Voltage Lithium Metal Batteries. Joule<\/em><\/strong> 2019, 3, 2647, doi:10.1016\/j.joule.2019.09.022.[PDF]<\/a><\/li>\n
    14. Li BQ, Kong L, Zhao CX, Jin Q, Chen X, Peng HJ, Qin JL, Chen JX, Yuan H, Zhang Q<\/u><\/strong>, Huang JQ. Expediting Redox Kinetics of Sulfur Species by Atomic\u2010Scale Electrocatalysts in Lithium\u2013Sulfur Batteries. InfoMat<\/em><\/strong> 2019, 1, 533, doi:10.1002\/inf2.12056.[PDF]<\/a><\/li>\n
    15. Jiang L, Cheng XB, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>. Carbon Materials for Traffic Power Battery. eTransportation<\/em><\/strong> 2019, 2, 100033, doi:10.1016\/j.etran.2019.100033.[PDF]<\/a><\/li>\n
    16. Chen XR, Li BQ, Zhu C, Zhang R, Cheng XB, Huang JQ, Zhang Q<\/u><\/strong>. A Coaxial\u2010Interweaved Hybrid Lithium Metal Anode for Long\u2010Lifespan Lithium Metal Batteries. Advanced Energy Materials<\/em><\/strong> 2019, 9, 1901932, doi:10.1002\/aenm.201901932.[PDF]<\/a><\/li>\n
    17. Chen XR, Li BQ, Zhao CX, Zhang R, Zhang Q<\/u><\/strong>. Synergetic Coupling of Lithiophilic Sites and Conductive Scaffolds for Dendrite\u2010Free Lithium Metal Anodes. Small Methods<\/em><\/strong> 2019, 4, 1900177, doi:10.1002\/smtd.201900177.[PDF]<\/a><\/li>\n
    18. Hong B, Fan H, Cheng XB, Yan X, Hong S, Dong Q, Gao C, Zhang Z, Lai Y, Zhang Q<\/u><\/strong>. Spatially uniform deposition of lithium metal in 3D Janus hosts. Energy Storage Materials<\/em><\/strong> 2019, 16, 259, doi:10.1016\/j.ensm.2018.04.032.[PDF]<\/a><\/li>\n
    19. Huang Y, Wang Y, Tang C, Wang J, Zhang Q<\/u><\/strong>, Wang Y, Zhang J. Atomic Modulation and Structure Design of Carbons for Bifunctional Electrocatalysis in Metal-Air Batteries. Advanced Materials<\/em><\/strong> 2019, 31, 1803800, doi:10.1002\/adma.201803800.[PDF]<\/a><\/li>\n
    20. Li BQ, Chen XR, Chen X, Zhao CX, Zhang R, Cheng XB, Zhang Q<\/u><\/strong>. Favorable Lithium Nucleation on Lithiophilic Framework Porphyrin for Dendrite-Free Lithium Metal Anodes. Research<\/em><\/strong> 2019, 2019, 1, doi:10.1155\/2019\/4608940.[PDF]<\/a><\/li>\n
    21. Li BQ, Peng HJ, Chen X, Zhang SY, Xie J, Zhao CX, Zhang Q<\/u><\/strong>. Polysulfide Electrocatalysis on Framework Porphyrin in High-Capacity and High-Stable Lithium\u2013Sulfur Batteries. CCS Chemistry<\/em><\/strong> 2019, 128, doi:10.31635\/ccschem.019.20180016.[PDF]<\/a><\/li>\n
    22. Liang Y, Zhao C Z, Yuan H, Chen Y, Zhang W, Huang J Q, Yu D, Liu Y, Titirici M M, Chueh Y L, Yu H, Zhang Q<\/u><\/strong>. A review of rechargeable batteries for portable electronic devices. InfoMat<\/em><\/strong> 2019, doi:10.1002\/inf2.12000.[PDF]<\/a><\/li>\n
    23. Shen X, Cheng X, Shi P, Huang J, Zhang X, Yan C, Li T, Zhang Q<\/u><\/strong>. Lithium\u2013matrix composite anode protected by a solid electrolyte layer for stable lithium metal batteries. Journal of Energy Chemistry<\/em><\/strong> 2019, 37, 29, doi:10.1016\/j.jechem.2018.11.016.[PDF]<\/a><\/li>\n
    24. Shi P, Li T, Zhang R, Shen X, Cheng XB, Xu R, Huang J Q, Chen XR, Liu H, Zhang Q<\/u><\/strong>. Lithiophilic LiC6 Layers on Carbon Hosts Enabling Stable Li Metal Anode in Working Batteries. Advanced Materials<\/em><\/strong> 2019, 31, 1807131, doi:10.1002\/adma.201807131.[PDF]<\/a><\/li>\n
    25. Wang B, Tang C, Wang HF, Chen X, Cao R, Zhang Q<\/u><\/strong>. A Nanosized CoNi Hydroxide@Hydroxysulfide Core-Shell Heterostructure for Enhanced Oxygen Evolution. Advanced Materials<\/em><\/strong> 2019, 31, doi:10.1002\/adma.201805658.[PDF]<\/a><\/li>\n
    26. Wang B, Tang C, Wang HF, Chen X, Cao R, Zhang Q<\/u><\/strong>. Core-branch CoNi hydroxysulfides with versatilely regulated electronic and surface structures for superior oxygen evolution electrocatalysis. Journal of Energy Chemistry<\/em><\/strong> 2019, 38, 8, doi:10.1016\/j.jechem.2018.12.006.[PDF]<\/a><\/li>\n
    27. Xie J, Li BQ, Peng HJ, Song YW, Li JX, Zhang ZW, Zhang Q<\/u><\/strong>. From Supramolecular Species to Self-Templated Porous Carbon and Metal-Doped Carbon for Oxygen Reduction Reaction Catalysts. Angew Chem Int Ed Engl<\/em><\/strong> 2019, 58, 4963, doi:10.1002\/anie.201814605.[PDF]<\/a><\/li>\n
    28. Xu R, Xiao Y, Zhang R, Cheng XB, Zhao CZ, Zhang XQ, Yan C, Zhang Q<\/u><\/strong>, Huang JQ. Dual-Phase Single-Ion Pathway Interfaces for Robust Lithium Metal in Working Batteries. Advanced Materials<\/em><\/strong> 2019, 1808392, doi:10.1002\/adma.201808392.[PDF]<\/a><\/li>\n
    29. Yuan H, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>. Sulfur Redox Reactions at Working Interfaces in Lithium-Sulfur Batteries: A Perspective. Advanced Materials Interfaces<\/em><\/strong> 2019, 6, doi:10.1002\/admi.201802046.[PDF]<\/a><\/li>\n
    30. Zhang R, Shen X, Cheng XB, Zhang Q<\/u><\/strong>. The dendrite growth in 3D structured lithium metal anodes: Electron or ion transfer limitation? Energy Storage Materials<\/em><\/strong> 2019, doi:10.1016\/j.ensm.2019.03.029.[PDF]<\/a><\/li>\n
    31. Zhao CX, Li BQ, Zhang Q<\/u><\/strong>. Advanced electrosynthesis of hydrogen peroxide on oxidized carbon electrocatalyst. Journal of Energy Chemistry<\/em><\/strong> 2019, 34, 10, doi:10.1016\/j.jechem.2018.09.002.[PDF]<\/a><\/li>\n
    32. Zhao M, Peng HJ, Zhang ZW, Li BQ, Chen X, Xie J, Chen X, Wei JY, Zhang Q<\/u><\/strong>, Huang JQ. Activating Inert Metallic Compounds for High-Rate Lithium-Sulfur Batteries Through In Situ Etching of Extrinsic Metal. Angew Chem Int Ed Engl<\/em><\/strong> 2019, 58, 3779, doi:10.1002\/anie.201812062.[PDF]<\/a><\/li>\n
    33. Zhu GL, Zhao CZ, Huang JQ, He C, Zhang J, Chen S, Xu L, Yuan H, Zhang Q<\/u><\/strong>. Fast Charging Lithium Batteries: Recent Progress and Future Prospects. Small<\/em><\/strong> 2019, 15, 1805389, doi:10.1002\/smll.201805389.[PDF]<\/a><\/li>\n
    34. Yuan H, Peng HJ, Li BQ, Xie J, Kong L, Zhao M, Chen X, Huang JQ, Zhang Q<\/u><\/strong>. Conductive and Catalytic Triple\u2010Phase Interfaces Enabling Uniform Nucleation in High\u2010Rate Lithium\u2013Sulfur Batteries. Advanced Energy Materials<\/em><\/strong> 2019, 9, 1802768, doi:10.1002\/aenm.201802768.[PDF]<\/a><\/li>\n
    35. Chen XR, Li BQ, Zhao C X, Zhang R, Zhang Q<\/u><\/strong>. Synergetic Coupling of Lithiophilic Sites and Conductive Scaffolds for Dendrite\u2010Free Lithium Metal Anodes. Small Methods<\/em><\/strong> 2019, doi:10.1002\/smtd.201900177.[PDF]<\/a><\/li>\n
    36. Kong L, Zhang Q<\/u><\/strong>. Three-dimensional matrix for lithium metal anode for next-generation rechargeable batteries: Structure design and interface engineering. Journal of Energy Chemistry<\/em><\/strong> 2019, 33, 167, doi:10.1016\/j.jechem.2018.08.003. [PDF]<\/a><\/li>\n
    37. Li B Q, Zhang SY, Chen X, Chen CY, Xia ZJ, Zhang Q<\/u><\/strong>. One\u2010Pot Synthesis of Framework Porphyrin Materials and Their Applications in Bifunctional Oxygen Electrocatalysis. Advanced Functional Materials<\/em><\/strong> 2019, doi:10.1002\/adfm.201901301. [PDF]<\/a><\/li>\n
    38. Li BQ, Zhao CX, Chen S, Liu JN, Chen X, Song L, Zhang Q<\/u><\/strong>. Framework-Porphyrin-Derived Single-Atom Bifunctional Oxygen Electrocatalysts and their Applications in Zn-Air Batteries. Advanced Materials<\/em><\/strong> 2019, 31, e1900592, doi:10.1002\/adma.201900592. [PDF]<\/a><\/li>\n
    39. Li BQ, Zhao CX, Liu JN, Zhang Q<\/u><\/strong>. Electrosynthesis of Hydrogen Peroxide Synergistically Catalyzed by Atomic Co-Nx -C Sites and Oxygen Functional Groups in Noble-Metal-Free Electrocatalysts. Advanced Materials<\/em><\/strong> 2019, e1808173, doi:10.1002\/adma.201808173. [PDF]<\/a><\/li>\n
    40. Qin JL, Li BQ, Huang JQ, Kong L, Chen X, Peng HJ, Xie J, Liu R, Zhang Q<\/u><\/strong>. Graphene-based Fe-coordinated framework porphyrin as an interlayer for lithium\u2013sulfur batteries. Materials Chemistry Frontiers<\/em><\/strong> 2019, 3, 615, doi:10.1039\/c8qm00645h. [PDF]<\/a><\/li>\n
    41. Tang C, Wang HF, Huang JQ, Qian W, Wei F, Qiao SZ, Zhang Q<\/u><\/strong>. 3D Hierarchical Porous Graphene-Based Energy Materials: Synthesis, Functionalization, and Application in Energy Storage and Conversion. Electrochemical Energy Reviews<\/em><\/strong> 2019, 2, 332, doi:10.1007\/s41918-019-00033-7. [PDF]<\/a><\/li>\n
    42. Wang HF, Tang C, Zhang Q<\/u><\/strong>. A review of graphene-based 3D van der Waals hybrids and their energy applications. Nano Today<\/em><\/strong> 2019, 25, 27, doi:10.1016\/j.nantod.2019.02.006. [PDF]<\/a><\/li>\n
    43. Zhang XQ, Chen X, Hou LP, Li BQ, Cheng XB, Huang JQ, Zhang Q<\/u><\/strong>. Regulating Anions in the Solvation Sheath of Lithium Ions for Stable Lithium Metal Batteries. ACS Energy Letters<\/em><\/strong> 2019, 4, 411, doi:10.1021\/acsenergylett.8b02376. [PDF]<\/a><\/li>\n
    44. Zhao CX, Li BQ, Liu JN, Huang JQ, Zhang Q<\/u><\/strong>. Transition metal coordinated framework porphyrin for electrocatalytic oxygen reduction. Chinese Chemical Letters<\/em><\/strong> 2019, 30, 911, doi:10.1016\/j.cclet.2019.03.026. [PDF]<\/a><\/li>\n<\/ol>\n

      2018<\/strong><\/p>\n

        \n
      1. Kong L, Chen X, Li BQ, Peng HJ, Huang JQ, Xie J, Zhang Q. A Bifunctional Perovskite Promoter for Polysulfide Regulation towards Stable Lithium\u2013Sulfur Batteries. Advanced Materials<\/em><\/strong> 2018, 30, 1705219, doi: 10.1002\/adma.201705219. [PDF]<\/a><\/li>\n
      2. Li T, Zhang Q. Advanced metal sulfide anode for potassium ion batteries. Journal of Energy Chemistry<\/em><\/strong> 2018, 27, 373-374. [PDF]<\/a><\/li>\n
      3. Liu SF, Xia XH, Zhong Y, Deng SJ, Yao ZJ, Zhang LY, Cheng XB, Wang XL, Zhang Q, Tu JP. Three-dimensional TiC\/C Core\/Shell Nanowires Skeleton for Dendrite-Free and Long-Life Lithium Metal Anode. Advanced Energy Materials<\/em><\/strong> 2018, 8, 1702322, doi: 10.1002\/aenm.201702322. [PDF]<\/a><\/li>\n
      4. Cheng XB, Yan C, Peng HJ, Huang JQ, Yang ST, Zhang Q<\/u><\/strong>. Sulfurized Solid Electrolyte Interphases with a Rapid Li+<\/sup> Diffusion on Dendrite-Free Li Metal Anodes. Energy Storage Materials <\/em><\/strong>2018, 10, 199-205. doi: 10.1016\/j.ensm.2017.03.008. [PDF]<\/a><\/li>\n
      5. Zhong Y, Xia XH, Deng SJ, Zhan JY, Fang RY, Xia Y, Wang XL, Zhang Q, Tu JP. Popcorn Inspired Porous Macrocellular Carbon: Rapid Puffing Fabrication from Rice and its Applications in Lithium-Sulfur Batteries Advanced Energy Materials<\/em><\/strong> 2018, 8, 1701110. doi: 10.1002\/aenm.201701110. [PDF]<\/a><\/li>\n
      6. Cheng XB, Zhang Q<\/u><\/strong>. Review on the Growth Mechanism and Suppression Strategies of Lithium Metal Dendrites. Progress in Chemistry <\/em><\/strong>2018, 30, 51-72, DOI: 10. 7536 \/PC170704. [PDF]<\/a><\/li>\n
      7. Cheng XB, Huang JQ, Zhang Q. A Review of Li Metal Anode in Working Lithium-Sulfur Batteries. Journal of the Electrochemical Society <\/em><\/strong>2018, 165, A6058-A6072. [PDF]<\/a><\/li>\n
      8. Zhang XQ, Cheng XB, Zhang Q. Advances in Interfaces between Li Metal Anode and Electrolyte. Advanced Materials Interfaces<\/em><\/strong> 2018, 5, 1701097, DOI: 10.1002\/admi.201701097. [PDF]<\/a><\/li>\n
      9. Shi JL, Tang C, Huang JQ, Zhu WC Zhang Q. Effective exposure of nitrogen heteroatoms in 3D porous graphene framework for oxygen reduction reaction and lithium-sulfur batteries. Journal of Energy Chemistry<\/em><\/strong> 2018, 27, 167-175. doi: 10.1016\/j.jechem.2017.09.014. [PDF]<\/a><\/li>\n
      10. Gao G, Zhai PY, Zhang Q<\/u><\/strong>, Shearer CJ, Zhao J, Shapter JG. Fe3O4@S nanoparticles embedded\/coated on the multi-wall carbon nanotubes for rechargeable lithium batteries. Chemical Engineering Journal <\/em><\/strong>2018, 333, 268-275. doi:10.1016\/j.cej.2017.09.156. [PDF]<\/a><\/li>\n
      11. Tang C, Zhong L, Zhang BS, Wang HF, Zhang Q. 3D mesoporous van der Waals heterostructures for trifunctional energy electrocatalysis. Advanced Materials <\/em><\/strong>2018, 30, 1705110. doi: 10.1002\/adma.201705110. [PDF]<\/a><\/li>\n
      12. Chen X, Shen X, Li B, Peng HJ, Cheng XB, Li BQ, Zhang XQ, Huang JQ, Zhang Q. Ion-Solvent Complexes Promote Gas Evolution from Electrolytes on Sodium Metal Anode. Angewandte Chemie International Edition<\/em><\/strong> 2018, 57, 734-737 DOI: 10.1002\/anie.201711552 and 10.1002\/ange.201711552. [PDF]<\/a><\/li>\n
      13. Wang HF, Tang C, Zhang Q<\/u><\/strong>. Template growth of nitrogen-doped mesoporous graphene on metal oxides and its use as a metal-free bifunctional electrocatalyst for oxygen reduction and evolution reactions. Catalysis Today <\/em><\/strong>2018, 301, 25-31. doi: 10.1016\/j.cattod.2017.02.012. [PDF]<\/a><\/li>\n
      14. Tang C, Wang HF, Zhang Q. Multiscale Principles to Boost Reactivity in Gas-Involving Energy Electrocatalysis Accounts of Chemical Research<\/em><\/strong> 2018, DOI: 10.1021\/acs.accounts.7b00616. [PDF]<\/a><\/li>\n
      15. Zhang R, Chen X, Shen X, Zhang XQ, Chen XR, Cheng XB, Yan C, Zhao CZ, Zhang Q. Coralloid Carbon Fibers based Composite Lithium Anode for Robust Lithium Metal Batteries. Joule<\/em><\/strong> 2018, 10.1016\/j.joule.2018.02.001. [PDF]<\/a><\/li>\n
      16. Yan C, Cheng XB, Tian Y, Chen X, Zhang XQ, Li WJ, Huang JQ, Zhang Q. Dual-Layered Film Protected Lithium Metal Anode to Enable Dendrite-Free Lithium Deposition. Advanced Materials<\/em><\/strong> 2018, 30, 1707629. DOI: 10.1002\/adma.201707629.[PDF]<\/a><\/li>\n
      17. Zhang XQ, Chen X, Cheng XB, Li BQ, Shen X, Yan C, Huang JQ, Zhang Q. Highly Stable Lithium Metal Batteries Enabled by Regulating the Li+ Solvation in Nonaqueous Electrolyte. Angewandte Chemie International Edition <\/em><\/strong>2018, DOI: 10.1002\/anie.201801513 and 10.1002\/ange.201801513.[PDF]<\/a><\/li>\n
      18. Li T, Liu H, Shi P, Zhang Q. Recent Progress on Carbon\/Lithium Metal Composite Anode for Safe Lithium Metal Batteries. Rare Metals <\/em><\/strong>2018.<\/li>\n<\/ol>\n

        2017<\/strong><\/p>\n

          \n
        1. Liu X, Huang JQ, Zhang Q<\/u><\/strong>, Mai LQ. Nanostructured Metal Oxides and Sulfides for Lithium-Sulfur Batteries. Advanced Materials <\/em><\/strong>2017, 29, 1601759. doi: 10.1002\/adma.201601759. [PDF]<\/a><\/li>\n
        2. Tang C, Zhang Q<\/u><\/strong>. Nanocarbon for Oxygen Reduction Electrocatalysis: Dopants, Edges, and Defects. Advanced Materials<\/em><\/strong> 2017, 29, 1604103. doi: 10.1002\/adma.201604103. [PDF]<\/a><\/li>\n
        3. Cheng XB, Yan C, Huang JQ, Li P, Zhu L, Zhao LD, Zhang YY, Zhu WC, Yang ST, Zhang Q<\/u><\/strong>. The gap between long lifespan Li-S coin and pouch cells: The importance of lithium metal anode protection. Energy Storage Materials <\/em><\/strong>2017, 6, 18-25. doi: 10.1016\/j.ensm.2016.09.003. [PDF]<\/a><\/li>\n
        4. Zhai PY, Huang JQ, Zhu L, Shi JL, Zhu WC, Zhang Q.<\/u><\/strong> Calendering of free-standing electrode for lithium-sulfur batteries with high volumetric energy density. Carbon<\/em><\/strong> 2017, 111, 493-501. doi: 10.1016\/j.carbon.2016.10.035. [PDF]<\/a><\/li>\n
        5. Huang JQ, Sun YZ, Wang YF, Zhang Q<\/u><\/strong>. Review on advanced functional separators for lithium-sulfur batteries. Acta Chimica Sinica<\/em><\/strong> 2017, 75, 173-188. DOI: 10.6023\/A16080454. [PDF]<\/a><\/li>\n
        6. Li J, Peng WC, Zhang Q<\/u><\/strong>, Luo GH, Zhu QS, Wei F. Novel Hierarchical Ni\/MgO Catalyst for Highly Efficient CO Methanation in a Fluidized Bed Reactor. AIChE J.<\/em><\/strong> 2017, DOI: 10.1002\/aic.15597. [PDF]<\/a><\/li>\n
        7. Zhang R, Li NW, Cheng XB, Yin YX, Zhang Q<\/u><\/strong>, Guo YG. Advanced Micro\/Nanostructures for Lithium Metal Anodes. Advanced Science <\/em><\/strong>2017, 4, 1600445. doi: 10.1002\/advs.201600445. [PDF]<\/a><\/li>\n
        8. Wang D, Zhang W, Zheng WT, Cui XQ, Rojo T, Zhang Q<\/u><\/strong>. Towards High-Safe Lithium Metal Anodes: Suppressing Lithium Dendrites via Tuning Surface Energy Advanced Science <\/em><\/strong>2017, 4, 1600168. doi:10.1002\/advs.201600168. [PDF]<\/a><\/li>\n
        9. Zhang XQ, Cheng XB, Chen X, Yan C, Zhang Q<\/u><\/strong>. Fluoroethylene Carbonate Additives to Render Uniform Li Deposits in Lithium Metal Batteries. Advanced Functional Materials <\/em><\/strong>2017, 27, 1605989. doi:10.1002\/adfm.201605989. [PDF]<\/a><\/li>\n
        10. Zhai PY, Peng HJ, Cheng XB, Zhu L, Huang JQ, Zhu WC, Zhang Q<\/u><\/strong>. Scaled-up fabrication of porous-graphene-modified separator for high-capacity lithium\u2212sulfur batteries. Energy Storage Materials <\/em><\/strong>2017, 7, 56-63. doi: 10.1016\/j.ensm.2016.12.004. [PDF]<\/a><\/li>\n
        11. Cheng XB, Yan C, Chen X, Guan C, Huang JQ, Peng HJ, Zhang R, Yang ST, Zhang Q<\/u><\/strong>. Implantable Solid Electrolyte Interphase in Lithium Metal Batteries. Chem<\/em><\/strong> 2017, 2, 258-270. doi: 10.1016\/j.chempr.2017.01.003. [PDF]<\/a><\/li>\n
        12. Chen X, Hou TZ, Li B, Zhu L, Yan C, Cheng XB, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>. Towards Stable Lithium-Sulfur Batteries: Mechanistic Insights into Electrolyte Decomposition on Lithium Metal Anode. Energy Storage Materials <\/em><\/strong>2017, 8, 194-201. in press. doi: 10.1016\/j.ensm.2017.01.003. [PDF]<\/a><\/li>\n
        13. Shi W, Wu KH, Xu JY, Zhang Q, Zhang BS, Su DS, Enhanced Stability of Immobilized Pt Nanoparticles through Nitrogen Heteroatoms on Doped Carbon Supports Chemistry of Materials <\/em><\/strong>2017, 29, 8670\u20138678. DOI: 10.1021\/acs.chemmater.7b02658. [PDF]<\/a><\/li>\n
        14. Zhu XL, Zhang Q<\/u><\/strong>, Huang C, Wang Y, Yang CH, Wei F. Validation of surface coating with nanoparticles to improve the flowability of fine cohesive powders. Particuology <\/em><\/strong>2017, 30, 53-61. doi: 10.1016\/j.partic.2016.09.001. [PDF]<\/a><\/li>\n
        15. Xiao XF, He XT, Zhao SL, Li J, Lin WS, Yuan ZK, Zhang Q<\/u><\/strong>, Wang SY, Dai LM, Yu DS. A general approach to cobalt-based homobimetallic phosphide ultrathin nanosheets for highly efficient oxygen evolution. Energy & Environmental Science<\/em><\/strong>, 2017, DOI: 10.1039\/C6EE03145E. [PDF]<\/a><\/li>\n
        16. Li P, Li J, Zhao Z, Fang ZS, Yang MJ, Yuan ZK, Zhang Y, Zhang Q<\/u><\/strong>, Chen XD, Hong W, Yu DS. A General Electrode Design Strategy for Flexible Fiber Micro-Pseudocapacitors Combining Ultrahigh Energy and Power Delivery Advanced Science<\/em><\/strong> 2017, 4, 1700003. DOI: 10.1002\/advs.201700003. [PDF]<\/a><\/li>\n
        17. Peng HJ, Huang JQ, Cheng XB, Zhang Q<\/u><\/strong>. Review on High-Loading and High-Energy Lithium-Sulfur Batteries. Advanced Energy Materials <\/em><\/strong>2017, 7, 1700260. DOI: 10.1002\/aenm.201700260. [PDF]<\/a><\/li>\n
        18. Chen CY, Peng HJ, Hou TZ, Zhai PY, Li BQ, Tang C, Zhu W, Huang JQ, Zhang Q<\/u><\/strong>. A Quinonoid-Imine-Enriched Nanostructured Polymer Mediator for Lithium\u2212Sulfur Batteries Advanced Materials<\/em><\/strong> 2017, 29, 1606802, doi:10.1002\/adma.201606802. [PDF]<\/a><\/li>\n
        19. Chen X, Peng HJ, Zhang R, Hou TZ, Huang JQ, Li B, Zhang Q<\/u><\/strong>. An Analogous Periodic Law for Strong Anchoring of Polysulfides on Polar Hosts in Lithium Sulfur Batteries: S- or Li-Binding on First-Row Transition-Metal Sulfides? ACS Energy Letters <\/em><\/strong>2017, 2, 795-801. DOI: 10.1021\/acsenergylett.7b00164. [PDF]<\/a><\/li>\n
        20. Peng HJ, Huang JQ, Liu XY, Cheng XB, Xu WT, Zhao CZ, Wei F, Zhang Q<\/u><\/strong>. Healing High-Loading Sulfur Electrodes with Unprecedented Long Cycling Life: Spatial Heterogeneity Control. Journal of the American Chemical Society <\/em><\/strong>2017, 139 (25), 8458\u20138466. DOI: 10.1021\/jacs.6b12358. [PDF]<\/a><\/li>\n
        21. Li BQ, Zhang SY, Tang C, Cui XY, Zhang Q<\/u><\/strong>. Anionic Regulated NiFe (Oxy)Sulfide Electrocatalysts for Water Oxidation. Small<\/em><\/strong> 2017, 13, 1700610. doi:10.1002\/smll.201700610. [PDF]<\/a><\/li>\n
        22. Chi SF, Liu YC, Song WL, Fan LZ, Zhang Q<\/u><\/strong>, Pre-Storing Lithium into Stable 3D Nickel Foam Host as Dendrite-Free Lithium Metal Anode. Advanced Functional Materials <\/em><\/strong>2017, 27, 1700348, doi: 10.1002\/adfm.201700348. [PDF]<\/a><\/li>\n
        23. Xie J, Peng HJ, Huang JQ, Xu WT, Chen X, Zhang Q<\/u><\/strong>. A Supramolecular Capsule for Reversible Polysulfide Storage\/Delivery in Lithium\u2013Sulfur Batteries. Angewandte Chemie International Edition<\/em><\/strong> 2017, 56, 16223-16227. DOI: 10.1002\/anie.201710025 and 10.1002\/ange.201710025. [PDF]<\/a><\/li>\n
        24. Zhang G, Zhang ZW, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>. A Toolbox for Lithium-Sulfur Battery Research: Methods and Protocols. Small Methods<\/em><\/strong> 2017, 1, 1700134, doi: 10.1002\/smtd.201700134. [PDF]<\/a><\/li>\n
        25. Zhang R, Chen XR, Chen X, Cheng XB, Zhang XQ, Yan C, Zhang Q<\/u><\/strong>. Lithiophilic Sites in Doped Graphene Guide Uniform Lithium Nucleation for Dendrite-Free Lithium Metal Anodes Angewandte Chemie Interational Edition. <\/em><\/strong>2017, 56, 7764\u20137768, doi: 10.1002\/anie.201702099. [PDF]<\/a><\/li>\n
        26. Kong L, Peng HJ, Huang JQ, Zhang Q. A review of nanostructured current collectors in lithium\u2013sulfur batteries Nano Research<\/em><\/strong> 2017, DOI: 10.1007\/s12274-017-1652-x. [PDF]<\/a><\/li>\n
        27. Hou TZ, Xu WT, Chen X, Peng HJ , Huang JQ, Zhang Q<\/u><\/strong>. Lithium Bond Chemistry in Lithium\u2013Sulfur Batteries. Angewandte Chemie Interational Edition <\/em><\/strong>2017, 56, 8178\u20138182, doi: 10.1002\/anie.201704324. [PDF]<\/a><\/li>\n
        28. Kong L, Peng HJ, Huang JQ, Zhu WC, Zhang G, Zhang ZW, Zhai PY, Sun JJ, Xie J, Zhang Q<\/u><\/strong>. Beaver-dam-like membrane: A robust and sulphifilic MgBO2(OH)\/CNT\/PP nest separator in Li-S batteries. Energy Storage Materials<\/em><\/strong> 2017, 8, 153-160. doi: 10.1016\/j.ensm.2017. 05.009. [PDF]<\/a><\/li>\n
        29. Cheng XB, Chen C, Zhao MQ, Pentecost A, Zhang XQ, Mathis T, Jiang JJ, Zhang Q<\/u><\/strong>, Gogotsi Y, Nanodiamonds Suppress the Growth of Lithium Dendrites, Nature Communications<\/em><\/strong> 2017, NCOMMS-16-29756. [PDF]<\/a><\/li>\n
        30. Wang HF, Tang C, Wang B, Li BQ, Zhang Q. Bifunctional Transition Metal Hydroxysulfides: Room-Temperature Sulfurization and Their Applications in Zn-Air Batteries. Advanced Materials<\/em><\/strong> 2017, 29, 1702327, doi: 10.1002\/adma.201702327. [PDF]<\/a><\/li>\n
        31. Xu QH, Liu ZM, Jiang H, Zhang Q, Zan C, Ma DS, Shi L. Chemical-Structural Properties of the Coke Produced by Low Temperature Oxidation Reactions during Crude Oil in-situ Combustion. Fuel<\/em><\/strong> 2017, 207, 179-188. [PDF]<\/a><\/li>\n
        32. Hao GP, Tang C, Zhang E, Zhai PY, Yin J, Zhu W, Zhang Q, Kaskel S. Thermal Exfoliation of Layered Metal\u2212Organic Frameworks into Ultra-Hydrophilic Graphene Stacks and Their Applications in Li-S Batteries. Advanced Materials<\/em><\/strong> 2017, 29, 1702829, doi: 10.1002\/adma.201702829. [PDF]<\/a><\/li>\n
        33. Yuan H, Kong L, Li T, Zhang Q. A review of transition metal chalcogenide\/graphenenanocomposites for energy storage and conversion. Chinese Chemical Letters <\/em><\/strong>2017, 28, 2180-2194. doi: 10.1016\/j.ccle.2017.11.038. [PDF]<\/a><\/li>\n
        34. Cheng XB, Zhang R, Zhao CZ, Zhang Q<\/u><\/strong>. Toward Safe Lithium Metal Anode in Rechargeable Batteries: A Review. Chemical Reviews<\/em><\/strong> 2017, 117, 10403\u201310473. cr-2017-00115d. [PDF]<\/a><\/li>\n
        35. Li BQ, Xia ZJ, Zhang BS, Tang C, Wang HF, Zhang Q<\/u><\/strong>. Regulating p-block metals in perovskite nanodots for efficient electrocatalytic water oxidation. Nature Communications <\/em><\/strong>2017, in press. [PDF]<\/a><\/li>\n
        36. Tang C, Wang B, Wang HF, Zhang Q. Defect Engineering of Co\/N\/O Tri-Doped Hierarchical Graphene for Rechargeable Flexible Solid Zn-Air Batteries Advanced Materials<\/em><\/strong> 2017, 29, 1703185. doi: 10.1002\/adma.201703185. [PDF]<\/a><\/li>\n
        37. Zhao CZ, Zhang XQ, Cheng XB, Zhang R, Xu R, Chen PY, Peng HJ, Huang JQ, Zhang Q. An Anion-Immobilized Composite Electrolyte for Dendrite-Free Lithium Metal Anodes. Proceedings of the National Academy of Sciences of the United States of America (PNAS)<\/em><\/strong> 2017, 114, 11069-11074. doi: 10.1073\/pnas.1708489114. [PDF]<\/a><\/li>\n
        38. Peng HJ, Huang JQ, Zhang Q. A review of flexible lithium\u2013sulfur and analogous alkali metal\u2013chalcogen rechargeable batteries. Chemical Society Reviews<\/em><\/strong> 2017, 46, 5237-5288 doi: 10.1039\/C7CS00139H. [PDF]<\/a><\/li>\n
        39. Qiao M, Tang C, Tanase LC, Teodorescu CM, Chen CM, Zhang Q, Titirici MM. Oxygenophilic Ionic Liquids Promote the Oxygen Reduction Reaction in Pt-Free Carbon Electrocatalysts  Materials Horizons <\/em><\/strong>2017 4, 895-899. DOI: 10.1039\/C7MH00298J. MH-COM-05-2017-000298. [PDF]<\/a><\/li>\n
        40. Zhang XQ, Xu R, Chen X, Cheng XB, Zhang R, Chen XR, Zhang Q. Columnar Lithium Metal Anodes. Angewandte Chemie International Edition<\/em><\/strong> 2017, 56, 14207-14211. doi: 10.1002\/anie.201707093. [PDF]<\/a><\/li>\n
        41. Tang C, Titirici MM, Zhang Q, A review of nanocarbons in energy electrocatalysis: Multifunctional substrates and highly active sites. Journal of Energy Chemistry<\/em><\/strong> 2017, 26, 1077-1093. doi: 10.1016\/j.jechem.2017.08.008. [PDF]<\/a><\/li>\n
        42. Huang JQ, Zhai PY, Peng HJ, Zhu WC, Zhang Q<\/u><\/strong>. Layered Metal\/Nanocarbon Current Collectors Enhanced Energy Efficiency in Lithium\u2013Sulfur Batteries Science Bulletin <\/em><\/strong>2017, 62, 1267-1274. doi: 10.1016\/j.scib.2017.09.007. [PDF]<\/a><\/li>\n
        43. Xu R, Sun YZ, Wang YF, Huang JQ, Zhang Q. Two-dimensional vermiculite separator for lithium sulfur batteries. Chinese Chemical Letters<\/em><\/strong> 2017, 28, 2235-2238. [PDF]<\/a><\/li>\n
        44. Sun YZ, Huang JQ, Zhao CZ, Zhang Q. A review of solid electrolytes for safe lithium-sulfur batteries. Science China Chemistry<\/em><\/strong> 2017, 60, 1508\u20131526 doi: 10.1007\/s11426-017-9164-2.299. [PDF]<\/a><\/li>\n
        45. Zhong L, Tang C, Wang B, Wang HF, Gao S, Wang Y, Zhang Q. SAPO-34 templated growth of hierarchical porous graphene cages as bifunctional oxygen reduction and evolution electrocatalysts. New Carbon Materials<\/em><\/strong> 2017, 32, 509-516. [PDF]<\/a><\/li>\n<\/ol>\n

          2016<\/strong><\/p>\n

            \n
          1. Cheng XB, Zhang R, Zhao CZ, Wei F, Zhang JG, Zhang Q<\/u><\/strong>. A Review of Solid Electrolyte Interphases on Lithium Metal Anode. Advanced Science<\/em><\/strong> 2016, 3, 1500213. [PDF]<\/a><\/li>\n
          2. Peng HJ, Wang DW, Huang JQ, Cheng XB, Yuan Z, Wei F, Zhang Q<\/u><\/strong>. Janus Separator of Polypropylene-Supported Cellular Graphene Framework for Sulfur Cathodes with High Utilization in Lithium-Sulfur Batteries. Advanced Science <\/em><\/strong>2016, 3, 1500268.
            [PDF]<\/a><\/li>\n
          3. Zhu XL, Zhang Q<\/u><\/strong>, Wang Y, Wei F. Review on the nanoparticle fluidization science and technology. Chinese Journal of Chemical Engineering<\/em><\/strong> 2016, 24, 9-22. doi: 10.1016\/j.cjche.2015.06.005. [PDF]<\/a><\/li>\n
          4. Zhang R, Cheng XB, Zhao CZ, Peng HJ, Shi JL, Huang JQ, Wang JF, Wei F, Zhang Q<\/u><\/strong>. Conductive Nanostructured Scaffolds Render Low Local Current Density to Inhibit Lithium Dendrite Growth. Advanced Materials<\/em><\/strong>. 2016, 28, 2155-2162. doi:10.1002\/adma.201504117. [PDF]<\/a><\/li>\n
          5. Yuan Z, Peng HJ, Hou TZ, Huang JQ, Chen CM, Wang DW, Cheng XB, Wei F, Zhang Q<\/u><\/strong>. Powering lithium\u2013sulphur battery performance by propelling polysulphide redox at sulphiphilic hosts. Nano Letters <\/em><\/strong>2016, 16(1), 519-527. doi: 10.1021\/acs.nanolett.5b04166. [PDF]<\/a><\/li>\n
          6. Cheng XB, Hou TZ, Zhang R, Peng HJ, Zhao CZ, Huang JQ, Zhang Q<\/u><\/strong> Dendrite-Free Lithium Deposition Induced by Uniformly Distributed Lithium-Ions for Efficient Lithium Metal Batteries. Advanced Materials<\/em><\/strong>,<\/em> 2016, 28(15), 2888-2895.
            doi:10.1002\/adma.201506124.             [PDF]<\/a><\/li>\n
          7. Zhang RF, Ning ZY, Xu ZW, Zhang YY, Xie HH, Ding F, Chen Q, Zhang Q<\/u><\/strong>, Qian WZ, Cui Y, Wei F. Interwall Friction and Sliding Behavior of Centimeters Long Double-Walled Carbon Nanotubes. Nano Letters<\/em><\/strong> 2016, 16(2), 1367-1374. DOI: 10.1021\/acs.nanolett.5b04820. [PDF]<\/a><\/li>\n
          8. Zhao CZ, Cheng XB, Zhang R, Peng HJ, Huang JQ, Ran R, Huang ZH, Wei F, Zhang Q<\/u><\/strong>, Li2<\/sub>S5<\/sub>-based Ternary-Salt Electrolyte for Robust Lithium Metal Anode. Energy Storage Materials<\/em><\/strong> 2016, 3, 77-84. doi: 10.1016\/j.ensm.2016.01.007. [PDF]<\/a><\/li>\n
          9. Wang HF, Tang C, Zhu XL, Zhang Q<\/u><\/strong>. A \u2018point-line-point\u2019 hybrid electrocatalyst for bi-functional catalysis of oxygen evolution and reduction reactions. Journal of Materials Chemistry A <\/em><\/strong>2016, 4(9),3379-3385. doi: 10.1039\/C5TA09327A. [PDF]<\/a><\/li>\n
          10. Tang C, Wang HF, Wang HS, Wei F, Zhang Q<\/u><\/strong>. Guest-Host Modulation of Multi-Metallic (Oxy)hydroxides for Superb Water Oxidation. Journal of Materials Chemistry A <\/em><\/strong>2016, 4(9), 3210-3216. doi:10.1039\/C6TA00328A. [PDF]<\/a><\/li>\n
          11. Tang C, Zhang Q<\/u><\/strong>. Can Metal-Nitrogen-Carbon Catalysts Satisfy the Oxygen Electrochemistry? Journal of Materials Chemistry A<\/em><\/strong>. 2016, 4, 4998-5001. doi: 10.1039\/C6TA01062H. [PDF]<\/a><\/li>\n
          12. Shi JL, Wang HF, Zhu XL, Chen CM, Huang X, Zhang XD, Li BQ, Tang C, Zhang Q<\/u><\/strong>. The nanostructure preservation of 3D graphene: New insights into the graphene stacking and surface chemistry of unstacked double-layered graphene after high-temperature treatment. Carbon <\/em><\/strong>2016, 103, 36-44. doi: 10.1016\/j.carbon.2016.03.002. [PDF]<\/a><\/li>\n
          13. Tang C, Wang HF, Zhu XL, Li BQ, Zhang Q. Advances in Hybrid Electrocatalysts for Oxygen Evolution Reaction: Rational Integration of NiFe Layered Double Hydroxides and Nanocarbon. Particle & Particle Systems Characterization<\/em><\/strong> 2016, 33, 473-486. doi:10.1002\/ppsc. 201600004. [PDF]<\/a><\/li>\n
          14. Guo MQ, Huang JQ, Kong XY, Peng HJ, Shui H, Qian FY, Zhu L, Zhu WC, Zhang Q<\/u><\/strong>. Hydrothermal synthesis of porous phosphorus-doped carbon nanotubes and their use in the oxygen reduction reaction and lithium-sulfur batteries. New Carbon Materials <\/em><\/strong>2016, 31, 352-363. [PDF]<\/a><\/li>\n
          15. Chen CY, Tang C, Wang HF, Chen CM, Zhang XY, Huang X, Zhang Q<\/u><\/strong>. Oxygen reduction reaction on graphene in electro-Fenton system: In-situ generation of H2<\/sub>O2<\/sub> as hydroxyl radical precursors for oxidation of organic compounds. ChemSusChem<\/em><\/strong> 2016, 9, 1194-1199. doi: 10.1002\/cssc.201600030. [PDF]<\/a><\/li>\n
          16. Hou TZ, Chen X, Peng HJ, Huang JQ, Li BQ, Zhang Q, Li B. Design Principles for Heteroatom-Doped Nanocarbon to Achieve Strong Anchoring of Polysulfides for Lithium-Sulfur Batteries. Small<\/em><\/strong>,<\/em> 2016, 12, 3283-3291; doi:10.1002\/smll.201600809. [PDF]<\/a><\/li>\n
          17. Zhang ZQ, Zhang H, Zhu L, Zhang Q<\/u><\/strong>, Zhu WC. Hierarchical porous Ca(BO2<\/sub>)2<\/sub> microspheres: Hydrothermal-thermal conversion synthesis and their applications in heavy metal ions adsorption and solvent-free oxidation of benzyl alcohol. Chemical Engineering Journal<\/em><\/strong> 2016, 283, 1273-1284. doi:10.1016\/j.cej.2015.08.073. [PDF]<\/a><\/li>\n
          18. Zhuang TZ, Huang JQ, Peng HJ, He LY, Cheng XB, Chen CM, Zhang Q<\/u><\/strong>. Rational Integration of Polypropylene\/Graphene Oxide\/Nafion as Ternary Layered Separator to Retard the Shuttle of Polysulfides for Lithium\u2013Sulfur Batteries. Small<\/em><\/strong>. 2016, 12(3), 381-389. doi: 10.1002\/smll.201503133. [PDF]<\/a><\/li>\n
          19. Tang C, Li BQ, Zhang Q,<\/u><\/strong> Zhu L, Wang HF, Shi JL, Wei F. CaO-Templated Growth of Hierarchical Porous Graphene for High-Power Lithium-Sulfur Battery Applications. Advanced Functional Materials<\/em><\/strong>. 2016, 26, 577-585. doi:10.1002\/afm.201503726. [PDF]<\/a><\/li>\n
          20. Zhu XL, Tang C, Wang HF, Li BQ, Zhang Q<\/u><\/strong>, Li CY, Yang CH, Wei F. Monolithic-Structured Ternary Hydroxides as Freestanding Bifunctional Electrocatalysts for Overall Water Splitting. Journal of Materials Chemistry A <\/em><\/strong>2016, 4, 7245-7250. doi: 10.1039\/C6TA02216B. [PDF]<\/a><\/li>\n
          21. Tang C, Wang HF, Chen X, Li BQ, Hou TZ, Zhang BS, Zhang Q<\/u><\/strong>, Titirici MM, Wei F. Topological Defects in Metal-Free Nanocarbons for Oxygen Electrocatalysis. Advanced Materials <\/em><\/strong>2016, 28, 6845-6851. doi:10.1002\/adma.201601406. [PDF]<\/a><\/li>\n
          22. Zhang XQ, Cheng XB, Zhang Q<\/u><\/strong>. Nanostructured energy materials for electrochemical energy conversion and storage: A review. Journal of Energy Chemistry <\/em><\/strong>2016, 25, 967-984. doi: 10.1016\/j.jechem.2016.11.003. [PDF]<\/a><\/li>\n
          23. Sun X, Hao G, Lu X, Xi L, Liu B, Si W, Ma C, Q. Liu, Zhang Q<\/u><\/strong>, Kaskel S, Schmidt OG, High-defect hydrophilic carbon cuboids anchored with Co\/CoO nanoparticles as highly efficient and ultra-stable lithium-ion battery anodes. Journal of Materials Chemistry A<\/em><\/strong> 2016 ,4, 10166-10173 DOI: 10.1039\/C6TA03098J. [PDF]<\/a><\/li>\n
          24. Rybarczyk MK, Peng HJ, Tang C, Lieder M, Zhang Q<\/u><\/strong>, Titirici MM. Porous carbon derived from rice husks as sustainable bioresources: Insights into the role of micro-\/mesoporous hierarchy in hosting active species for lithium\u2013sulphur batteries. Green Chemistry<\/em><\/strong> 2016, 18, 5169-5179. doi:10.1039\/C6GC00612D. [PDF]<\/a><\/li>\n
          25. Peng HJ, Xu WT, Zhu L, Wang DW, Huang JQ, Cheng XB, Yuan Z, Wei F, Zhang Q<\/u><\/strong>. 3D Carbonaceous Current Collectors: The Origin of Enhanced Cycling Stability for High-Sulfur-Loading Lithium\u2212Sulfur Batteries. Advanced Functional Materials<\/em><\/strong> 2016, 26, 6351-6358. 10.1002\/adfm.201602071. [PDF]<\/a><\/li>\n
          26. Peng HJ, Zhang G, Chen X, Zhang ZW, Xu WT, Huang JQ, Zhang Q<\/u><\/strong>. Enhanced Electrochemical Kinetics on Conductive Polar Mediators for Lithium\u2212Sulfur Batteries. Angewandte Chemie International Edition<\/em><\/strong> 2016, 55, 12990-12995. DOI: 10.1002\/anie.201605676 and 10.1002\/ange.201605676. [PDF]<\/a><\/li>\n
          27. Tian GL, Huang JQ, Li J, Zhang Q<\/u><\/strong>, Wei F. Enhanced growth of carbon nanotube bundles in a magnetically assisted fluidized bed chemical vapor deposition. Carbon<\/em><\/strong> 2016, 108, 404-411. doi: 10.1016\/j.carbon.2016.07.036. [PDF]<\/a><\/li>\n
          28. Yan C, Cheng XB, Zhao CZ, Huang JQ, Yang ST, Zhang Q<\/u><\/strong>. Lithium metal protection through in-situ<\/em> formed solid electrolyte interphase in lithium-sulfur batteries: The role of polysulfides on lithium anode. Journal of Power Sources<\/em><\/strong>, 2016, 327, 212-220. doi: 10.1016\/j.jpowsour.2016.07.056. Carbon<\/em><\/strong> 2016, 108, 404-411. doi: 10.1016\/j.carbon.2016.07.036. [PDF]<\/a><\/li>\n
          29. Qiao M, Tang C, He GJ, Qiu KP, Binions R, Parkin IP, Zhang Q<\/u><\/strong>, Guo ZX, Titirici MM. Graphene\/nitrogen-doped porous carbon sandwiches for the metal-free oxygen reduction reaction: conductivity versus active sites. Journal of Materials Chemistry A <\/em><\/strong>2016, 4, 12658-12666 DOI: 10.1039\/C6TA04578B. Carbon<\/em><\/strong> 2016, 108, 404-411. doi: 10.1016\/j.carbon.2016.07.036. [PDF]<\/a><\/li>\n
          30. Peng HJ, Zhang ZW, Huang JQ, Zhang G, Xie J, Xu WT, Shi JL, Chen X, Cheng XB, Zhang Q<\/u><\/strong>. A Cooperative Interface for Highly Efficient Lithium\u2212Sulfur Batteries. Advanced Materials <\/em><\/strong>2016, 28, 9551-9558. doi:10.1002\/adma.201603401. Carbon<\/em><\/strong> 2016, 108, 404-411. doi: 10.1016\/j.carbon.2016.07.036. [PDF]<\/a><\/li>\n
          31. Zheng QW, Huang L, Zhang Y, Wang JY, Zhao CZ, Zhang Q, Zheng WJ, Cao DP, OHare D, Wang Q. Unexpected highly reversible topotactic CO2<\/sub> sorption\/desorption capacity for potassium dititanate. Journal of Materials Chemistry A <\/em><\/strong>2016, 4, 12889-12896. DOI: 10.1039\/C6TA04117E. Carbon<\/em><\/strong> 2016, 108, 404-411. doi: 10.1016\/j.carbon.2016.07.036. [PDF]<\/a><\/li>\n
          32. Li BQ, Tang C, Wang HF, Zhu XL, Zhang Q<\/u><\/strong>. An aqueous preoxidation method for monolithic perovskite electrocatalysts with enhanced water oxidation performance. Science Advances<\/em><\/strong> 2016, 2, e1600495. [PDF]<\/a><\/li>\n
          33. Shi W, Zhang BS, Lin YM, Wang Q, Zhang Q<\/u><\/strong>, Su DS. Enhanced Chemoselective Hydrogenation through Tuning the Interaction between Pt Nanoparticles and Carbon Supports: Insights from Identical Location Transmission Electron Microscopy and X-ray Photoelectron Spectroscopy. ACS Catalysis <\/em><\/strong>2016, 6, 7844-7854. DOI: 10.1021\/acscatal.6b02207. [PDF]<\/a><\/li>\n
          34. Hao GP, Zhang Q, Sin M, Hippauf F, Borchart L, Brunner E, Kaskel S. Design of Hierarchically Porous Carbons with Interlinked Hydrophilic and Hydrophobic Surface and Their Capacitive Behavior. Chemistry of Materials<\/em><\/strong> 2016, 28, 8715\u20138725. doi: 10.1021\/acs.chemmater.6b03964. [PDF]<\/a><\/li>\n
          35. Zhang TB, Cheng XB, Zhang Q, Lu YC, Luo GS. Construction of a cathode using amorphous FePO4<\/sub> nanoparticles for a high-power\/energy-density lithium-ion battery with long-term stability. Journal of Power Sources<\/em><\/strong> 2016, 324, 52-60. [PDF]<\/a><\/li>\n<\/ol>\n

            2015<\/strong><\/p>\n

              \n
            1. Yu JF, Zhu L, Fan C, Zhang Q<\/u><\/strong>, Zan C, Hu L, Yang SH, Zhu WC, Shi L, Wei F. Highly dispersed Mn2<\/sub>O3<\/sub> microspheres: Facile solvothermal synthesis and their applications as anodes for Li-ion batteries. Particuology<\/em><\/strong> 2015, 22, 85-94. doi: 10.1016\/j.partic.2014.10.007. [PDF]<\/a><\/li>\n
            2. Cheng XB, Zhang Q<\/u><\/strong>, Wang HF, Tian GL, Huang JQ, Peng HJ, Zhao MQ, Wei F. Nitrogen-doped herringbone carbon nanofibers with large lattice spacings and abundant edges: Catalytic growth and their applications in lithium ion batteries and oxygen reduction reactions. Catalysis Today <\/em><\/strong>2015, 249, 244-251. doi: 10.1016\/j.cattod.2014.10.047. [PDF]<\/a><\/li>\n
            3. Zhu L, Peng HJ, Liang JY, Huang JQ, Chen CM, Guo XF, Zhu WC, Li P, Zhang Q<\/u><\/strong>. Interconnected carbon nanotube\/graphene nanosphere scaffolds as free-standing paper electrode for high-rate and ultra-stable lithium-sulfur batteries. Nano Energy<\/em><\/strong> 2015, 11, 745-755. doi: 10.1016\/j.nanoen.2014.11.062. [PDF]<\/a><\/li>\n
            4. Tian GL, Zhang Q<\/u><\/strong>, Zhao MQ, Wang HF, Chen CM, Wei F. Fluidized-bed CVD of unstacked double-layer templated graphene and its application in supercapacitors AIChE Journal <\/em><\/strong>2015, 61(3), 747-755. doi: 10.1002\/aic.14710. [PDF]<\/a><\/li>\n
            5. Liu Z, Kong QQ, Chen CM, Zhang Q<\/u><\/strong>, Hu L, Li XM, Han PD, Cai R. From two-dimensional to one-dimensional structures: SiC nano-whiskers derived from graphene via a catalyst-free carbothermal reaction. RSC Advances <\/em><\/strong>2015, 5(8), 5946-5949. doi: 10.1039\/C4RA11380B. [PDF]<\/a><\/li>\n
            6. Gao G, Zhang Q<\/u><\/strong>, Cheng XB, Qiu PY, Sun RJ, Yin T, Cui DX. CNTs in situ embedded into \u03b1-Fe2<\/sub>O3<\/sub> submicron spheres for enhancing lithium storage capacity. ACS Applied Materials & Interfaces <\/em><\/strong>2015, 7(1), 340-350. doi:10.1021\/am506238q. [PDF]<\/a><\/li>\n
            7. Jiang W, Yu DS, Zhang Q<\/u><\/strong>, Goh K, Wei L, Yong Y, Jiang R, Wei J, Chen Y. Ternary Hybrids of Amorphous Nickel Hydroxide-Carbon Nanotube-Conducting Polymer for Supercapacitors with High Energy Density, Excellent Rate Capability and Long Cycle Life, Advanced Functional Materials<\/em><\/strong>, 2015, 25(7), 1063\u20131073. DOI: 10.1002\/adfm.201403354. [PDF]<\/a><\/li>\n
            8. Wang ZJ, Weinberg G, Zhang Q<\/u><\/strong>, Lunkenbein T, Klein-Hoffmann A, Kurnatowska M, Plodinec M, Li Q, Chi L, Schlogl R, Willinger MG. Direct Observation of Graphene Growth and Associated Copper Substrate Dynamics by In-Situ<\/em> Scanning Electron Microscopy. ACS Nano<\/em><\/strong> 2015, 9(2), 1506\u20131519. DOI: 10.1021\/nn5059826. [PDF]<\/a><\/li>\n
            9. Huang JQ, Zhuang TZ, Zhang Q<\/u><\/strong>, Peng HJ, Chen CM, Wei F. Permselective Graphene Oxide Membrane for High-Stable and Anti-Self-Discharge Lithium-Sulfur Batteries. ACS Nano<\/em><\/strong>, 2015, 9(3), 3002-3011. DOI: 10.1021\/nn507178a. [PDF]<\/a><\/li>\n
            10. Hou TZ, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>, Li B, The formation of strong-couple interactions between nitrogen-doped graphene and sulfur\/lithium (poly)sulfides in lithium-sulfur batteries. 2D Materials <\/em><\/strong>2015, 2, 014011. [PDF]<\/a><\/li>\n
            11. Cheng XB, Zhang Q<\/u><\/strong>. Dendrite-free lithium metal anodes: Stable solid electrolyte interphase for high-efficiency batteries. Journal of Materials Chemistry A<\/em><\/strong> 2015, 3(14), 7207-7209. 10.1039\/C5TA00689A. [PDF]<\/a><\/li>\n
            12. Shi JL, Peng HJ, Zhu L, Zhu WC, Zhang Q<\/u><\/strong>. Template growth of porous graphene microspheres on layered double oxide catalysts and their applications in lithium-sulfur batteries. Carbon<\/em><\/strong> 2015, 92, 96-105. doi: 10.1016\/j.carbon.2015.03.031. [PDF]<\/a><\/li>\n
            13. Xu WT, Peng HJ, Huang JQ, Zhao CZ, Cheng XB, Zhang Q<\/u><\/strong>, Towards stable lithium-sulfur batteries with low self-discharge rate: Ion diffusion modulation and anode protection. ChemSusChem<\/em><\/strong> 2015, 8, 2892-2901. doi: 10.1002\/cssc.201500428. [PDF]<\/a><\/li>\n
            14. Jiang HF, Zhang Q<\/u><\/strong>, Shi L, Effective thermal conductivity of carbon nanotube-based nanofluid. Journal of the Taiwan Institute of Chemical Engineering <\/em><\/strong>2015, 55, 76-81. doi: 10.1016\/j.jtice.2015.03.037. [PDF]<\/a><\/li>\n
            15. Liu TY, Yuan HG, Li Q, Tang YH, Zhang Q<\/u><\/strong>, Qian WZ, van der Bruggen B, Wang XL. Ion-Responsive Channels of Zwitterion-Carbon Nanotube Membrane for Rapid Water Permeation and Ultra-High Mono-\/Multivalent Ion Selectivity. ACS Nano<\/em><\/strong> 2015, 9(7), 7488\u20137496. doi:10.1021\/acsnano.5b02598. [PDF]<\/a><\/li>\n
            16. Cheng XB, Peng HJ, Huang JQ, Zhang R, Zhao CZ, Zhang Q<\/u><\/strong>. Dual-Phase Lithium Metal Anode Containing a Polysulfide-Induced Solid Electrolyte Interphase and Nanostructured Graphene Framework for Lithium\u2013Sulfur Batteries. ACS Nano<\/em><\/strong> 2015, 9(6), 6373\u20136382. doi:10.1021\/acsnano.5b01990. [PDF]<\/a><\/li>\n
            17. Shi JL, Tian GL, Zhang Q<\/u><\/strong>, Zhao MQ, Wei F. Customized casting of unstacked graphene with high surface area (>1300 m2<\/sup> g-1<\/sup>) and its application in oxygen reduction reaction. Carbon<\/em><\/strong> 2015, 93, 702-712. [PDF]<\/a><\/li>\n
            18. Tang C, Wang HS, Wang HF, Zhang Q<\/u><\/strong>, Tian GL, Nie JQ, Wei F. Spatially Confined Hybridization of Nanometer-Sized NiFe Hydroxides into Nitrogen-Doped Graphene Frameworks Leading to Superior Oxygen Evolution Reactivity. Advanced Materials<\/em><\/strong> 2015, 27(30), 4516-4522. doi: 10.1002\/adma.201501901. [PDF]<\/a><\/li>\n
            19. Fan C, Zan C, Zhang Q<\/u><\/strong>, Shi L, Hao QS, Jiang H, Wei F. Air Injection for Enhanced Oil Recovery: in-situ Monitoring the Low-Temperature Oxidation of Oil through Thermogravimetry\/Differential Scanning Calorimetry and Pressure Differential Scanning Calorimetry Industrial & Engineering Chemistry Research<\/em><\/strong> 2015, 54(26), 6634-6640. doi: 10.1021\/acs.iecr.5b00997. [PDF]<\/a><\/li>\n
            20. Wang HF, Tang C, Zhang Q<\/u><\/strong>. Towards superior oxygen evolution through graphene barriers between metal substrates and hydroxide catalysts. Journal of Materials Chemistry A <\/em><\/strong>2015, 3(31),16183-16189. DOI: 10.1039\/C5TA03422A. [PDF]<\/a><\/li>\n
            21. Peng HJ, Zhang Q<\/u><\/strong>, Designing Host Materials for Sulfur Cathodes: From Physical Confinement to Surface Chemistry. Angewandte Chemie International Edition<\/em><\/strong> 2015, 54, 11018\u201311020. DOI: 10.1002\/anie.201505444 and 10.1002\/ange.201505444. [PDF]<\/a><\/li>\n
            22. Shi JL, Tang C, Peng HJ, Zhu L, Cheng XB, Huang JQ, Zhu WC, Zhang Q<\/u><\/strong>. 3D Mesoporous Graphene: CVD Self-Assembly on Porous Oxide Templates and Applications in High-Stable Li-S Batteries. Small<\/em><\/strong> 2015, 11, 5243-5252, doi: 10.1002\/smll.201501467. [PDF]<\/a><\/li>\n
            23. Chen TC, Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Tang C, Wei F. Rational recipe for bulk growth of graphene\/carbon nanotube hybrids: New insights from in-situ characterization on working catalysts. Carbon<\/em><\/strong> 2015, 95, 292-301. 10.1016\/j.carbon.2015.08.044. [PDF]<\/a><\/li>\n
            24. Huang JQ, Zhang Q<\/u><\/strong>, Wei F. Multi-functional interlayer\/separator system for high-stable lithium-sulfur batteries: Progress and prospects. Energy Storage Materials<\/em><\/strong> 2015 1, 127-145. doi: 10.1016\/j.ensm.2015.09.008. [PDF]<\/a><\/li>\n
            25. Hao GP, Sahraie NR, Zhang Q<\/u><\/strong>, Krause S, Oschatz M, Bachmatiuk A, Strasser P, Kaskel S, Hydrophilic non-precious metal nitrogen-doped carbon electrocatalysts for enhanced efficiency in oxygen reduction reaction. Chemical Communications<\/em><\/strong> 2015, 51, 17285-17288. DOI: 10.1039\/C5CC06256J. [PDF]<\/a><\/li>\n
            26. Gao G, Zhang Q<\/u><\/strong>, Cheng XB, Sun RJ, Shapter JG, Yin T, Cui DX. Synthesis of three-dimensional rare-earth ions doped CNTs-GO-Fe3<\/sub>O4<\/sub> hybrid structures using one-pot hydrothermal method. Journal of Alloys and Compounds<\/em><\/strong> 2015, 649, 82-88. [PDF]<\/a><\/li>\n
            27. Zhu XL, Tang C, Wang HF, Zhang Q<\/u><\/strong>, Yang CH, Wei F. Dual-sized NiFe layered double hydroxides in-situ<\/em> grown on oxygen-decorated self-dispersal nanocarbon as enhanced water oxidation catalysts. Journal of Materials Chemistry A<\/em><\/strong> 2015, 3, 24540-24546. DOI: 10.1039\/C5TA08019C. [PDF]<\/a><\/li>\n
            28. Gao G, Zhang Q<\/u><\/strong>, Cheng XB, Shapter J, Yin T, Sun RJ, Cui DX. Ultrafine ferroferric oxide nanoparticles embedded into mesoporous carbon nanotubes for lithium ion batteries. Scientific Reports<\/em><\/strong> 2015, 5, 17553. doi: 10.1038\/srep17553. [PDF]<\/a><\/li>\n
            29. Fan C, Zhang Q<\/u><\/strong>, Wei F. Towards Controllable Oxidation for Oil Recovery: Low Temperatures Oxidative Decomposition of Heavy Oil on MnO2<\/sub> Catalyst. Chinese Journal of Catalysis<\/em><\/strong> 2015, 36(2), 153-159. doi: 10.1016\/S1872-2067(14)60236-9. [PDF]<\/a><\/li>\n
            30. Zhang Q<\/u><\/strong>. Innovation with carbon materials -A report on the annual world conference on carbon, Carbon 2015. New Carbon Materials<\/em><\/strong> 2015, 30(4), I-IV. [PDF]<\/a><\/li>\n<\/ol>\n

              2014<\/strong><\/p>\n

                \n
              1. Zhu WC*, Zhang LL, Tian GL, Wang RG, Zhang H, Piao XL, Zhang Q*<\/u><\/strong>. Flux and surfactant directed facile thermal conversion synthesis of hierarchical porous MgO for efficient adsorption and catalytic growth of carbon nanotubes. CrystEngComm <\/em><\/strong>2014, 21(3), 308-318. doi:10.1039\/C3CE41394B. (Cover) [PDF]<\/a><\/li>\n
              2. Huang JQ, Zhang Q<\/u><\/strong>, Peng HJ, Liu XY, Qian WZ, Wei F. Ionic shield for polysulfides towards highly-stable lithium\u2013sulfur batteries. Energy & Environmental Science<\/em><\/strong> 2014, 7(1), 347-353. (Cover) [PDF]<\/a><\/li>\n
              3. Shen K, Zhang Q<\/u><\/strong>, Huang ZH, Yang JH, Yang GZ, Shen WC, Kang FY. Interface enhancement of carbon nanotube\/mesocarbon microbead isotropic. Composites Part A <\/em><\/strong>2014, 56: 44-50. [PDF]<\/a><\/li>\n
              4. Chu Y, Zhang Q<\/u><\/strong>, Wu TW, Nawaz Z, Wang Y, Wei F. Ultra-dispersed Pt nanoparticles on SAPO-34\/\u03b3-Al2<\/sub>O3<\/sub> support for efficient propane dehydrogenation. Journal of Nanoscience and Nanotechnology <\/em><\/strong>2014, 14(9), 6900-6906 doi: 10.1166\/jnn.2014.8956. [PDF]<\/a><\/li>\n
              5. Zhao MQ, Peng HJ, Zhang Q<\/u><\/strong>, Huang JQ, Tian GL, Tang C, Hu Li, Jiang HR, Cai HY, Yuan HX, Wei F. Controllable bulk growth of few-layer graphene\/single-walled carbon nanotube hybrids containing Fe@C nanoparticles in a fluidized bed reactor. Carbon<\/em><\/strong> 2014, 67, 554-563. doi: 10.1016\/j.carbon.2013.10.028. [PDF]<\/a><\/li>\n
              6. Fan C, Zan C, Zhang Q<\/u><\/strong>, Ma DS, Chu Y, Jiang H, Shi L, Wei F. The Oxidation of Heavy Oil: Thermogravimetric Analysis and Non-isothermal Kinetics Using the Distributed Activation Energy Model. Fuel Processing Technology<\/em><\/strong>, 2014, 119, 146-150. doi: 10.1016\/j.fuproc. 2013.10.020. [PDF]<\/a><\/li>\n
              7. Liu XY, Peng HJ, Zhang Q<\/u><\/strong>, Huang JQ, Liu XF, Wang L, He XM, Zhu WC, Wei F. Hierarchical carbon nanotube\/carbon black scaffolds as short- and long-range electron pathways with superior Li-ion storage performance. ACS Sustainable Chemistry & Engineering<\/em><\/strong> 2014, 2(2):200-206. doi: 10.1021\/sc400\u200b239u. [PDF]<\/a><\/li>\n
              8. Tian GL, Zhao MQ, Zhang BS, Zhang Q<\/u><\/strong>, Zhang W, Huang JQ, Chen TC, Qian WZ, Su DS, Wei F. Monodisperse embedded nanoparticles derived from an atomic metal-dispersed precursor of layered double hydroxide for architectured carbon nanotube formation. Journal of Materials Chemistry A<\/em><\/strong> 2014, 2(6): 1686-1696. doi: 10.1039\/C3TA14380E. (Cover) [PDF]<\/a><\/li>\n
              9. Peng HJ, Huang JQ, Zhao MQ, Zhang Q<\/u><\/strong>, Liu XY, Qian WZ, Wei F. Nanoarchitectured graphene\/CNT@porous carbon with extraordinary electrical conductivity and interconnected micro\/mesopores for lithium-sulfur batteries. Advanced Functional Materials <\/em><\/strong>2014, 24(19), 2772-2781. doi:10.1002\/adfm.201303296. (Cover) [PDF]<\/a><\/li>\n
              10. Cheng XB, Huang JQ, Peng JQ, Nie JQ, Liu XY, Zhang Q<\/u><\/strong>, Wei F. Polysulfide Shuttle Control: Towards a Lithium-Sulfur Battery with Superior Capacity Performance up to 1000 Cycles by Matching the Sulfur\/Electrolyte Loading. Journal of Power Sources <\/em><\/strong>2014, 253, 263-268. doi:10.1016\/j.jpowsour.2013.12.031. [PDF]<\/a><\/li>\n
              11. Zhou K, Li B, Zhang Q<\/u><\/strong>, Huang JQ, Jia JC, Tian GL, Su DS, Luo GH, Wei F. The Catalytic Pathways of Hydrohalogenation over Metal-Free Nitrogen-Doped Carbon Nanotubes. ChemSusChem<\/em><\/strong> 2014, 7(3), 723-728. doi: 10.1002\/cssc.201300793. (Cover) [PDF]<\/a><\/li>\n
              12. Cheng XB, Huang JQ, Zhang Q<\/u><\/strong>, Peng HJ, Zhao MQ, Wei F. Aligned carbon nanotube\/sulfur composite cathodes with high sulfur content for lithium-sulfur batteries. Nano Energy<\/em><\/strong>, 2014, 4, 65-72. doi:10.1016\/j.nanoen.2013.12.013. [PDF]<\/a><\/li>\n
              13. Tian GL, Zhao MQ, Yu DS, Kong XY, Huang JQ, Zhang Q<\/u><\/strong>, Wei F. Nitrogen-Doped Graphene\/Carbon Nanotube Hybrids: In-Situ Formation on Bifunctional Catalysts and Their Superior Electrocatalytic Activity for Oxygen Reduction Reaction. Small<\/em><\/strong> 2014. 10(11), 2251-2259. doi:10.1002\/ smll.201303715. (Cover) [PDF]<\/a><\/li>\n
              14. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Tian GL, Nie JQ, Peng HJ, Wei F. Unstacked double-layer templated graphene for high-rate lithium sulphur batteries. Nature Communications<\/em><\/strong> 2014, 5, 3410 | DOI: 10.1038\/ncomms4410. [PDF]<\/a><\/li>\n
              15. Zhu WC, Wang RG, Zhu SL, Zhang LL, Cui XL, Zhang H, Piao XL, Zhang Q*<\/u><\/strong>. Green, noncorrosive, easy scale-up hydrothermal\u2013thermal conversion: A feasible solution to mass production of magnesium borate nanowhiskers. ACS Sustainable Chemistry & Engineering<\/em><\/strong> 2014, 2(4), 836-845. doi: 10.1021\/sc400481j. [PDF]<\/a><\/li>\n
              16. Zhao JW, Chen JL, Xu SM, Shao MF, Zhang Q<\/u><\/strong>, Wei F, Ma J, Wei M, Evans DG, Duan X. Hierarchical NiMn Layered Double Hydroxide\/Carbon Nanotubes Architecture with Superb Energy Density for Flexible Supercapacitors. Advanced Functional Materials<\/em><\/strong>, 2014, 24(20), 2938-2946. DOI: 10.1002\/adfm.201303638. (Cover) [PDF]<\/a><\/li>\n
              17. Huang JQ, Peng HJ, Liu XY, Nie JQ, Cheng XB, Zhang Q<\/u><\/strong>, Wei F. Flexible all-carbon interlinked nanoarchitectures as cathode scaffolds for high-rate lithium-sulfur batteries. Journal of Materials Chemistry A<\/em><\/strong> 2014, 2(28), 10869-10875. doi: 10.1039\/C4TA00245H. (Cover) [PDF]<\/a><\/li>\n
              18. Kong QQ, Gao JG, Chen CM, Zhang Q<\/u><\/strong>, Zhou GM, Tao ZC, Zhang XH, Wang MZ, Li F, Cheng HM, Cai R. Hierarchical Graphene-Carbon Fiber Composite Paper as a Flexible Lateral Heat Spreader . Advanced Functional Materials<\/em><\/strong> 2014, 24(27): 4222\u20134228. doi: 10.1002\/adfm.201304144. (Cover) [PDF]<\/a><\/li>\n
              19. Zhao MQ, Zhang Q<\/u><\/strong>, Tian GL, Wei F. Emerging double helical nanostructures. Nanoscale <\/em><\/strong>2014, 6(16), 9339-9354. doi: 10.1039\/C4NR00271G. [PDF]<\/a><\/li>\n
              20. Chu Y, Fan C, Zhang Q<\/u><\/strong>, Zan C, Ma DS, Jiang H, Wang Y, Wei F. The air oxidation of heavy oil to enhance oil recovery: The numerical model and the criteria to describe the low and high temperature oxidation. Chemical Engineering Journal <\/em><\/strong>2014, 248, 422-429. doi: 10.1016\/j.cej.2014.03.036. [PDF]<\/a><\/li>\n
              21. Cheng XB, Peng HJ, Huang JQ, Zhu L, Yang SH, Liu Y, Zhang HW, Zhu WC, Wei F, Zhang Q<\/u><\/strong>, Three-dimensional aluminum foam\/carbon nanotube scaffolds as long- and short-range electron pathways with improved sulfur loading for high energy density lithium-sulfur batteries. Journal of Power Sources<\/em><\/strong> 2014, 261, 264-270. doi: 10.1016\/j.jpowsour.2014.03.088. [PDF]<\/a><\/li>\n
              22. Zhu L, Zhu WC, Cheng XB, Huang JQ, Peng HJ, Yang SH, Zhang Q.<\/u><\/strong> Carbon Nanotubes Based Cathode Materials for High Density Lithium-sulfur Batteries. Carbon<\/em><\/strong> 2014, 75, 161-168. doi: 10.1016\/j.carbon.2014.03.049. [PDF]<\/a><\/li>\n
              23. Yu DS, Goh K, Wang H, Wei L, Jiang WC, Zhang Q<\/u><\/strong>, Dai LM, Chen Y. Scalable synthesis of hierarchically structured carbon nanotube\u2013graphene fibres for capacitive energy storage. Nature Nanotechnology<\/em><\/strong> 2014, 9(7): 555-562. DOI: 10.1038\/NNANO.2014.93. [PDF]<\/a><\/li>\n
              24. Tang C, Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Cheng XB, Tian GL, Peng HJ, Wei F. Nitrogen-doped aligned carbon nanotube\/graphene sandwiches: Facile catalytic growth on bifunctional natural catalysts and their applications as scaffolds for high-rate lithium-sulfur batteries. Advanced Materials<\/em><\/strong> 2014, 26(35), 6100-6105.
                doi:10.1002\/adma.201401243. (Cover)                 [PDF]<\/a><\/li>\n
              25. Tang C, Zhang Q<\/u><\/strong>, Zhao MQ, Tian GL, Wei F. Resilient aligned carbon nanotube\/graphene sandwiches for robust mechanical energy storage. Nano Energy<\/em><\/strong>, 2014, 7, 161-169. 10.1016\/j.nanoen.2014.05.005. [PDF]<\/a><\/li>\n
              26. Tian GL, Zhang Q<\/u><\/strong>, Zhang BS, Jin YG, Huang JQ, Su DS, Wei F. Toward Full Exposure of \u201cActive Sites\u201d: Nanocarbon Electrocatalyst with Surface Enriched Nitrogen for Superior Oxygen Reduction and Evolution Reactivity. Advanced Functional Materials<\/em><\/strong> 2014, 24(38), 5956-5961. doi:10.1002\/adfm.201401264 (Cover) [PDF]<\/a><\/li>\n
              27. Peng HJ, Hou TZ, Zhang Q<\/u><\/strong>, Huang JQ, Cheng XB, Guo MQ, Yuan Z, He LY, Wei F. Strongly Coupled Interfaces between Heterogeneous Carbon Host and Sulfur-Containing Guest for Highly-Stable Lithium-Sulfur Batteries: Mechanistic Insight into Capacity Degradation. Advanced Materials Interfaces <\/em><\/strong>2014, 1, 1400227. doi:10.1002\/adfm.201400227. (Cover) [PDF]<\/a><\/li>\n
              28. Yuan Z, Peng HJ, Huang JQ, Liu XY, Wang DW, Cheng XB, Zhang Q<\/u><\/strong>, Hierarchical free-standing carbon nanotube paper electrodes with ultrahigh sulfur loading for lithium-sulfur batteries. Advanced Functional Materials<\/em><\/strong>, 2014, 24(39), 6105-6112. doi:10.1002\/adfm.201401501. (Cover) [PDF]<\/a><\/li>\n
              29. Zhang LL, Zhu WC, Zhang H, Bi SW, Zhang Q<\/u><\/strong>, Hydrothermal-thermal conversion synthesis of hierarchical porous MgO microrods as efficient adsorbents for lead (II) and chromium (VI) removal. RSC Advances <\/em><\/strong>2014, 4(58), 30542-30550. DOI: 10.1039\/C4RA03971H. [PDF]<\/a><\/li>\n
              30. Cheng XB, Huang JQ, Peng HJ, Wei F, Zhang Q<\/u><\/strong>. Dendrite-Free Nanostructured Anode: Entrapment of Lithium in 3D Fibrous Matrix for Ultra-Stable Lithium-Sulfur Batteries. Small<\/em><\/strong> 2014, 10(21), 4257-4263. doi:10.1002\/smll.201401837. (Cover) [PDF]<\/a><\/li>\n
              31. Zhao MQ, Peng HJ, Tian GL, Zhang Q<\/u><\/strong>, Huang JQ, Cheng XB, Tang C, Wei F. Hierarchical Vine-Tree-Like Carbon Nanotube Architectures: In-Situ<\/em> CVD Self-Assembly and Their Use as Robust Scaffolds for Lithium-Sulfur Batteries. Advanced Materials<\/em><\/strong>, 2014, 26(41), 7051-7058. doi:10.1002\/ adma.201402488. (Cover) [PDF]<\/a><\/li>\n
              32. Zhang Q<\/u><\/strong>, Cheng XB, Huang JQ, Peng HJ, Wei F. Review on carbon materials for advanced lithium-sulfur batteries. New Carbon Materials<\/em><\/strong>, 2014, 29(4): 241-264. [PDF]<\/a><\/li>\n
              33. Yu DS, Goh K, Zhang Q<\/u><\/strong>, Wei L, Wang H, Jiang WC, Chen Y. Controlled Functionalization of Carbonaceous Fibers for High-Voltage Asymmetric Solid-State Micro-Supercapacitors with High Volumetric Energy Density. Advanced Materials<\/em><\/strong>, 2014, 26(39), 6790\u20136797. doi:10.1002\/adma.201403061. [PDF]<\/a><\/li>\n
              34. Zhang ZQ, Zhu WC, Wang RG, Zhang LL, Zhu L, Zhang Q<\/u><\/strong>. Ionothermal confined self-organization for hierarchical porous magnesium borate superstructures as high efficient adsorbents for dye removal. Journal of Materials Chemistry A<\/em><\/strong> 2014, 2(45), 19167-19179. 10.1039\/C4TA03580A. [PDF]<\/a><\/li>\n
              35. Peng HJ, Liang JY, Zhu L, Huang JQ, Cheng XB, Guo XF, Ding WP, Zhu WC, Zhang Q<\/u><\/strong>. Catalytic Self-Limited Assembly at Hard Templates: A Mesoscale Approach to Graphene Nanoshells for Lithium-Sulfur Batteries. ACS Nano<\/em><\/strong> 2014, 8(11), 11280-11289. doi: 10.1021\/nn503985s. [PDF]<\/a><\/li>\n<\/ol>\n

                2013<\/strong><\/p>\n

                  \n
                1. Zhang RF, Xie HH, Zhang YY, Zhang Q<\/u><\/strong>, Jin YG, Li P, Qian WZ, Wei F. The reason for the low density of horizontally aligned ultralong carbon nanotube arrays. Carbon<\/em><\/strong>, 2013, 52:232-238. [PDF]<\/a><\/li>\n
                2. Huang JQ, Liu XF, Zhang Q<\/u><\/strong>, Chen CM, Zhao MQ, Zhang SM, Zhu WC, Qian WZ, Wei F. Entrapment of sulfur in hierarchical porous graphene for lithium\u2013sulfur batteries with high rate performance from \u221240 to 60 o<\/sup>C. Nano Energy<\/em><\/strong>. 2013 2(2): 314-321. [PDF]<\/a><\/li>\n
                3. Zhang SM, Zhang Q<\/u><\/strong>, Huang JQ, Liu XF, Zhu WC, Zhao MQ, Qian WZ, Wei F. Composite Cathode Containing SWCNT@S Coaxial Nanocables: Facile Synthesis, Surface Modification, and Enhanced Performance for Li-ion Storage. Particle & Particle System Characterization<\/em><\/strong>. 2013, 30(2): 158-165. [PDF]<\/a><\/li>\n
                4. Chu Y, Zhang BS, Zhang Q<\/u><\/strong>, Wang Y, Su DS, Wei F. The use of deposited nanocarbon for characterization of zeolite supported metal catalyst Microporous and Mesoporous Materials<\/em><\/strong> 2013, 169C:201-206. [PDF]<\/a><\/li>\n
                5. Zhu WC, Zhang XY, Zhang Q<\/u><\/strong>, Xiang L, Zhu SL. Subunit contribution model for thermodynamic properties of borates and its application in hydrothermal synthesis of MgBO2<\/sub>(OH) nanowhiskers. CIESC Journal<\/em><\/strong> 2013, 64(2):443-451. [PDF]<\/a><\/li>\n
                6. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Tian GL, Chen TC, Qian WZ, Wei F. Towards high purity graphene\/single-walled carbon nanotube hybrids with improved electrochemical capacitive performance. Carbon<\/em><\/strong>. 2013, 54: 403-411. [PDF]<\/a><\/li>\n
                7. Zhu WC, Cui XL, Zhang LY, Zhang H, Piao XL, Zhang Q<\/u><\/strong>. Hydrothermal evolution, optical and electrochemical properties of hierarchical porous hematite nanoarchitectures. Nanoscale Research Letters, <\/em><\/strong>2013, 8:2. [PDF]<\/a><\/li>\n
                8. Cui Y, Zhang Q<\/u><\/strong>, He J, Wang Y, Wei F. Pore-structure-mediated hierarchical SAPO-34: Facile synthesis, tunable nanostructure, and catalysis applications for the conversion of dimethyl ether into olefins. Particuology<\/em><\/strong>. 2013, 11(4): 468-474. [PDF]<\/a><\/li>\n
                9. Zhang RF, Ning ZY, Zhang YY, Zheng QS, Chen Q, Xie HH, Zhang Q<\/u><\/strong>, Qian WZ, Wei F. Macroscale Superlubricity Observed in Centimeter Long Carbon Nanotubes in Ambient Conditions. Nature Nanotechnology<\/em><\/strong>. 2013, 8(12), 912-916. doi: 10.1038\/NNANO.2013.217. (Cover) [PDF]<\/a><\/li>\n
                10. Zhao XC, Zhang Q<\/u><\/strong>, Zhang BS, Chen CM, Xu JM, Wang AQ, Su DS, Zhang T. Decorated resol derived mesoporous carbon: highly ordered microstructure, rich boron incorporation, and excellent electrochemical capacitance. RSC Advances<\/em><\/strong> 2013, 3(11): 3578-3584. [PDF]<\/a><\/li>\n
                11. Liu XF, Zhang Q<\/u><\/strong>, Zhang SM, Huang JQ, Peng HJ, Wei F. Hierarchical nanostructured composite cathode with carbon nanotubes as conductive scaffold for lithium-sulfur batteries. Journal of Energy Chemistry<\/em><\/strong> 2013, 2(2): 341-346. [PDF]<\/a><\/li>\n
                12. Yu DS, Wei L, Jiang WC, Wang H, Su B, Zhang Q<\/u><\/strong>, Goh K, Si RM, Chen Y. Nitrogen doped holey graphene as efficient metal-free multifunctional electrochemical catalysts for hydrazine oxidation and oxygen reduction Nanoscale <\/em><\/strong>2013, 5(8), 3457\u20133464. [PDF]<\/a><\/li>\n
                13. Zhou GM, Li L, Zhang Q<\/u><\/strong>, Li N, Li F. Octahedral Co3O4 particles threaded by carbon nanotube arrays as intergrated structure anodes for lithium ion batteries. Physical Chemistry Chemical Physics <\/em><\/strong>2013, 15(15), 5582-5587. [PDF]<\/a><\/li>\n
                14. Huang JQ, Zhang Q<\/u><\/strong>, Zhang SM, Liu XF, Zhu WC, Qian WZ, Wei F. Aligned sulfur-coated carbon nanotubes with a polyethylene glycol barrier at one end for use as a high efficiency sulfur cathode. Carbon <\/em><\/strong>2013, 58, 99-106. [PDF]<\/a><\/li>\n
                15. Zhang Q<\/u><\/strong>, Huang JQ, Qian WZ, Zhang YY, Wei F. The road for nanomaterials industry: A review of carbon nanotube production, post-treatment, and bulk applications for composite and energy storage. Small<\/em><\/strong>, 2013, 9(8): 1237\u20131265. [PDF]<\/a><\/li>\n
                16. Zhang RF, Zhang YY, Zhang Q<\/u><\/strong>, Xie HH, Wang HD, Nie JQ, Wen Q, Wei F. Optical visualization of individual ultralong carbon nanotubes by chemical vapour deposition of titanium dioxide nanoparticles. Nature Communications<\/em><\/strong> 2013, 4, 1727 | DOI: 10.1038\/ ncomms2736. [PDF]<\/a><\/li>\n
                17. Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Qian WZ, Wei F. Review on Mass Production and Industrialization of Carbon Nanotubes. Science China Chemistry<\/em><\/strong>, 2013, 43(6): 641-666. [PDF]<\/a><\/li>\n
                18. Chen TC, Zhao MQ, Zhang Q<\/u><\/strong>, Tian GL, Huang JQ, Wei F. In Situ Monitoring the Role of Working Metal Catalyst Nanoparticles for Ultrahigh Purity Single-Walled Carbon Nanotubes. Advanced Functional Materials<\/em><\/strong>, 2013, 23(40): 5066-5073. (Cover) [PDF]<\/a><\/li>\n
                19. Gao G, Zhang Q<\/u><\/strong>, Wang K, Song H, Qiu PY, Cui DX, Axial compressive \u03b1-Fe2O3 microdisks prepared from CSS template for potential anode materials of lithium ion batteries. Nano Energy <\/em><\/strong>2013, 2(5): 1010-1018. doi:10.1016\/j.nanoen.2013.03.023. [PDF]<\/a><\/li>\n
                20. Zhang RF, Ning ZY, Zhang YY, Xie HH, Zhang Q<\/u><\/strong>, Qian WZ, Chen Q, Wei F. Facile Manipulation of Individual Carbon Nanotubes Assisted by Inorganic Nanoparticles. Nanoscale<\/em><\/strong> 2013, 5(14), 6584-6588. [PDF]<\/a><\/li>\n
                21. Jin YG, Zhang YY, Zhang Q<\/u><\/strong>, Zhang RF, Li P, Qian WZ, Wei F. Multiwall carbon nanotube-based carbon\/carbon composites with three-dimensional network structures Nanoscale<\/em><\/strong> 2013, 5(13), 6181-6186. [PDF]<\/a><\/li>\n
                22. Zhang W, Zhang Q<\/u><\/strong>, Zhao MQ, Kuhn LT. Direct writing on graphene \u201cpaper\u201d by manipulating electrons as \u201cinvisible ink\u201d. Nanotechnology<\/em><\/strong> 2013, 24(27): 275301. [PDF]<\/a><\/li>\n
                23. Xu CG, Ning GQ, Zhu X, Wang G, Liu XF, Gao JS, Zhang Q<\/u><\/strong>, Qian WZ, Wei F. Synthesis of graphene sheets from asphaltene molecules absorbed on vermiculite layers. Carbon<\/em><\/strong> 2013, 62, 213-221. [PDF]<\/a><\/li>\n
                24. Cheng XB, Tian GL, Liu XF, Nie JQ, Zhao MQ, Huang JQ, Zhu WC, Hu L, Zhang Q<\/u><\/strong>, Wei F. Robust growth of herringbone carbon nanofibers from layered double hydroxides and their applications as anodes for Li-ion batteries. Carbon <\/em><\/strong>2013, 62, 393-404. [PDF]<\/a><\/li>\n
                25. Zhang RF, Zhang YY, Zhang Q<\/u><\/strong>, Xie HH, Qian WZ, Wei F. Growth of half-meter long carbon nanotubes based on Schulz-Flory distribution ACS Nano. <\/em><\/strong>2013, 7(7): 6156\u20136161. [PDF]<\/a><\/li>\n
                26. Kong QQ, Chen CM, Zhang Q<\/u><\/strong>, Zhang XH, Wang MZ, Cai R. Small particles of chemically-reduced graphene with improved electrochemical capacity. Journal of Physical Chemistry C <\/em><\/strong>2013, 117(30): 15496\u201315504. [PDF]<\/a><\/li>\n
                27. Yu DS, Goh KL, Wang H, Zhang Q<\/u><\/strong>, Jiang WC, Si RM, Chen Y. Multifunctional nitrogen-rich \u201cbrick-and-mortar\u201d carbon as high performance supercapacitor electrodes and oxygen reduction electrocatalysts. Journal of Materials Chemistry A <\/em><\/strong>2013, 1(36), 11061-11069. [PDF]<\/a><\/li>\n
                28. Yun S, Qian WZ, Cui CJ, Yu YT, Zheng C, Liu Y, Zhang Q<\/u><\/strong>, Wei F. Highly selective synthesis of single-walled carbon nanotubes from methane in a coupled Downer-turbulent fluidized-bed reactor. Journal of Energy Chemistry<\/em><\/strong> 2013, 22(4): 567-572. [PDF]<\/a><\/li>\n
                29. Liu XY, Peng HJ, Huang JQ, Zhang Q<\/u><\/strong>, Wei F. Carbon nanotubes for flexible energy storage devices\u2014A review. Energy Storage Science and Technology<\/em><\/strong> 2013, 2(5):433-450. [PDF]<\/a><\/li>\n<\/ol>\n

                  2012<\/strong><\/p>\n

                    \n
                  1. Chen CM, Huang JQ, Zhang Q<\/u><\/strong>, Gong WZ, Yang QH, Wang MZ, Yang YG. Annealing a graphene oxide film to produce a free standing high conductive graphene film. Carbon<\/em><\/strong> 2012, 50(2):659-667. [PDF]<\/a><\/li>\n
                  2. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Wei F. Hierarchical nanocomposites derived from nanocarbons and layered double hydroxides – Properties, synthesis, and applications Advanced Functional Materials<\/em><\/strong> 2012, 22(4):675-694. (Invited Review) [PDF]<\/a><\/li>\n
                  3. Huang JQ, Zhao MQ, Zhang Q<\/u><\/strong>, Nie JQ, Yao LD, Su DS, Wei F. Efficient synthesis of aligned nitrogen-doped carbon nanotubes in a fluidized-bed reactor. Catalysis Today<\/em><\/strong> 2012, 186(1):83-92. [PDF]<\/a><\/li>\n
                  4. Jia XL, Zhang Q<\/u><\/strong>, Zheng C, Huang JQ, Qian WZ, Wei F. Directly dispersing agglomerated carbon nanotube powder into bismaleimide for strong composites under high pressure homogenization. Powder Technology <\/em><\/strong>2012, 217:477-481. [PDF]<\/a><\/li>\n
                  5. Huang CH, Zhang Q<\/u><\/strong>, Chou TC, Chen CM, Su DS, Doong RA. Three-dimensional hierarchically-ordered porous carbons with partially graphitic nanostructure for electrochemical capacitive energy storage. ChemSusChem <\/em><\/strong>2012, 5(3):563-571. [PDF]<\/a><\/li>\n
                  6. Zhao XC, Zhang Q<\/u><\/strong>, Zhang BS, Chen CM, Wang AQ, Zhang T, Su DS. Dual-heteroatom modified ordered mesoporous carbon: Hydrothermal functionalization, structure, and its electrochemical performance. Journal of Materials Chemistry<\/em><\/strong> 2012, 22(11): 4963-4969. [PDF]<\/a><\/li>\n
                  7. Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Wei F. A review of the large-scale production of carbon nanotubes:The practice of nanoscale process engineering. Chinese Science Bulletin<\/em><\/strong> 2012, 57 (2-3): 157-166. [PDF]<\/a><\/li>\n
                  8. Jia XL, Zhang Q<\/u><\/strong>, Zhao MQ, Xu GH, Huang JQ, Qian WZ, Lu YF, Wei F. Dramatic enhancements in toughness of polyimide nanocomposite via long-CNT-induced long-range creep. Journal of Materials Chemistry<\/em><\/strong> 2012, 22(14):7050-7056. [PDF]<\/a><\/li>\n
                  9. Jia XL, Chen Z, Suwarnasarn A, Rice L, Wang XL, Sohn H, Zhang Q<\/u><\/strong>, Wu BM, Wei F, Lu YF. High-performance flexible lithium-ion electrodes based on robust network architecture. Energy & Environmental Science<\/em><\/strong>, 2012, 5(5):6845-6849. [PDF]<\/a><\/li>\n
                  10. Zhao MQ, Tian GL, Zhang Q<\/u><\/strong>, Huang JQ, Nie JQ, Wei F. Preferential Growth of Short Aligned, Metallic-Rich Single-Walled Carbon Nanotubes from Perpendicular Layered Double Hydroxide Film. Nanoscale<\/em><\/strong>, 2012, 4(7): 2470-2477. [PDF]<\/a><\/li>\n
                  11. Liu XF, Zhu WC, Cui XL, Liu T, Zhang Q<\/u><\/strong>, Facile thermal conversion route synthesis, characterization, and optical properties of rod-like micron nickel borate. Powder Technology<\/em><\/strong>, 2012, 222: 160-166. [PDF]<\/a><\/li>\n
                  12. Chen CM, Zhang Q<\/u><\/strong>, Yang MG, Huang CH, Yang YG, Wang MZ. Structural evolution during annealing of chemically derived graphene for application in supercapacitors. Carbon<\/em><\/strong>, 2012, 50(10): 3571-3583. [PDF]<\/a><\/li>\n
                  13. Yan J, Sun W, Wei T, Zhang Q<\/u><\/strong>, Fan ZJ, Wei F. Fabrication and electrochemical performances of hierarchical porous Ni(OH)2<\/sub> nanoflakes anchored on graphene sheets. Journal of Materials Chemistry<\/em><\/strong> 2012, 22(23): 11494-11502. [PDF]<\/a><\/li>\n
                  14. Zhao MQ, Zhang Q<\/u><\/strong>, Tian GL, Huang JQ, Wei F. Space confinement and rotation stress induced self-organization of double-helix nanostructure: A nanotube twist with a moving catalyst head. ACS Nano<\/em><\/strong>, 2012, 6(5):4520-4529. [PDF]<\/a><\/li>\n
                  15. Zhu WC, Liang ZZ, Liu XF, Zhang H, Zheng YJ, Piao XL, Zhang Q<\/u><\/strong>, Soft-template self-assembly of hierarchical mesoporous SrCO3<\/sub> by low-temperature hydrothermal route and their application as adsorbents for methylene blue and heavy metal ions. Powder Technology, <\/em><\/strong>2012, 226:165-172. [PDF]<\/a><\/li>\n
                  16. Zhao XC, Zhang Q<\/u><\/strong>, Chen CM, Zhang BS, Reiche S, Wang AQ, Zhang T, Schl\u00f6gl R, Su DS. Aromatic sulfide, sulfoxide, and sulfone mediated mesoporous carbon monolith for use in supercapacitor. Nano Energy<\/em><\/strong>, 2012, 1(4): 624-630. [PDF]<\/a><\/li>\n
                  17. Chen CM, Zhang Q<\/u><\/strong>, Huang JQ, Zhang W, Huang CH, Zhao XC, Wei F, Yang YG, Wang MZ, Su DS. Chemically derived graphene\/metal oxide hybrids as electrodes for electrochemical energy storage: Pre-graphenization or post-graphenization? Journal of Materials Chemistry<\/em><\/strong>, 2012 22(28): 13947-13955. [PDF]<\/a><\/li>\n
                  18. Chen CM, Zhang Q<\/u><\/strong>, Zhao XC, Zhang BS, Blume R, Kong QQ, Yang MG, Yang QH, Wang MZ, Yang YG, Schlogl R, Su DS. Hierarchical aminated graphene based honeycombs as supercapacitor electrode. Journal of Materials Chemistry.<\/em><\/strong> 2012, 22(28): 14076-14084. [PDF]<\/a><\/li>\n
                  19. Chen CM, Zhang Q<\/u><\/strong>, Huang CH, Zhao XC, Zhang BS, Kong QQ, Wang MZ, Cai R, Su DS. Ultralight macroporous \u2018bubble\u2019 graphene film via template-directed ordered-assembly for high rate supercapacitors. Chemical Communications<\/em><\/strong>. 2012, 48(57): 7149-7151. [PDF]<\/a><\/li>\n
                  20. Chu Y, Chu BZ, Wei XB, Zhang Q<\/u><\/strong>, Wei F. An emulsion phase condensation model to describe the defluidization behavior for reactions involving gas-volume reduction. Chemical Engineering Journal<\/em><\/strong>. 2012, 198-199C: 364-370. [PDF]<\/a><\/li>\n
                  21. Yan J, Fan ZJ, Sun W, Ning GQ, Wei T, Zhang Q<\/u><\/strong>, Zhgang RF, Zhi LJ, Wei F. Advanced asymmetric supercapacitors based on Ni(OH)2<\/sub>\/ graphene and porous graphene electrodes with high energy density. Advanced Functional Materials<\/em><\/strong>. 2012, 22(12): 2632-2641. [PDF]<\/a><\/li>\n
                  22. Zheng C, Qian WZ, Cui CJ, Zhang Q<\/u><\/strong>, Jin YG, Zhao MQ, Tan PH, Wei F. Hierarchical carbon nanotube membrane with high packing density and tunable porous structure for high voltage supercapacitors. Carbon<\/em><\/strong> 2012, 50(14):5167-5175. [PDF]<\/a><\/li>\n
                  23. Tian GL, Zhao MQ, Zhang Q,<\/u><\/strong> Huang JQ, Wei F. Self-organization of nitrogen doped carbon nanotubes into double-helix structures. Carbon<\/em><\/strong>, 2012, 50(14): 5323-5330. [PDF]<\/a><\/li>\n
                  24. Liu XF, Huang JQ, Zhang Q<\/u><\/strong>, Liu XY, Peng HJ, Zhu WC, Wei F. N-methyl-2-pyrrolidone-assisted solvothermal synthesis of nanosize orthorhombic lithium iron phosphate with improved Li-storage performance. Journal of Materials Chemistry<\/em><\/strong>. 2012, 22(36), 18908-18914. [PDF]<\/a><\/li>\n
                  25. Huang JQ, Zhang Q<\/u><\/strong>, Jin Y, Wei F. sp2<\/sup> nanocarbon materials for lithium ion battery applications. Energy Storage Science and Technology<\/em><\/strong>. 2012, 1(1):1-13. [PDF]<\/a><\/li>\n
                  26. Xiao Y, Zhang Q<\/u><\/strong>, Yan J, Wei T, Fan ZJ, Wei F. Compressible aligned carbon nanotube\/MnO2<\/sub> as high-rate electrode materials for supercapacitors. Journal of Electroanalytical Chemistry <\/em><\/strong>2012, 684:32-37. [PDF]<\/a><\/li>\n
                  27. Zhao MQ, Liu XF, Zhang Q<\/u><\/strong>, Tian GL, Huang JQ, Zhu WC, Wei F. Graphene\/single-walled carbon nanotube hybrids: One-step catalytic growth and applications for high-rate Li-S batteries. ACS Nano<\/em><\/strong> 2012, 6(12): 10759\u201310769. [PDF]<\/a><\/li>\n<\/ol>\n

                    2011<\/strong><\/p>\n

                      \n
                    1. Zhu WC, Zhang Q<\/u><\/strong>, Xiang L, Zhu, SL. Green coprecipitation byproduct assisted thermal conversion route to submicron Mg2<\/sub>B2<\/sub>O5<\/sub> whiskers. CrystEngComm<\/em><\/strong> 2011, 13(5):1654-1663. [PDF]<\/a><\/li>\n
                    2. Lv RT, Cui TX, Jun MS, Zhang Q<\/u><\/strong>, Cao AY, Su DS, Zhang ZJ, Yoon SH, Miyawaki J, Mochida I, Kang FY. Open-Ended, N-doped carbon nanotube-graphene hybrid nanosctructure using as support material for fuel cell catalyst. Advanced Functional Materials <\/em><\/strong>2011, 21(5): 999-1006. [PDF]<\/a><\/li>\n
                    3. Rinaldi A, Tessonnier JP, Schuster ME, Blume R, Girgsdies F, Zhang Q<\/u><\/strong>, Jacob T, Abd-Hamid SB, Su DS, Schl\u00f6gl R. Dissolved carbon controls the initial stage of nanocarbon growth. Angewandte Chemie International Edition <\/em><\/strong>2011, 50(14): 3313-3317. [PDF]<\/a><\/li>\n
                    4. Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Zhou K, Wei F. Very fast growth of millimeter-tall aligned carbon nanotubes between two stacked substrates coated with a metal catalyst. Carbon<\/em><\/strong> 2011, 49(4):1395-1400. [PDF]<\/a><\/li>\n
                    5. Nie JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Wen Q, Cui Y, Qian WZ, Wei F. Synthesis of high quality single-walled carbon nanotubes on natural sepiolite and their use for phenol absorption. Carbon<\/em><\/strong> 2011, 49(5):1568-1580. [PDF]<\/a><\/li>\n
                    6. Zhu WC, Cui XL, Zhang LY, Zhang Q<\/u><\/strong>. Monodisperse porous pod-like hematite: Hydrothermal formation, optical absorbance, and magnetic properties. Materials Letters<\/em><\/strong>. 2011,65(6):1003- 1006. [PDF]<\/a><\/li>\n
                    7. Zhao MQ, Huang JQ, Zhang Q<\/u><\/strong>, Nie JQ, Wei F. Stretchable single-walled-carbon-nanotube- array double helices derived from molybdenum containing layered double hydroxides. Carbon<\/em><\/strong> 2011, 49(6):2148-2152. [PDF]<\/a><\/li>\n
                    8. Zhu WC, Zhang Q<\/u><\/strong>, Hu L, Xiang L, Zhu SL. Repair the pores and preserve the morphology: Formation of high crystallinity 1D nanostructures via the thermal conversion route Crystal Growth and Design <\/em><\/strong>2011, 11(3):709-718. [PDF]<\/a><\/li>\n
                    9. Xu GH, Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Wei F. Fabrication of double- and multi-walled carbon nanotube transparent conductive films by filtration-transfer process and their property improvement by acid treatment. Applied Physics A<\/em><\/strong> 2011, 103(2): 403\u2013411. [PDF]<\/a><\/li>\n
                    10. Zhao MQ, Huang JQ, Zhang Q<\/u><\/strong>, Luo WL, Wei F. Sponge-like hybrids of aligned carbon nanotube array intercalated natural vermiculite for oil absorption Applied Clay Science<\/em><\/strong> 2011, 53(1):1-7. [PDF]<\/a><\/li>\n
                    11. Zhu WC, Wang XL, Zhang X, Zhang H, Zhang Q<\/u><\/strong>. Hierarchical laminar superstructures of rhombic priceite (Ca4<\/sub>B10<\/sub>O19<\/sub>\u00b77H2<\/sub>O): Facile hydrothermal synthesis, shape evolution, optical and thermal decomposition properties. Crystal Growth & Design<\/em><\/strong> 2011, 11(7):2935-2941. [PDF]<\/a><\/li>\n
                    12. Xu GH, Zheng C, Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Nie JQ, Wang XH, Wei F. Binder-free activated carbon\/carbon nanotube paper electrodes for use in supercapacitors. Nano Research<\/em><\/strong> 2011, 4(9):870-881. [PDF]<\/a><\/li>\n
                    13. Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Qian WZ, Wei F. Carbon nanotube mass production: Principles and processes. ChemSusChem<\/em><\/strong> 2011, 4(7): 864-889. (Invited Review) [PDF]<\/a><\/li>\n
                    14. Zhang RF, Wen Q, Qian WZ, Su DS, Zhang Q<\/u><\/strong>, Wei F. Superstrong Ultra long Carbon Nanotubes for Mechanical Energy Storage. Advanced Materials <\/em><\/strong>2011, 23(30): 3387-3391. [PDF]<\/a>
                      Nanowerk<\/em><\/strong>:                       http:\/\/www.nanowerk.com\/news\/newsid=23074.php<\/a>
                      NPG Asia Materials<\/em><\/strong>:                       http:\/\/www.nature.com\/am\/journal\/2011\/201110\/full\/am2011174a.html<\/a><\/li>\n
                    15. Zhu WC, Zhang X, Wang XL, Zhang H, Zhang Q<\/u><\/strong>, Xiang L. Short belt-like Ca2<\/sub>B2<\/sub>O5<\/sub>\u2022H2<\/sub>O nanostructures: Hydrothermal formation, FT-IR, thermal decomposition, and optical properties. Journal of Crystal Growth<\/em><\/strong> 2011, 332(1):81-86. [PDF]<\/a><\/li>\n
                    16. Jia XL, Yan CZ, Chen Z, Wang RR, Zhang Q,<\/u><\/strong> Guo L, Wei F, Lu YF. Direct growth of flexible LiMn2<\/sub>O4<\/sub>\/CNTs lithium-ion cathodes. Chemical Communications<\/em><\/strong>, 2011, 47(34):9669-9671. [PDF]<\/a><\/li>\n
                    17. Zhang BS, Ni XJ, Zhang W, Shao LD, Zhang Q<\/u><\/strong>, Girgsdies F, Liang CH, Schlogl R, Su DS. Structural rearrangements of Ru nanoparticles supported on carbon nanotubes under microwave irradiation. Chemical Communications<\/em><\/strong>. 2011, 47(38):10716-10718. [PDF]<\/a><\/li>\n
                    18. Zhu WC, Zhang LY, Cui XL, Zhang Q<\/u><\/strong>. Efficient synthesis of one-dimensional orthorhombic lithium borate hydroxide rods and their thermal conversion to lithium borates. Powder Technology<\/em><\/strong>. 2011, 210(1): 67-72. [PDF]<\/a><\/li>\n<\/ol>\n

                      2010<\/strong><\/p>\n

                        \n
                      1. Zhao MQ, Zhang Q<\/u><\/strong>, Jia XL, Huang JQ, Zhang YH, Wei F. Hierarchical composites of single\/double walled carbon nanotubes interlinked flakes from directly carbon deposition on layered double hydroxides. Advanced Functional Materials<\/em><\/strong> 2010, 20(4):677-685. (Featured on cover)<\/strong> [PDF]<\/a><\/li>\n
                      2. Highten by Chinese Science Bulletin<\/em><\/strong> 2010, 55(12): 1194.<\/li>\n
                      3. Zhang Q<\/u><\/strong>, Zhao MQ, Tang DM, Li F, Huang JQ, Liu BL, Zhu WC, Zhang YH, Wei F. Carbon\u2013nanotube-array double helices. Angewandte Chemie International Edition<\/em><\/strong>. 2010, 49(21):3642-3645; Angewandte Chemie<\/em><\/strong> 2010, 122(21):3724-3727. [PDF]<\/a><\/li>\n
                      4. Su DS. Inorganic materials with double-helix structures. Angewandte Chemie International Edition <\/em><\/strong>2011, 50(21):4747\u20134750. [PDF]<\/a><\/li>\n
                      5. Fan ZJ, Yan J, Zhi LJ, Zhang Q<\/u><\/strong>, Wei T, Feng J, Zhang ML, Qian WZ, Wei F. Three-dimensional carbon nanotube\/graphene sandwich and its application as electrode in supercapacitors. Advanced Materials <\/em><\/strong>2010, 22(33):3723\u20133728. [PDF]<\/a><\/li>\n
                      6. Wen Q, Qian WZ, Nie JQ, Cao AY, Ning GQ, Wang Y, Hu L, Zhang Q<\/u><\/strong>, Huang JQ, Wei F. 100 mm long, semiconducting, triple-walled carbon nanotubes. Advanced Materials<\/em><\/strong> 2010, 22(16):1867-1871. (Featured on cover)<\/strong> [PDF]<\/a><\/li>\n
                      7. Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Nie JQ, Wei F. Mass production of aligned carbon nanotube arrays by fluidized bed catalytic chemical vapor deposition. Carbon<\/em><\/strong> 2010, 48(4):1196-1209. [PDF]<\/a><\/li>\n
                      8. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Wei F. Large scale intercalated growth of short aligned carbon nanotubes among vermiculite layers in a fluidized bed reactor. Journal of Physics and Chemistry of Solids<\/em><\/strong> 2010, 71(4):624-626. [PDF]<\/a><\/li>\n
                      9. Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Wei F. Comparison of vertically aligned carbon nanotube array intercalated production among vermiculites in fixed and fluidized bed reactors. Powder Technology<\/em><\/strong>. 2010, 198(2):285-291. [PDF]<\/a><\/li>\n
                      10. Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Wei F. The release of free standing vertically-aligned carbon nanotube arrays from a substrate using CO2<\/sub> oxidation. Carbon<\/em><\/strong> 2010, 48(5):1441-1450. [PDF]<\/a><\/li>\n
                      11. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Nie JQ, Wei F. Advanced materials from natural resources : Facile synthesis aligned carbon nanotubes on wollastonites ChemSusChem<\/em><\/strong> 2010,3(4):453-459. [PDF]<\/a><\/li>\n
                      12. Zhang Q<\/u><\/strong>, Wang DG, Huang JQ, Zhou WP, Luo GH, Qian WZ, Wei F. Dry spinning yarns from vertically aligned carbon nanotube arrays produced by an improved floating catalyst chemical vapor deposition method. Carbon<\/em><\/strong> 2010, 48(10):2855-2861. [PDF]<\/a><\/li>\n
                      13. Xu GH, Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Zhou WP, Wei F. A two-step shearing strategy to disperse long carbon nanotubes from vertically aligned carbon nanotube arrays for transparent conductive films Langmuir<\/em><\/strong> 2010, 26(4):2798-2804. [PDF]<\/a><\/li>\n
                      14. Zhu WC, Zhang GL, Li J, Zhang Q<\/u><\/strong>, Piao XL, Zhu SL. Mesoporous SrCO3<\/sub> hierachical submicron spheres derived from reaction-limited aggregation induced \u201crod-to-dumbbell-to-sphere\u201d self-orgniazation. CrystEngComm <\/em><\/strong>2010,12(6):1795-1802. [PDF]<\/a><\/li>\n
                      15. Zhang Q<\/u><\/strong>, Zuo YZ, Han MH, Wang JF, Jin Y, Wei F. Long carbon nanotubes intercrossed Cu\/Zn\/Al\/Zr catalyst for CO\/CO2<\/sub> hydrogenation to methanol\/dimethyl ether. Catalysis Today<\/em><\/strong> 2010, 150(1-2):55-60. [PDF]<\/a><\/li>\n
                      16. Shu Q, Nawaz Z, Gao JX, Liao YH, Zhang Q<\/u><\/strong>, Wang DZ, Wang JF. Synthesis of biodiesel from waste oil feedstocks using the carbon-based solid acid catalyst: Reaction and separation. Bioresource Technology<\/em><\/strong> 2010, 101(14): 374-5384. [PDF]<\/a><\/li>\n
                      17. Zuo YZ, Zhang Q<\/u><\/strong>, An X, Han MH, Wang TF, Wang JF, Jin Y. One-step dimethyl ether synthesis on a Cu\/ZnO\/Al2<\/sub>O3<\/sub>\/ZrO2<\/sub>+\u03b3-Al2<\/sub>O3<\/sub> bifunctional catalyst in a slurry reactor. Journal of Fuel Chemistry and Technology<\/em><\/strong> 2010, 38(1):102-107. [PDF]<\/a><\/li>\n
                      18. Zhao MQ, Zhang Q<\/u><\/strong>, Huang JQ, Nie JQ, Wei F. Layered double hydroxides as catalysts for the efficient growth of high quality single walled carbon nanotubes in a fluidized bed reactor. Carbon <\/em><\/strong>2010, 48(11):3260-3270. [PDF]<\/a><\/li>\n
                      19. Zhu WC, Li GD, Zhang Q<\/u><\/strong>, Xiang L, Zhu SL. Hydrothermal mass production of MgBO2<\/sub>(OH) nanowhiskers and subsequent thermal conversion to Mg2<\/sub>B2<\/sub>O5<\/sub> nanowhiskers for biaxially oriented polypropylene resins reinforcement. Powder Technology<\/em><\/strong> 2010, 203(2):265-271. [PDF]<\/a><\/li>\n
                      20. Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Xu GH, Wei F. Patterning of hydrophobic three-dimensional carbon nanotube architectures by a pattern transfer approach. Nanoscale <\/em><\/strong>2010, 2(8):1401-1404. (Featured on cover)<\/strong> [PDF]<\/a><\/li>\n
                      21. Zhou K, Huang JQ, Zhang Q<\/u><\/strong>, Wei F. Multi-directional growth of aligned carbon nanotubes over catalyst film prepared by atomic layer deposition. Nanoscale Research Letters. <\/em><\/strong>2010, 5(10): 1555-1560. [PDF]<\/a><\/li>\n
                      22. Yang Z, Zhang Q<\/u><\/strong>, Luo GH, Xiang R, Qian WZ, Wang Y, Wei F. Super long vertically aligned carbon nanotube arrays. New Carbon Materials<\/em><\/strong> 2010,25(3):168-174. [PDF]<\/a><\/li>\n
                      23. Zhu WC, Zhang GL, Liu CM, Zhang Q<\/u><\/strong>, Piao XL, Zhu SL. Hierarchical strontium carbonate submicron spheres self-assembled under hydrothermal conditions. Crystal Research and Technology<\/em><\/strong> 2010, 45(8):845-850. [PDF]<\/a><\/li>\n
                      24. Yang Z, Zhang Q<\/u><\/strong>, Luo GH, Huang JQ, Zhao MQ, Wei F. Coupled process of plastics pyrolysis and chemical vapor deposition for controllable synthesis of vertically aligned carbon nanotube arrays. Applied Physics A <\/em><\/strong>2010, 100(2):533-540. [PDF]<\/a><\/li>\n
                      25. Fan ZJ, Yan J, Ning GQ, Wei T, Qian WZ, Zhang SJ, Zheng C, Zhang Q<\/u><\/strong>, Wei F. Oil sorption and recovery by using vertically aligned carbon nanotubes. Carbon <\/em><\/strong>2010, 48(14):4197-4200. [PDF]<\/a><\/li>\n
                      26. Ma YJ, Yao XF, Zheng QS, Yin YJ, Xu GH, Wei F, Zhang Q<\/u><\/strong>. Carbon nanotube films change Poisson\u2019s ratios from negative to positive. Applied Physics Letters<\/em><\/strong>. 2010,97(6): 061909-1-3. [PDF]<\/a><\/li>\n
                      27. Zhang Q<\/u><\/strong>. The development and prospects of carbon science \u2013 A report on the annual world conference on carbon, Carbon’10. New Carbon Materials<\/em><\/strong>. 2010, 25(5):395-399. [PDF]<\/a><\/li>\n
                      28. Zhao MQ, Zhang Q<\/u><\/strong>, Zhang W, Huang JQ, Zhang YH, SU DS, Wei F. Embedded high density metal nanoparticles with extraordinary thermal stability derived from guest-host mediated layered double hydroxides. Journal of the American Chemical Society<\/em><\/strong> 2010, 132(42): 14739\u201314741. [PDF]<\/a><\/li>\n
                      29. Yu DS#<\/sup>, Zhang Q<\/u><\/strong>#<\/sup>, Dai LM. Highly-efficient metal-free growth of nitrogen-doped single-walled carbon nanotubes on plasma-etched substrates for oxygen reduction. Journal of the American Chemical Society<\/em><\/strong> 2010, 132(43):15127-15129. (# <\/sup>equal contribution) [PDF]<\/a><\/li>\n<\/ol>\n

                        2009<\/strong><\/p>\n

                          \n
                        1. Zhang Q<\/u><\/strong>, Zhao MQ, Liu Y, Cao AY, Qian WZ, Lu YF, Wei F, Energy-absorbing hybrid composites based on alternate carbon nanotube and inorganic layers. Advanced Materials<\/em><\/strong> 2009, 21(28):2876-2880. [PDF]<\/a><\/li>\n
                        2. Nie JQ, Qian WZ, Zhang Q<\/u><\/strong>, Wen Q, Wei F. Very high quality single walled carbon nanotubes grown using a structured and tunable porous Fe\/MgO catalyst. Journal of Physics Chemistry C<\/em><\/strong> 2009, 113(47): 20178\u201320183. [PDF]<\/a><\/li>\n
                        3. Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Qian WZ, Wei F. Modulating the diameter of carbon nanotubes in array form via floating catalyst chemical vapor deposition. Applied Physics A<\/em><\/strong> 2009, 94(4): 853-860. [PDF]<\/a><\/li>\n
                        4. Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Liu Y, Wang Y, Qian WZ, Wei F. Vertically aligned carbon nanotube arrays grown on a lamellar catalyst by fluidized bed catalytic chemical vapor deposition. Carbon<\/em><\/strong> 2009, 47(11):2600-2610. [PDF]<\/a><\/li>\n
                        5. Liu Y, Qian WZ, Zhang Q<\/u><\/strong>, Ning GQ, Luo GH, Wang Y, Wang DZ, Wei F. Synthesis of high-quality double-walled carbon nanotubes in fluidized bed reactor. Chemical Engineering & Technology<\/em><\/strong> 2009, 32(1):73-79. [PDF]<\/a><\/li>\n
                        6. Xiang R, Luo GH, Yang Z, Zhang Q<\/u><\/strong>, Qian WZ, Wei F. Large area growth of aligned CNT arrays on spheres: Cost performance and product control. Materials Letters<\/em><\/strong> 2009, 63(1): 84-87. [PDF]<\/a><\/li>\n
                        7. Huang JQ, Zhang Q<\/u><\/strong>, Zhao MQ, Wei F. Process intensification by CO2<\/sub> for high quality carbon nanotube forest growth: Double walled carbon nanotube convexity or single walled carbon nanotube bowl? Nano Research<\/em><\/strong> 2009, 2(11):872-881. [PDF]<\/a><\/li>\n
                        8. Zhang Q<\/u><\/strong>, Xu GH, Huang JQ, Zhou WP, Zhao MQ, Wang Y, Qian WZ, Wei F. Fluffy carbon nanotubes produced by shearing vertically aligned carbon nanotube arrays. Carbon<\/em><\/strong> 2009, 47(2): 538-541. [PDF]<\/a><\/li>\n
                        9. Shu Q, Zhang Q<\/u><\/strong>, Gao JX, Wang JF. Advances in carbon-based solid acid for catalytic preparation of biodisel. Modern Chemical Industry<\/em><\/strong> 2009, 29(8):21-25. [PDF]<\/a><\/li>\n
                        10. Shu Q, Zhang Q<\/u><\/strong>, Xu GH, Nawas Z, Wang DZ, Wang JF. Synthesis of biodiesel from cottonseed oil and methanol using a carbon-based solid acid catalyst. Fuel Processing Technology<\/em><\/strong> 2009, 90(7-8):1001-1007. [PDF]<\/a><\/li>\n
                        11. Shu Q, Zhang Q<\/u><\/strong>, Xu GH, Wang JF. Preparation of biodiesel using s-MWCNT catalysts and the coupling of reaction and separation. Food and Byproducts Processing<\/em><\/strong>. 2009, 87(3): 164-170. [PDF]<\/a><\/li>\n
                        12. An X, Zuo YZ, Zhang Q<\/u><\/strong>, Wang JF. Methanol synthesis from CO2<\/sub> hydrogenation with a Cu\/Zn\/Al\/Zr fibrous catalyst. Chinese Journal of Chemical Engineering<\/em><\/strong> 2009, 17(1):88-94. [PDF]<\/a><\/li>\n
                        13. Nawaz Z, Tang XP, Zhang Q<\/u><\/strong>, Wang DZ, Wei F. SAPO-34 supported Pt\u2013Sn-based novel catalyst for propane dehydrogenation to propylene. Catalysis Communications<\/em><\/strong> 2009, 10(14): 1925-1930. [PDF]<\/a><\/li>\n
                        14. Zuo YZ, Zhang Q<\/u><\/strong>, Han MH, Wang JF, Wang TF, Wang DZ, Jin Y. The sintering of a Cu-based methanol synthesis catalyst Chinese Journal of Catalysis<\/em><\/strong> 2009, 30(7):624-630. [PDF]<\/a><\/li>\n
                        15. Zhang Q<\/u><\/strong>, Huang C, Jiang D, Wei XB, Qian Z, Wei F. Particle measurement sensor for in situ determination of phase structure of fluidized bed. Particuology<\/em><\/strong> 2009, 7(3): 175-182. [PDF]<\/a><\/li>\n
                        16. Huang JQ, Zhang Q<\/u><\/strong>, Wei F. Coiled carbon nanotubes. Progress in Chemistry<\/em><\/strong> 2009, 21(4): 637-643. (Review)<\/strong> [PDF]<\/a><\/li>\n<\/ol>\n

                          2008<\/strong><\/p>\n

                            \n
                          1. Zhang Q<\/u><\/strong>, Huang JQ, Zhao MQ, Wang Y, Qian WZ, Wei F. Radial growth of vertically aligned carbon nanotube arrays from ethylene on ceramic spheres. Carbon<\/em><\/strong> 2008, 46(8): 1152-1158. (Featured on cover)<\/strong> [PDF]<\/a><\/li>\n
                          2. Zhang Q<\/u><\/strong>, Zhao MQ, Huang JQ, Qian WZ, Wei F. Selective synthesis of single\/ double\/multi-walled carbon nanotubes on MgO supported Fe catalyst. Chinese Journal of Catalysis<\/em><\/strong> 2008, 29 (11): 1138-1144. [PDF]<\/a><\/li>\n
                          3. Zhang Q<\/u><\/strong>, Liu Y, Hu L, Qian WZ, Luo GH, Wei F. Synthesis of thin-walled carbon nanotubes from methane by tailoring the Ni\/Mo ratio of Ni\/Mo\/MgO catalyst. New Carbon Materials<\/em><\/strong> 2008, 23(4): 319-325. [PDF]<\/a><\/li>\n
                          4. Liu Y, Qian WZ, Zhang Q<\/u><\/strong>, Ning GQ, Wen Q, Luo GH, Wei F. The confined growth of double-walled carbon nanotubes in porous catalysts by chemical vapor deposition.<\/a> Carbon<\/em><\/strong> 2008, 46(14): 1860-1868. [PDF]<\/a><\/li>\n
                          5. Zhang Q<\/u><\/strong>, Liu Y, Huang JQ, Qian WZ, Wang Y, Wei F. Synthesis of single walled carbon nanotubes from liquefied petroleum gas. Nano<\/em><\/strong> 2008, 3(2): 95-100. [PDF]<\/a><\/li>\n
                          6. Zhang Q<\/u><\/strong>, Yu H, Liu Y, Qian WZ, Wang Y, Luo GH, Wei F. Few walled carbon nanotube production in large-scale by nano-agglomerate fluidized-bed process. Nano<\/em><\/strong> 2008, 3(1): 45-50. [PDF]<\/a><\/li>\n
                          7. Zhang Q<\/u><\/strong>, Qian WZ, Xiang R, Yang Z, Luo GH, Wang Y, Wei F. In situ<\/em> growth of carbon nanotubes on inorganic fibers with different surface properties. Materials Chemistry and Physics<\/em><\/strong> 2008, 107(2-3): 317-321. [PDF]<\/a><\/li>\n
                          8. Qian WZ, Tian T, Guo C, Wen Q, Li K, Zhang H, Shi H, Wang D, Liu Y, Zhang Q<\/u><\/strong>, Zhang YX, Wei F, Wang ZW, Li XD, Li YD. Enhanced activation and decomposition of CH4<\/sub> by the addiation of C2<\/sub>H4<\/sub> or C2<\/sub>H2<\/sub> for hydrogen and carbon nanotube production. Journal of Physical Chemistry C<\/em><\/strong> 2008, 112(20): 7588-7593. [PDF]<\/a><\/li>\n
                          9. Huang JQ, Zhang Q<\/u><\/strong>, Wei F, Qian WZ, Wang DZ, Hu L. Liquefied petroleum gas containing sulfur as the carbon source for carbon nanotube forests. Carbon <\/em><\/strong>2008, 45(2): 291-296. [PDF]<\/a><\/li>\n
                          10. Zhang Q<\/u><\/strong>, Yu H, Huang JQ, Hu L, Qian WZ, Wang DZ, Wei F. Carbon nanofiber microspheres obtained from ethylene using FeCl3<\/sub> as the catalyst precursor. Materials Letters<\/em><\/strong> 2008, 62 (17-18): 3149-3151. [PDF]<\/a><\/li>\n
                          11. Xiang R, Yang Z, Zhang Q<\/u><\/strong>, Luo G, Qian WZ, Wei F, Kadowaki M, Einarsson E, Maruyama S. Growth deceleration of vertically aligned carbon nanotube arrays: Catalyst deactivation or feedstock diffusion controlled? Journal of Physical Chemistry C<\/em><\/strong> 2008, 112(13): 4892-4896. [PDF]<\/a><\/li>\n
                          12. Xu GH, Zhang Q<\/u><\/strong>, Zhou WP, Huang JQ, Wei F. The feasibility of producing MWCNT paper and strong MWCNT film from VACNT array. Applied Physics A<\/em><\/strong> 2008, 92(3): 531-539. [PDF]<\/a><\/li>\n
                          13. Liu Y, Qian WZ, Zhang Q<\/u><\/strong>, Cao AY, Li ZF, Zhou WP, Ma Y, Wei F. Hierarchical agglomerates of carbon nanotubes as high-pressure cushions. Nano Letters<\/em><\/strong> 2008, 8(5): 1323-1327. [PDF]<\/a><\/li>\n
                          14. Huang JQ, Zhang Q<\/u><\/strong>, Xu GH, Qian WZ, Wei F. Substrate morphology induced self-organization into carbon nanotube arrays, ropes, and agglomerates. Nanotechnology<\/em><\/strong> 2008, 19(43): 43560. [PDF]<\/a><\/li>\n
                          15. Zhu WC, Zhang Q<\/u><\/strong>, Xiang L, Wei F, Sun X, Piao X, Zhu SL. Flux-assisted thermal conversion route to pore-free high crystallinity magnesium borate nanowhiskers at a relatively low temperature. Crystal<\/em><\/strong> Growth and Design<\/em><\/strong> 2008, 8(8): 2938-2945. [PDF]<\/a><\/li>\n
                          16. Zhu WC, Xiang L, Zhang Q<\/u><\/strong>, Zhang XY, Hu L, Zhu SL. Morphology preservation and crystallinity improvement in the thermal conversion of the hydrothermal synthesized MgBO2<\/sub>(OH) nanowhiskers to Mg2<\/sub>B2<\/sub>O5<\/sub> nanowhiskers. Journal of Crystal Growth<\/em><\/strong>. 2008, 310(18): 4262-4267. [PDF]<\/a><\/li>\n
                          17. An X, Zuo YZ, Zhang Q<\/u><\/strong>, Wang DZ, Wang JF. Dimethyl ether synthesis from CO2<\/sub> hydrogenation on a CuO-ZnO-Al2<\/sub>O3<\/sub>-ZrO2<\/sub>\/HZSM-5 bifunctional catalyst. Industrial & Engineering Chemistry Research<\/em><\/strong> 2008, 47(17): 6547-6554. [PDF]<\/a><\/li>\n
                          18. Chen YJ, Zhou HQ, Zhu J, Zhang Q<\/u><\/strong>, Wang Y, Wang DZ, Wei F. Direct synthesis of a fluidizable SAPO-34 catalyst for a fluidized dimethyl ether-to-olefins process. Catalysis Letters<\/em><\/strong> 2008, 124(3-4):297-303. [PDF]<\/a><\/li>\n
                          19. Liu F, Wei F, Li GL, Cheng Y, Wang L, Luo GH, Li Q, Qian Z, Zhang Q<\/u><\/strong>, Jin Y. Study on the FCC process of a novel riser-downer coupling reactor (III): Industrial trial and CFD modeling. Industrial & Engineering Chemistry Research<\/em><\/strong> 2008, 47(22):8582-8587. [PDF]<\/a><\/li>\n
                          20. Wei F, Zhang Q<\/u><\/strong>, Qian WZ, Yu H, Wang Y, Luo GH, Xu GH, Wang DZ. The mass production of carbon nanotubes using a nano-agglomerate fluidized bed reactor: a multiscale space-time analysis Powder Technology <\/em><\/strong>2008, 183(1): 10-20. (Review)<\/strong> [PDF]<\/a><\/li>\n<\/ol>\n

                            2007<\/strong><\/p>\n

                              \n
                            1. Zhang Q<\/u><\/strong>, Zhou WP, Qian WZ, Xiang R, Huang JQ, Wang DZ, Wei F. Synchronous growth of vertically aligned carbon nanotubes with pristine stress in the heterogeneous catalysis process. Journal of Physical Chemistry C<\/em><\/strong> 2007, 111(40): 14638-14643. [PDF]<\/a><\/li>\n
                            2. Xiang R, Luo GH, Qian WZ, Zhang Q<\/u><\/strong>, Wang Y, Wei F, Li Q, Cao AY. Encapsulation, compensation, and substitution of catalyst particles during continuous growth of carbon nanotubes Advanced Materials<\/em><\/strong> 2007, 19(17): 2360-2363. [PDF]<\/a><\/li>\n
                            3. Zhang Q,<\/u><\/strong> Qian WZ Wen Q, Liu Y, Wang DZ, Wei F. The effect of phase separation in Fe\/Mg\/Al\/O catalysts on the synthesis of DWCNTs from methane. Carbon<\/em><\/strong> 2007, 45(8): 1645-1650. [PDF]<\/a><\/li>\n
                            4. Zhang Q<\/u><\/strong>, Qian WZ, Yu H, Wei F, Wen Q. Synthesis of carbon nanotubes with totally hollow channel and\/or with totally filled copper nanowires. Applied Physics A<\/em><\/strong> 2007, 86(2): 265-269. [PDF]<\/a><\/li>\n
                            5. Zhang Q<\/u><\/strong>, Huang JQ, Wei F, Xu GH, Wang Y, Qian WZ, Wang DZ. Large scale production of carbon nanotube arrays on the sphere surface from liquefied petroleum gas at low cost. Chinese Science Bulletin<\/em><\/strong> 2007, 52(21): 2896-2902. (Featured on cover)<\/strong> [PDF]<\/a><\/li>\n
                            6. Wen Q, Qian WZ, Wei F, Liu Y, Ning GQ, Zhang Q<\/u><\/strong>. CO2<\/sub>-assisted SWNT growth on porous catalysts. Chemistry of Materials<\/em><\/strong> 2007, 19(6): 1226-1230. [PDF]<\/a><\/li>\n
                            7. Xiang R, Luo GH, Yang Z, Zhang Q<\/u><\/strong>, Qian WZ, Wei F. Temperature effect on substrate selectivity of carbon nanotube growth in a floating catalysis process. Nanotechnology<\/em><\/strong> 2007, 18(41): 415703. [PDF]<\/a><\/li>\n
                            8. Zhou WP, Li ZF, Zhang Q<\/u><\/strong>, Liu YP, Wei F, Luo GH. Gas flow-assisted alignment of super long electrospun nanofibers. Journal of Nanoscience and Nanotechnology<\/em><\/strong> 2007, 7(8): 2667-2673. [PDF]<\/a><\/li>\n
                            9. An X, Li JL, Zuo YZ, Zhang<\/u><\/strong> Q<\/u><\/strong>, Wang DZ, Wang JF. A Cu\/Zn\/Al\/Zr fibrous catalyst that is an improved CO2<\/sub> hydrogenation to methanol catalyst. Catalysis Letters<\/em><\/strong> 2007, 118 (3-4): 264-269. [PDF]<\/a><\/li>\n
                            10. Wei F, Zhang Q<\/u><\/strong>, Qian WZ, Xu GH, Xiang R, Wen Q, Wang Y, Luo GH. Progress on aligned carbon nanotube array. New Carbon Materials<\/em><\/strong> 2007, 22(3): 271-282. (Review)<\/strong> [PDF]<\/a><\/li>\n<\/ol>\n

                              2006<\/strong><\/p>\n

                                \n
                              1. Yu H, Zhang Q<\/u><\/strong>, Zhang QF, Wang QX, Ning GQ, Luo GH, Wei F. Effect of the reaction atmosphere on the diameter of single-walled carbon nanotubes produced by chemical vapor deposition. Carbon<\/em><\/strong> 2006, 44(9): 1706-1712. [PDF]<\/a><\/li>\n
                              2. Qian WZ, Chen L, Zhang Q<\/u><\/strong>, Wei F, Ling C, Wang ZW. Preparation of nanosized iron catalyst and small diameter carbon nanotubes from methane decomposition. (In Chinese) The Chinese Journal of Process Engineering<\/em><\/strong> 2006, 6(Suppl.2): 294-297. [PDF]<\/a><\/li>\n<\/ol>\n\n\n

                                <\/p>\n\n\n\n

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                                2020 Zhao CZ, Zhao BC, Yan C, Zhang XQ, Huang JQ, Mo Y, Xu X, Li H, Zhang Q. Liquid Phase Therapy to Solid Electrolyte\u2013Electrode Interface in Solid-State Li Metal Batteries: A Review. Energy Storage Materials 2020, 24, 75, doi:10.1016\/j.ensm.2019.07.026.[PDF] Zhang XQ, Li T, Li BQ, Zhang R, Shi P, Yan C, Huang JQ, Zhang […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-99","page","type-page","status-publish","hentry"],"aioseo_notices":[],"_links":{"self":[{"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/pages\/99","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/comments?post=99"}],"version-history":[{"count":133,"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/pages\/99\/revisions"}],"predecessor-version":[{"id":2694,"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/pages\/99\/revisions\/2694"}],"wp:attachment":[{"href":"https:\/\/www.qianggroup.com\/wp\/en\/wp-json\/wp\/v2\/media?parent=99"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}