NB: For more info, such as possible full text of the publications, please visit Wancheng ZHU's ResearcherID:  http://www.researcherid.com/rid/D-5697-2017

一、SCI论文【58】

1、通讯/第一作者论文 ~【53】

[61] Huang, Y.G.; Wang, C.; Wang, F.; Wang, Y.M.; Zhang, L.Y.; Zhang, H.; Xiang, L.*; Zhu, W.C.*. Titanium-bearing blast furnace slags derived porous Mg-Al layered double hydroxides (LDHs) nanospheres as superior adsorbents for organic dyes removal. 2024, In preparation.

[60] Wang, Y.M.; Su, Y.B.; Zhang, X.Y.; Huang, Y.G.; Zhang, L.Y.; Yang, Z.Y.; Liu, Y.; Xu, Y.J.; Chen, H.S.; Liu, Z.Y.*; Zhu, W.C.*. Manganese-titanium based composite lithium ion-sieve nanospheres with extraordinary synergistic lithium adsorption performance: Facile mild calcination synthesis and molecular dynamics simulation investigation. 2024, To be submitted.

[59] Wang, F.; Liang, K.R.; Hui, Q.X.; Hu, H.; Zhang, X.R.; Zhang, C.C.; Yin, H.; Wu, B.Y.; Zhang, L.Y.*, Zhang, H.;  Zhu, W.C.*. Rotating hydrothermal synthesis of hierarchical flowerlike mesoporous cobalt nickel silicates composite microspheres for highly efficient electrochemical detection of hydrogen peroxide. 2024, Under review.

[58] Hui, Q.X.; Hang, Y.R.; Wang, F.; Dai, H.P.; Li, Z.D.; Zhang, X.R.; Wu, B.Y.; Guan, Z.Y.; Zhang, H.*; Zhang, L.Y.; Zhu, W.C.*. Red mud based uniform hierarchical porous flowerlike boehmite (γ-AlOOH) microspheres: Rotating hydrothermal synthesis, force analysis, formation mechanism and superior adsorption performances for anionic dyes removal. 2024, Under review. 

[57] Jia, X.H.^#;  Sun, P.P.^#; Liu, A.Q.; Chen, J.X.; Wang, J.Y.; Zhang, H.; Zhu, W.C.*.  One-pot hydrothermal synthesis of the nanosheets constructed hollow cobalt silicate hydroxide hierarchical porous submicron spheres as efficient adsorbents for organic dyes removal. Chemical Research in Chinese Universities, 2023, 39(4), 680-689.

[56] Wang, L.H.; Li, H.W.; Li, M.Y.; Zhang, L.Y.; Zhang, H.; Liu, Z.Y.; Zhu, W.C.*. Trace Nitrogen-doped hierarchical porous biochar nanospheres: Waste corn roots derived superior adsorbents for high concentration single and mixed organic dyes removal. Nano Research, 2023, 16(2), 1846-1858 (https://doi.org/10.1007/s12274-022-5248-8).  (SCI. IF=9.9, 大类材料科学-2区)

[55] Zheng, Y.Y.^#; Wang, J.Y.^#; Sun, P.P.; Xue, H.M.; Zhang, L.Y.^*; Chen, J.X.; Zhang, H.; Zhu, W.C.*. Using waste to treat waste: Red mud induced hierarchical porous γ-AlOOH and γ-Al₂O₃ microspheres as superior Pd support for catalytic reduction of 4-nitrophenol. Particuology, 2023, 73, 59-67 (https://www.sciencedirect.com/science/article/pii/S1674200122000694) (SCI. IF=3.067, 工程技术-2区，Invited Paper).

[54] Zheng, Y.Y.; Wang, L.H.; Zhang, L.Y.; Zhang, H.; Zhu, W.C.*. One-pot hydrothermal synthesis of hierarchical porous manganese silicate microspheres as excellent Fenton-like catalysts for organic dyes degradation. Nano Research, 2022, 15(4): 2977−2986. (https://link.springer.com/article/10.1007/s12274-021-3929-3；新闻稿链接：https://mp.weixin.qq.com/s/IcaGT3QcOMElw8c7ZrT3cw) (SCI. IF=10.269, 大类材料科学-1区，TOP)

[53] Zhu, W.C.*; Sun, P.P.; Ran, W.G.; Zheng, Y.Y.; Wang, L.H.; Zhang, L.Y.; Jia, X.H.; Chen, J.X.; Wang, J.Y.; Zhang, H.; Liu, Z.Y.; Zhao, S. Rational design and facile hydrothermal-thermal conversion synthesis of hierarchical porous urchin-like Cu_2-xSi₂O₅(OH)₃·xH₂O and CuO/SiO₂ hollow microspheres for high efficiency catalytic reduction of nitroarenes and adsorption of organic dye. Chem. Eng. J. 2021, 411, 128442.   (SCI. IF=16.744，小类化工1区，工程技术-1区，TOP)  

[52] Wang, J.Y.; Sun, P.P.; Xue, H.M.; Chen, J.X.; Zhang, H.*; Zhu, W.C.*  Red mud derived facile hydrothermal synthesis of hierarchical porous α-Fe₂O₃ microspheres as efficient adsorbents for removal of Congo red. J. Phys. Chem. Solids 2020, 140, 109379. (SCI. IF=3.995, 大类工程3区) (https://doi.org/10.1016/j.jpcs.2020.109379) 

[51] Chen, J.-X.; Zhang, X.-Q.; Li, B.-Q.; Wang, X.-M.; Shi, P.; Zhu, W.C.*; Chen, A.; Jin, Z.; Xiang, R.; Huang, J.-Q.*; Zhang, Q.* The origin of sulfuryl-containing components in SEI from sulfate additives for stable cycling of ultrathin lithium metal anodes. J. Energy Chem. 2020, 47, 128-131.  (SCI. IF=7.216, 化工、化学-1区，TOP）

[50] Xu, L.; Sun, P.P.; Jiang, X.Z.; Chen, J.X.; Wang, J.Y.; Zhang, H.; Zhu, W.C.* Hierarchical quasi waxberry-like Ba₅Si₈O₂₁ microspheres: Facile green rotating hydrothermal synthesis, formation mechanism and high adsorption performance for Congo red. Chem. Eng. J. 2020, 384, 123387.  (SCI. IF=13.273，小类化工1区，大类工程-1区，TOP)  (https://doi.org/10.1016/j.cej.2019.123387)

[49] Jiang, X.Z.; Sun, P.P.; Xu, L.; Xue, Y.R.; Zhang, H.; Zhu, W.C.* Platanus orientalis leaves based hierarchical porous carbon microspheres as high efficiency adsorbents for organic dyes removal. Chinese J. Chem. Eng. 2020, 28, 254-265.  (SCI. IF=2.627)  

[48] Kong, L.ǂ; Chen, J.-X.ǂ;  Peng, H.-J.ǂ; Huang, J.-Q.* ; Zhu, W.C.* ;  Jin, Q.;  Li, B.-Q.; Zhang, X.-T.;  Zhang, Q.* Current-density dependence of Li₂S/Li₂S₂ growth in lithium–sulfur batteries. Energy & Environmental Science 2019, 12, 2976-2982. (SCI. IF=30.289，化工-1区，TOP)

[47] Sun, P.P.; Xu, L.; Jiang, X.Z.; Zhang, H.; Zhu, W.C.* Facile and green one-pot hydrothermal formation of hierarchical porous magnesium silicate microspheres as excellent adsorbents for anionic organic dye removal. Ind. Eng. Chem. Res. 2019, 58, 2945-2957.  (SCI. IF=3.573, 小类化工-3区，大类工程-2区，TOP)

[46] Xu, L.; Sun, P.P.; Chen, X.P.; Zhai, P.Y.; Zhu, W.C.* Facile hydrothermal-thermal conversion synthesis of CaSiO₃ nanowires as promising structure and function integrated photoluminescent host candidate. Chinese Chem. Lett. 2019, 30(1), 171-174.  (SCI. IF=4.632, 大类化学2区)

[45] Zhu, W.C.*; Chen, X.P.; Sun, P.P.; Li, J.; Zhai, P.Y.; Zheng, Y.Y.; Wang, L.H.; Zhang, H.; Zhang, Z.S. Correction: Facile hydrothermal synthesis of hierarchical porous priceite (Ca₄B₁₀O₁₉·7H₂O) microspheres as high efficiency adsorbents for heavy metal ions removal. CrystEngComm  2019,  21, 7329-7329.  (SCI. IF=3.117, 大类化学3区, 大类物理2区)

[44] Zhu, W.C.*; Chen, X.P.; Sun, P.P.; Li, J.; Zhai, P.Y.; Zheng, Y.Y.; Wang, L.H.; Zhang, H.; Zhang, Z.S. Facile hydrothermal synthesis of hierarchical porous priceite (Ca₄B₁₀O₁₉·7H₂O) microspheres as high efficiency adsorbents for heavy metal ions removal. CrystEngComm 2019, 21, 7141-7154.  (SCI. IF=3.117, 大类化学3区,大类物理2区)

[43] Zhu, W.C.*; Zhang, Z.Q.; Xu L.; Zhai, K.L.; Sun, P.P. Ultralong Ca₂B₂O₅·H₂O nanowires: Water-bath pretreated eco-friendly hydrothermal synthesis, optical and rare earth doped photoluminescence properties. CrystEngComm 2019, 21, 2451-2463. (SCI. IF=3.117, 大类化学3区,大类物理2区)

[42] Xu, L.; Sun, P.P.; Chen, X.P.; Li, J.; Zhai, P.Y.; Zhang, H.; Zhang, Z.S.; Zhu, W.C.* High aspect ratio Ca₆Si₆O₁₇(OH)₂ nanowires: Green hydrothermal synthesis, Formation mechanism, Optical and photoluminescence properties. Powder Technol. 2018, 335, 360-370. (SCI. IF=3.413, 小类化工2区，大类工程2区)  (https://doi.org/10.1016/j.powtec.2018.05.010)

[41] Sun, P.P.; Chen, L.Y.; Xu, L.;  Zhu, W.C.* Hierarchical porous MgBO₂(OH) microspheres: Hydrothermal synthesis, thermal decomposition, and application as adsorbents for Congo red removal. Chinese J. Chem. Eng. 2018, 26, 1561-1569. (DOI: https://doi.org/10.1016/j.cjche.2018.01.013)

[40] Zhai, P.Y.; Chen, X.P.; Zhang, Z.Q.; Zhu, L.; Zhang, H.; Zhu, W.C.* Facile room-temperature coprecipitation for uniform barium chloroapatite (Ba₅(PO₄)₃Cl) nanoassemblies as great potential host photoluminescent candidates. Particuology 2018, 37, 37-42.  (SCI. IF=2.621, 小类化工3区，大类工程3区)

[39] Sun, P.P.; Xu, L.; Li, J.; Zhai, P.Y.; Zhang, H.; Zhang, Z.S.; Zhu, W.C.* Hydrothermal synthesis of mesoporous Mg₃Si₂O₅(OH)₄ microspheres as high-performance adsorbents for dye removal. Chem. Eng. J. 2018, 334, 377-388.  (SCI. IF=8.355，小类化工1区，大类工程1区，TOP) 

[38] Li, J.; Xu, L.; Sun, P.P.; Zhai, P.Y.; Chen, X.; Zhang, H.; Zhang, Z.; Zhu, W.C.* Novel application of red mud: Facile hydrothermal-thermal conversion synthesis of hierarchical porous AlOOH and Al₂O₃ microspheres as adsorbents for dye removal.  Chem. Eng. J. 2017, 321, 622-634. (SCI. IF=6.735，小类化工1区，大类工程1区，TOP)

[37] Zhai, P.Y.; Peng, H.J.; Cheng, X.B.; Zhu, L.; Huang, J.Q.*; Zhu, W.C.*; Zhang, Q.* Scaled-up fabrication of porous-graphene-modified separator for high-capacity lithium-sulfur batteries. Energy Storage Materials 2017, 7, 56-63. 

[36] Zhai, P.Y.; Huang, J.-Q.*, Zhu, L.; Shi, J.-L.; Zhu, W.C.*; Zhang, Q.* Calendering of free-standing electrode for lithium-sulfur batteries with high volumetric energy density. Carbon 2017, 111, 493-501. (SCI. IF=6.198，大类工程1区，TOP)

[35] Kong, L.; Peng, H.-J.; Huang, J.-Q.*; Zhu, W.C.*; Zhang, G.; Zhang, Z.-W.; Zhai, P.Y.; Sun, P.P.; Xie, J.; Zhang, Q.* Beaver-dam-like membrane: A robust and sulphifilic MgBO₂(OH)/CNT/PP nest separator in Li-S batteries.  Energy Storage Materials 2017, 8, 153-160. 

[34] Liu, Y.Y.; Zhou, D.*; Zhu, W.C.* Theoretical predictions of viscosity of methane under confined conditions. Chinese J Chem. Eng. 2016, 24, 904-908.(SCI. IF=1.207)

[33] Chen, X.P.; Zhai, P.Y.; Li, J.; Zhang, H.*; Zhu, W.C.* Hierarchical γ-BaB₂O₄ hollow microspheres: Surfactant-assisted hydrothermal formation, phase conversion, optical properties and application as adsorbents. RSC Adv. 2016, 6, 64383-64393 (SCI. IF=3.289, 大类化学2区，小类化学综合3区)

[32] Zhang, Z.Q.; Zhang, H.*; Zhu, L.; Zhang, Q.; Zhu, W.C.* Hierarchical porous Ca(BO₂)₂ microspheres: Hydrothermal-thermal conversion synthesis and their applications in heavy metal ions adsorption and solvent-free oxidation of benzyl alcohol. Chem. Eng. J. 2016, 283, 1273-1284. (SCI. IF=6.216，小类化工1区，大类工程1区，TOP)

[31] Zhang, H.*; Wang, T.; Zhu, W.C.* Controllable hydrothermal synthesis of star-shaped Sr₃Fe₂(OH)₁₂ assemblies and their thermal decomposition and magnetic properties. Particuology 2016, 24, 210-215(SCI. IF=2.11，大类工程、小类化工3区)

[30] Chen, X.P.; Zhang, L.L.; Zhang, Z.Q.; Zhu, L.; Zhu, W.C.* Hierarchical Ba₂(B₅O₉)Cl·(H₂O)_0.5 microspheres: surfactant-assisted facile hydrothermal synthesis, Tb³⁺ doping and photoluminescent properties. CrystEngComm 2015, 17, 7856-7865. (SCI. IF=4.034，大类化学、小类晶体学2区)

[29] Zhu, L.; Peng, H.-J.; Liang, J.; Huang, J.-Q.*; Chen, C.-M.; Guo, X.; Zhu, W.C.*; Li, P.; Zhang, Q.* Interconnected carbon nanotube/graphene nanosphere scaffolds as free-standing paper electrode for high-rate and ultra-stable lithium-sulfur batteries. Nano Energy  2015, 11, 746-755. (SCI. IF=11.553，小类材料科学:综合、大类工程1区，TOP, ESI 高被引论文)

[28] Peng, Hong-Jie^#; Liang, Jiyuan^#;  ZhuLin^#; Huang, Jia-Qi; Cheng, Xin-Bing; Guo, Xuefeng*; Ding, Weiping; Zhu, W.C.*; Zhang, Qiang*. Catalytic self-limited assembly at hard templates: A mesoscale approach to graphene nanoshells for lithium-sulfur batteries. ACS Nano 2014, 8 (11), 11280–11289. (IF=12.881，小类材料科学:综合、大类工程1区，TOP)

[27] Zhang, Z.Q.; Zhu, W.C.*; Wang, R.; Zhang, L.; Zhu, L.; Zhang, Q.* Ionothermal confined self-organization for hierarchical porous magnesium borate superstructures as high efficient adsorbents for dye removal. J. Mater. Chem. A 2014, 2 (45), 19167-19179. (SCI. IF=7.443，小类材料科学:综合2区、大类工程1区，TOP) (Inside Front Cover)

[26] Zhang, L.L.; Zhu, W.C.*; Zhang,H.; Bi, S.W.; Zhang,Q.* Hydrothermal-thermal conversion synthesis of hierarchical porous MgO microrods as efficient adsorbents for lead (II) and chromium (VI) Removal. RSC Adv. 2014, 4(58), 30542-30550. (SCI. IF=3.84，化学3区)

[25] Cui, X.L.; Liu, T.; Zhang, Z.Q.; Wang, L.; Zuo, S.Q.; Zhu, W.C.* Hematite nanorods with tunable porous structure: facile hydrothermal-calcination route synthesis, optical and photocatalytic properties. Powder Technol. 2014,266,113-119. (SCI. IF=2.349) <工程类三区>

[24] Zhu, L.; Zhu,W.C.*; Cheng, X.-B.; Huang, J.-Q.; Peng, H.-J.; Yang, S.-H.; Zhang, Q.*. Cathode materials based on carbon nanotubes for high density lithium-sulfur batteries. Carbon 2014,75,161-168. (SCI. IF=6.196) <工程类一区>

[23] Zhu, W.C.*; Wang, R.G.; Zhu, S.L.; Zhang, L.L.; Cui, X.L.; Zhang, H.; Piao, X.L.; Zhang, Q.* Green noncorrosive and easy scale-up hydrothermal-thermal conversion: a feasible solution to mass production of magnesium borate nanowhiskers. ACS Sustain. Chem. Eng. 2014, 2, 836-845. (SCI. IF=4.642，小类化工、大类化学2区)

[22] Zhu, W.C.*; Zhang, L.; Tian, G.-L.; Wang, R.; Zhang, H.; Piao, X.; Zhang, Q.* Flux and surfactant directed facile thermal conversion synthesis of hierarchical porous MgO for efficient adsorption and catalytic growth of carbon nanotubes. CrystEngComm 2014, 16, 308-318. (SCI. IF=4.034) <晶体学二区>（Cover Article）

[21] Zhu, W.C.*; Cui, X.; Liu, X.; Zhang, L.; Huang, J-Q.; Piao, X.; Zhang, Q.*. Hydrothermal evolution, optical and electrochemical properties of hierarchical porous hematite nanoarchitectures. Nanoscale Res. Lett. 2013, 8:2. (SCI. IF=2.524) <材料类二区>

[20] Liu, X.; Huang, J.-Q.; Zhang, Q.*; Liu, X.-Y.; Peng, H.-J.; Zhu, W.C.*; Wei, F.* N-Methyl-2-pyrrolidone-assisted solvothermal synthesis of nanosize orthorhombic lithium iron phosphate with improved Li-storage performance. J. Mater. Chem. 2012, 22, 18908. (SCI. IF=6.10) <化学类二区>

[19] Liu, X.; Zhu, W.C.*; Cui, X.; Liu, Tao.; Zhang, Q. Facile thermal conversionroute synthesis, characterization, and optical properties of rod-like micron nickel borate. Powder Technol. 2012, 222, 160-166. (SCI. IF=2.024) <工程类三区>

[18] Zhu, W.C.*; Liang, Z.; Liu, X.; Zhang, H.; Zheng, Y.; Piao, X.; Zhang, Q. Soft-template self-assembly of hierarchical mesoporous SrCO₃ by low-temperature hydrothermal route and their application as adsorbents for methylene blue and heavy metal ions. Powder Technol. 2012, 226, 165-172. (SCI. IF=2.024) <工程类三区>

[17] Zhu, W.C.; Yang, Y.; Hu, S.; Xiang, G.; Xu, B.; Zhuang, J.; Wang X*. (Ni,Mg)₃Si₂O₅(OH)₄ solid-solution nanotubes supported sub-0.06 wt% Pd as robust high efficiency catalyst for Suzuki-Miyaura cross-coupling reactions. Inorg. Chem. 2012, 51, 6020-6031. (SCI. IF=4.593)<化学类二区>

[16] Zhu, W.C.*; Zhang, X.; Wang, X.L.; Zhang, H.; Zhang, Q.*; Xiang, L. Short belt-like Ca₂B₂O₅·H₂O nanostructures: Hydrothermal formation, FT-IR, thermal decomposition, and optical properties. J. Cryst. Growth 2011, 332, 81-86. (SCI. IF=1.726) <材料类三区>

[15] Zhu, W.C.*; Wang, X.L.; Zhang, X.; Zhang, H.; Zhang, Q.*. Hierarchical laminar superstructures of rhombic priceite (Ca₄B₁₀O₁₉·7H₂O): Facile hydrothermal synthesis, shape evolution, optical and thermal decomposition properties. Cryst. Growth Des. 2011, 11, 2935-2941. (SCI. IF=4.72)<化学类二区>

[14] Zhu, W.C.*; Zhang, L.Y.; Cui, X.L.; Zhang, Q.* Efficient synthesis of orthorhombic lithium borate hydroxide micro-rods and their thermal conversion to lithium borate. Powder Technol. 2011, 210, 67-72. (SCI. IF=2.08)<工程类三区>

[13] Zhu, W.C.*; Zhang, Q.; Xiang, L.*; Zhu, S. Repair the pores and preserve the morphology: Formation of high crystallinity 1D nanostructures via the thermal conversion route. Cryst. Growth Des. 2011, 11, 709-718. (SCI. IF=4.72)<化学类二区>

[12] Zhu, W.C.*; Cui, X.L.; Wang, L.; Liu, T.; Zhang, Q*. Monodisperse porous pod-like hematite: hydrothermal formation, optical absorbance, and magnetic properties. Mater. Lett. 2011, 65, 1003-1006. (SCI. IF=2.307)<材料学三区>

[11] Zhu, W.C.*; Zhang, Q.; Xiang, L.*; Zhu, S. Green co-precipitation byproduct-assisted thermal conversion route to submicron Mg₂B₂O₅ whiskers. CrystEngComm 2011, 13, 1654-1663. (SCI. IF=3.842)<化学类二区，晶体学二区>

[10] Zhu, W.C.*; Zhang, G.L.; Liu, C.M.; Zhang, Q.; Zhu, S. Hierarchical strontium carbonate submicron spheres self-assembled under hydrothermal conditions. Cryst. Res. Technol. 2010, 45, 845-850. (SCI. IF=0.946)<晶体学四区> 

[09] Zhu, W.C.*; Li, G.D.; Zhang, Q.; Xiang, L.*; Zhu, S. Hydrothermal mass production of MgBO₂(OH) nanowhiskers and subsequent thermal conversion to Mg₂B₂O₅ nanorods for biaxially oriented polypropylene resins reinforcement. Powder Technol. 2010, 203, 265-271. (SCI. IF=1.887)<工程类三区>

[08] Zhu, W.C.*; Zhang, G.L.; Li, J.; Zhang, Q.*; Piao, X.L.; Zhu, S. Hierarchical mesoporous SrCO₃ submicron spheres derived from reaction-limited aggregation induced “Rod-to-Dumbbell-to-Sphere” self-assembly. CrystEngComm 2010, 12, 1795-1802. (SCI. IF=4.006)<化学类二区>

[07] Zhu, W.C.*; Zhu, S.L.; Xiang, L.* Successive effect of rolling up, oriented attachment and Ostwald ripening on the hydrothermal formation of szaibelyite MgBO₂(OH) nanowhiskers. CrystEngComm 2009, 11, 1910-1919. (SCI. IF=4.183) <化学类二区>

[06] Zhu, W.C.*; Zhang, X.Y; Xiang, L.*; Zhu, S.L. Hydrothermal formation of the head-to-head coalesced szaibelyite MgBO₂(OH) nanowires. Nanoscale Res. Lett. 2009, 4, 724-731. (SCI. IF=2.894)< 材料类二区>

[05] Zhu, W.C.*; Zhang, Q.; Xiang, L.*; Wei, F.; Sun, X.T.; Piao, X.L.; Zhu, S.L. Flux-assisted thermal conversion route to pore-free high crystallinity magnesium borate nanowhiskers at a relatively low temperature. Cryst. Growth Des. 2008, 8(8), 2938-2945. (SCI. IF=4.215) <化学类二区>

[04] Zhu, W.C.*; Xiang, L.*; Zhang, Q.; Zhang, X.Y.; Hu, L.; Zhu, S.L. Morphology preservation and crystallinity improvement in the thermal conversion route to magnesium borate nanowhiskers at a relatively low temperature. J. Cryst. Growth 2008, 310, 4262-4267. (SCI. IF=1.757) <晶体学三区>

[03] Zhu, W.C.; Xiang, L.*; Zhang, X.Y.; Zhu, S.L. Influence of process parameters on hydrothermal formation of magnesium borate hydroxide nanowhiskers. Mater. Res. Innov. 2007, 11(4), 188-192. (SCI. IF=1.723; EI 9840066) 

[02] Zhu, W.C.; Xiang, L.*; He, T.B.; Zhu, S.L. Hydrothermal synthesis and characterization of magnesium borate hydroxide nanowhiskers. Chem. Lett. 2006, 35(10), 1158-1159. (SCI. IF=1.734) <化学类三区>

[01] Zhu, W.C.; Chen, J.; Wang, Y. Synthesis and characterization of ultra-fine calcium carbonate whiskers in high-gravity. Chinese J. Chem. Phys. 2004, 17(2): 175-178. (In Chinese) 

朱万诚，陈建峰，王玉红，超重力环境中合成微细晶须碳酸钙及其表征，化学物理学报 2004, 17(2), 175-178. (SCI. IF=0.469)

2、其他合作SCI论文 ~【13】

[17] Zhang, H.*; Liu,J.Q.; Liu,C.Y.; Wang,T.T.; Zhu, W. High dispersion of heteropolyacid nanoparticles on hydrothermally Cs-modified three-dimensionally ordered macroporous SiO₂ with excellent selectivity in methacrolein oxidation, Chinese J. Chem. Eng., 2020, 28: 2785-2791.

[16]Ma, X.X.; Wang, T.T.; Zhang, M.N.; Zhu, W.; Zhang, Z.S.; Zhang, H.* Heteropoly Acid Supported on Cu-Doped Three-Dimensionally Ordered Macroporous SiO₂ as Efficient Catalyst for the Selective Oxidation of Methacrolein,Catalysis Lett., 2018, 148: 660-670.

[15] Zhang, H.*; Wang, Jiajia; Liu, Xu; Ma, Xinxin; Zhu, W.C.*. Hydrothermal synthesis of pure-phase hierarchical porous hexagonal WO₃ microspheres as highly efficient support for Pd catalyst for hydrogenation, Particuology, 2018, 41: 126-132.

[14] Zhang, H.*;  Wang, T.T.; Chen, X.P.;  Zhu, W.C.*. Controllable hydrothermal synthesis of star-shaped Sr₃Fe₂(OH)₁₂ assemblies and their thermal decomposition and magnetic properties,Particuology, 2016, 24: 210-215.

[13] Wang, T.; Liu, C.; Ma, X.; Zhu, W.; Lv, X.; Zhang, H.* Synthesis of Ni₃Si₄O₁₀(OH)₂ porous microspheres as support of Pd catalyst for hydrogenation reaction. Nanomaterials 2019, 9, 998. (SCI. IF=4.034, 小类纳米科技3区、大类工程2区)

[12] Zhao, M.Q.; Liu, X.F.; Zhang, Q.; Tian, G.L.; Huang, J.Q.; Zhu, W.C.; Wei, F. Graphene/single-walled carbon nanotube hybrids: One-step catalytic growth and applications for high-rate Li-S batteries. ACS Nano 2012, 6(12), 10759–10769. <SCI, IF=12.062, 化学类、工程类、纳米类、物理类一区>

[11] Huang, J.Q.; Liu, X.F.; Zhang, Q.; Chen, C.M.; Zhao, M.Q.; Zhang, S.M.; Zhu, W.C.; Qian, W.Z.; Wei, F. Entrapment of sulfur in hierarchical porous graphene for Lithium-sulfur batteries with high rate performance from -40 to 60^oC. Nano Energy 2013, 2(2), 314-321. (SCI.IF=10.211)

[10] Zhang, S.M.; Zhang, Q.; Huang, J.Q.; Liu, X.F.; Zhu, W.C.; Zhao, M.Q.; Qian, W.Z.; Wei, F. Composite cathode containing SWCNT@S coaxial nanocables: Facile synthesis, surface modification, and enhanced performance for Li-ion storage. Particle & Particle System Characterization 2013, 30(2), 158-165. (SCI检索，新期刊)

[09] Huang, J.Q.; Zhang, Q.; Zhang, S.M.; Liu, X.F.; Zhu, W.C.; Qian, W.Z.; Wei, F. Carbon nanotube@sulfur coaxial arrays asymmetrically modified by polymer barrier for high efficient sulfur cathodes. Carbon 2013, 58, 99-106. (SCI期刊，IF=5.868，工程类一区)

[08] Cheng, X.B.; Tian, G.L.; Liu, X.F.; Nie, J.Q.; Zhao, M.Q.; Huang, J.Q.; Zhu, W.C.; Hu, L.; Zhang, Q.*; Wei, F. Robust growth of herringbone carbon nanofibers from layered double hydroxides and their applications as anodes for Li-ion batteries. Carbon 2013, 62, 393-404. (SCI期刊，IF=5.868，工程类一区) 

[07] Liu. X.Y.; Peng, H.J.; Zhang, Q.; Liu, X.F.; Huang, J.Q.; Zhu, W.C.; Wei, F. The use of carbon nanotubes and carbon black as conductive pastes in the cathode for Li-ion battery. ACS Sustain. Chem. Eng. 2013, DOI: 10.1021/sc400239u. (SCI检索，新期刊)

[06] Zhang, C.; Zhu, W.C.; Li, S.; Wu, G.; Ma, X.; Wang, X.; Gong, J. Sintering-resistant Ni-based reforming catalysts obtained via the nanoconfinement effect. Chem. Commun. 2013, 49, 9383-9385. (SCI. IF=6.38)<化学类二区>

[05] Long, Y.; Hui, J.F.; Wang, P.P.; Xiang, G.L.; Xu, B.; Hu, S.; Zhu, W.C.; Lv, X.Q.; Zhuang, J.; Wang, X. Hydrogen bond nanoscale networks showing switchable transport performance. Scientific Report. 2012, DOI: 10.1038/srep00612.

[04] Zhang, Q.; Zhao, M.Q.; Tang, D.M.; Li, F.; Huang, J.Q.; Liu, B.L.; Zhu, W.C.; Zhang, Y.H.; Wei, F. Carbon-nanotube-array double helices. Angew. Chem. Int. Ed. 2010, 122, 3724-3727. (SCI. IF=12.73)<化学类一区>

[03] He, T.B.; Xiang, L.*; Zhu, W.C.; Zhu, S.L. H₂SO₄-assisted hydrothermal preparation of γ-AlOOH nanorods. Mater. Lett. 2008, 62(17-18), 2939-2942. (SCI. IF=1.748) <材料类二区>

[02] Sun, X.T.; Xiang, L.*; Zhu, W.C.;  Liu, Q. Influence of solvents on the hydrothermal formation of magnesium hydroxide fibers. Cryst. Res. Technol. 2008, 43(10), 1057-1061.(SCI. IF=0.921) <晶体学四区>

[01] Sun, X.T.; Shi, W.T.; Xiang, L.*;Zhu, W.C. Controllable synthesis of magnesium oxysulfate nanowires with different morphologies. Nanoscale Res. Lett. 2008, 3(10), 386-389.(SCI. IF=1.731) <材料类三区>

二、EI&非SCI第一/通讯作者论文 ~【5】

[5] Zhang, Z.Q.; Zhu, W.C.* Advances in one-dimensional nanostructured borates: from fundamental thermodynamics to engineering practice. CIESC Journal 2014, 65(7), 2588-2619 (Review, In Chinese)

张照强; 朱万诚*. 一维纳米硼酸盐研究进展：从基础热力学到工程实践. 化工学报  2014, 65(7), 2588-2619（综述）. (21276141, SKL-ChE-12A05) (EI收录)

[4] Zhu, W.C.*; Zhang, X.; Zhang, Q.;Xiang, L.; Zhu, S. Subunit contribution model for borates thermodynamic properties and its application in the hydrothermal synthesis of MgBO₂(OH) nanowhiskers. CIESC Journal 2013, 64(2):443-451. (In Chinese)

朱万诚, 张学一, 张强, 向兰, 朱慎林. 硼酸盐热力学基元贡献模型及在MgBO₂(OH)纳米晶须水热合成过程分析中应用. 化工学报 2013, 64(2), 443-451. (EI收录)

[3] Zhu, W.C.; Chen, J.; Wang, Y. Experimental study on the synthesis of ultra-fine calcium carbonate whiskers in rotating packed bed reactor. Mater. Sci. & Technol. 2005, 13(1), 30-33+37. (In Chinese)

朱万诚，陈建峰，王玉红，旋转填充床中合成微细晶须碳酸钙的试验研究，材料科学与工艺 2005, 1, 3(1), 30-33+37. (EI. 05179069967)

[2] Zhu, W.C.; Chen, J. Progress in synthesis of calcium carbonate whiskers. Modern Chemical Industry 2004, 24(n suppl.): 21-22+24. (In Chinese) 

朱万诚，陈建峰，晶须碳酸钙的合成进展，现代化工 2004, 24(n suppl.), 21-22+24. (EI. 04448437185)

[1] Zhu, W.C.; Wang, Y.; Chen, J.; Shi, Y. Synthesis of ultra-fine needle-like calcium carbonate particles by high-gravity technology and its characterization. J. Beijing Univ. Chem. Technol. 2002,29(5):16-18+24. (In Chinese)

朱万诚，王玉红，陈建峰，施用唏，微细针状碳酸钙的超重力法制备及表征，北京化工大学学报 2002, 29(5), 16-18+24. (EI. 02497258212)

三、第一作者一般性学术论文 ~【3】

[3] 朱万诚*，张恒，周迪，张雨强. 打造温馨科研之家，促师范院校工科专业人才培养.曲阜师范大学学报(自然科学版) 2015, 41(3), 115-118（21276141）.

[2] Zhu, W.C.; Chen, J.; Wang, Y. On The Crystal Progress and Product Stability of the Ultrafine Calcium Carbonate Whiskers in High- Gravity Field. J. Qufu Normal Univ. 2003, 29(4): 77-81. (In Chinese)

朱万诚，陈建峰，王玉红，超重力场中微细晶须碳酸钙结晶过程及产品稳定性研究，曲阜师范大学学报(自然科学版), 2003, 29(4):77-81.

[1] Zhu, W.C.; Wang, Y.; Chen, J. Synthesis of Ultra-fine Needle-like Calcium Carbonate Particles by High-Gravity Reactive Precipitation. J. Chem. Eng. Chinese Univ., 2002, 16(5):560-564. (In Chinese)

朱万诚，王玉红，陈建峰，超重力反应结晶法合成微细针状碳酸钙研究，高校化学工程学报, 2002, 16(5), 560-564. 

四、书篇 ~【1】

[1] 朱万诚; 张照强 纳米晶生长机理[M]//纳米材料液相合成. 王训 等编著. 北京：化学工业出版社，2017.5.

[23] 朱万诚，王斐，惠庆雪，张历云，张恒. 一种以赤泥或正硅酸乙酯(TEOS)为原料制备高性能二氧化硅消光剂的方法.2024-5-9,中国，申请号：202410566371.X

[22] 朱万诚，惠庆雪，王斐，张历云，张恒.一种从赤泥中提取有价金属制备功能氧化物的旋转水热法及其构建复合膜与应用. 2023-11-16，中国，申请号：202311528227.9

[21] 朱万诚，王亚萌，苏羽贝，张历云，黄俞钢，杨子印. 一种锰钛基复合锂离子筛及其制备方法与应用. 2022-11-04，中国，申请号：202211374670.0

[20] 朱万诚，王丽华，李红伟，郑宇宇，张历云，张恒. 一种废弃农作物根系为原料制备掺氮多孔碳的方法及应用. 2023-9-19，中国，ZL 202111469464.3

[19] 朱万诚，郑宇宇，孙盼盼，张恒，张历云. 一种硅酸锰微球的绿色一步水热合成方法及应用. 2020-11-05，中国，申请号：202011224423. 3 

[18] 朱万诚，许林，孙盼盼，姜学珍. 一种硅酸钡微球及其制备方法和应用. 发明专利，申请号：201911063962.0

[17] 朱万诚，孙盼盼，贾晓浩，陈金秀，王婧伊. 羟基硅酸钴中空微球和硅酸钴中空微球及两者的制备方法和应用. 2023-02-19，中国，ZL 201910878597.2

[16] 朱万诚，孙盼盼，许林，姜学珍. 一种硅酸铜中空微球的制备方法. 申请日：2018.08.15；授权日：2022-02-25；中国，ZL 201810928860X

[15] 朱万诚，孙盼盼，许林，李杰，张恒，张兆顺. 一种介孔硅酸镁微球及其水热-热转化制备方法. 2019-10-8，中国，ZL 2017 1 0690833.9

[14] 朱万诚，张照强，翟奎露，朱林，张强. 一种高长径比水合及无水硼酸钙纳米晶须的温和水热-热转化合成方法. 2018-11-02，中国，ZL 2016 1 0299803.0

[13] 张恒，王婷婷，朱万诚.负载型杂多化合物催化剂、制备方法及其应用，2015, 中国，专利，申请号：201510916301.3；公开号：CN105457678A

[12] 朱万诚，李杰，翟配艳，陈秀平，张恒，张兆顺. 一种赤泥为原料制备活性勃姆石及氧化铝多孔微球的水热-热转化方法. 2018-06-12，中国, ZL 2017 1 0083548.0 

[11] 朱万诚，陈秀平，李杰，翟配艳，张恒，张兆顺，张强. 一种水合硼酸钙微球、无水硼酸钙微球及其制备方法. 2018-05-25，中国，ZL 2016 1 0369590.4

[10] 朱万诚，张照强，张恒，朱林，张强. 一种水合及无水多级多孔硼酸钙微球的低温水热-热转化合成方法. 2017-01-11，中国,  ZL 2015 1 0198818.3

[09] 朱万诚，张照强，于游，王汝国，张琳琳，朱林，张强. 一种微球状多孔碱式硼酸镁及硼酸镁纳米超结构的离子热合成方法.2016-06-01, 中国, ZL 2014 1 0399152.3

[08] 朱万诚，王汝国，朱山林，张琳琳，张强. 一种无孔高结晶硼酸镁纳米晶须的绿色水热合成方法. 2016-04-26, 中国, ZL 2014 1 0034281.2

[07] 向兰，朱万诚，朱慎林. 一种硼酸镁晶须的水热合成制备方法. 2008.3, 中国, ZL 200610113032.8

[06] 向兰，朱万诚，朱慎林. 一种无孔高结晶硼酸镁晶须的低温熔盐热转化制备方法. 2010.9, 中国, ZL 200810102550.9

[05] 张学一，朱万诚，向兰. 一维微-纳米结构材料特征尺寸测量软件V1.0. 计算机软件著作权登记证书. 登记号: 2007SRBJ1573

[04] 向兰，何涛波，高立东，朱万诚，朱慎林. 一种水热-熔剂工艺制备一维氧化铝纤维的方法. 中国, ZL 200710177969.6

[03] 魏飞，张强，黄佳琦，朱万诚. 一种基于氧化处理分离碳纳米管阵列与基板的方法. 2010.12, 中国, ZL 200810119666.3 

[02] 魏飞、黄佳琦、张强、刘晓斐、朱万诚. 一种锂离子电池用自支撑柔性碳纳米管纸复合电极材料. 中国,  CN 201210046590.2

[01] 魏飞、黄佳琦、张强、刘晓婓、张书锚、朱万诚. 一种用于锂硫二次电池的定向碳纳米管复合正极材料. 中国, ZL 201210046593.6

[25]朱万诚*. 低值资源高值高效利用探索：以碱土金属硅酸盐/赤泥/生物质基功能材料为例.第十一届全球华人化工学者研讨会, 四川大学, 成都, 2019.08.02-05, 口头.

[24]朱万诚*. 碱土金属硼/硅酸盐纳米纤维: 定向生长、三维组装及在储能与水处理等领域应用 / Alkaline earth metal borates/silicates nanofibers: Oriented growth, 3D self-assembly, and novel applications in energy storage and water treatment (oral). Frontiers in Chemical Engineering 10th Global Chinese Chemical Engineers Symposium (第十届全球华人化工学者研讨会)，Aug. 17-20, 2018，Niagara Falls，Ontario，Canada.

[23]陈秀平，张琳琳，张照强，朱林，朱万诚*. 多级Ba₂(B₅O₉)Cl·(H₂O)_0.5微球的水热合成及其Tb³⁺掺杂发光性能.2015中国化工学会年会，2015,10,16-18，北京

[22] 朱万诚. 碱土金属纳米硼酸盐：从基础热力学到定向生长、可控组装及应用开发. 第七届全球华人化工学者研讨会, 天津大学, 天津, 2015.07.12-15, 口头.

[21] Zhang, Z.Q.; Chen, X.P.; Zhu, L.; Zhang, H.; Zhu, W.C.* Alkaline Metal Borates Nanostructures: 1D Preferential Growth, 3D Self-assembly, and Applications in Water Treatment and Catalysis. 8 th International Conference on Materials for Advanced Technologies (ICMAT2015), 28 June-03 July, 2015, Singapore. (Oral)

[20]Zhu,W.C.*. Hydrothermal-thermal conversion route to Mg₂B₂O₅ nanowhiskers: from fundamental thermodynamics to green engineering practice. The 4^th International Symposium on Aqua Science and Water Resource (ISASWR2014)，Aug. 14-16, 2014, Taiyuan, China. (IL-3-8, 邀请报告, 分会主席) （21276141, SKL-ChE-12A05）

[19]朱万诚*, 张照强, 王汝国, 朱山林, 王晓丽, 张晓, 张历云, 张强. 碱/碱土金属硼酸盐：从基础热力学数据估算到绿色水热合成及组装. 第六届全球华人化工学者研讨会, 2014,7, 16-19, 香港科技大学(HKUST), 香港, 中国.（21276141, SKL-ChE-12A05）

[18] Zhu,W.C.*; Wang, R.; Zhu, S.; Zhang, L.; Zhang, H.; Zhang, Q.* Green, Noncorrosive, Easy Scale-Up Hydrothermal-Thermal Conversion: A Feasible Solution to Mass Production of Magnesium Borate Nanowhiskers. The 7^th World Congress of Particle Technology, 19-22, May, 2014, Beijing, China.（21276141, SKL-ChE-12A05）(E266)

[17] Zhang, L.; Zhu,W.C.*, Zhang, H.; Zhang, Q*. Hydrothermal-thermal conversion synthesis of hierarchical porous MgO microrods as efficient adsorbents for Pb (II) and Cr (VI) removal. The 7^th World Congress of Particle Technology, 19-22, May, 2014, Beijing, China. （21276141, SKL-ChE-12A05）(E265)

[16] Zhu,W.C.*; Yang, Y.; Hu, S.; Wang, X. (Ni,Mg)3Si2O5(OH)4 Solid-Solution Nanotubes: Controllable Hydrothermal Synthesis and Supported Catalytic Application. The 3rd Conference on Nanomaterials (CN 2014). Jan. 14-15, 2014, Shenzhen, China.（21276141, SKL-ChE-12A05）(ID 60250)

[15] Zhang, L.; Tian, G.-L.; Wang, R.; Zhang, H.; Piao, X.; Zhang, Q.*; Zhu,W.C.*. Hierarchical Porous MgO: Flux and Surfactant Directed Facile Thermal Conversion Synthesis and Application for Adsorption and Catalytic Growth of Carbon Nanotubes. EnerParticle2013, (3rd Symposium of Particulate Energy Materials, Chinese Particuology Society, 2013年能源颗粒前沿-暨第三届全国能源颗粒材料学术研讨会会议), Dec. 13-15, 2013, Beijing, China.（21276141, SKL-ChE-12A05）(Poster-22).

[14] Zhang, Z.; Wang, R.; Zhang, L.; Zhu, L.; Nie, Y.; Zhang, Q.*; Zhu, W.*Ionothermal-Thermal Conversion Synthesis and Application of Hierarchical Porous MgBO₂(OH)/Mg₂B₂O₅ Superstructures. EnerParticle2013, (3rd Symposium of Particulate Energy Materials, Chinese Particuology Society, 2013年能源颗粒前沿-暨第三届全国能源颗粒材料学术研讨会会议), Dec. 13-15, 2013, Beijing, China.（21276141, SKL-ChE-12A05）(Poster-11). 

[13]朱林、朱万诚、黄佳琦、程新兵、彭翃杰、何濂远、元喆、张强.用于高能量密度的锂硫电池的碳纳米管基正极材料. 2013年能源颗粒前沿-暨第三届全国能源颗粒材料学术研讨会会议, 2013, 12, 13-15, 北京.（Poster-27）

[12]Zhu,W.C.*; Wang, X.L.; Zhang, X.; Zhang, Q. Calcium borates nanostructures : hydrothermal formation, self-assembly, thermal conversion, and properties. UK-China International Particle Technology Forum IV (UCIPTF IV). Shanghai, China, 2013, Oct. 15-17. （21276141, SKL-ChE-12A05）(Oral-ABS039).  

[11]朱万诚*, 王汝国, 朱山林, 张琳琳, 张强.硼酸镁纳米晶须的无腐蚀绿色水热合成及性能. 2013中国化工学会年会，9, 23-25, 南京.（21276141, SKL-ChE-12A05）(化工新材料分会场-Oral).

[10] 朱万诚*, 张琳琳, 张照强, 张强. 纳米结构材料湿化学-热转化法合成过程中的形貌保持及结构调变. 国际化学工程前沿展望-第五届全球华人化工学者研讨会, 2013,7,22-25, 西安.（21276141, SKL-ChE-12A05）(Oral-67)

[9]Zhu,W.C.*; Zhang, L.; Wang, X.; Zhang, X.; Zhang, Q. Alkaline-earth borates & oxides: wet-chemistry based thermal conversion route synthesis, properties and applications. Collaborative Conference on Crystal Growth (3CG 2013 Meeting), Cancun, Mexico, June 10-13, 2013. (21276141, SKL-ChE-12A05) (Invited, B8, 邀请报告)

[8]张琳琳, 刘晓斐, 田桂丽, 梁作中, 张强, 朱万诚*. 多级多孔氧化镁超结构：热转化合成、形成机制及应用. 中国化学会第28届学术年会，2012, 4, 13-16, 成都. (04-P-157). 

[7] Zhu, W.C.*; Zhang, G.L.; Wang, X.L.; Zhang, L.Y. Hydrothermal Technology: an Intensified Process for Nanoparticles Growth and Assembly. The International Conference on Process Intensification for Sustainable Chemical Industries (ICPI 2011), June, 26-29, 2011, Beijing, China. (Oral: S1-O-4)

[6] Zhu, W.C.*; Xiang, L.; Zhu, S.L. Formation of pore-free magnesium borate nanowhiskers and their reinforcement for BOPP-D1 resins. 2nd International Solvothermal and Hydrothermal Association Conference (ISHA-2010), Beijing, China, July, 2010. (Oral: 2O-09)

[5] 朱万诚, 向兰, 朱慎林. 水热-焙烧法制备无孔硼酸镁纳米晶须. 中国化学会第27届学术年会, 2010, 6, 20-23, 厦门. (04-P-030)

[4] Zhu, W.C.; Xiang, L.; Zhang, X.Y.; Zhu, S.L. Influence of the precursor on the morphology of MgBO2(OH) nanowhiskers. International conference on nanoscience & technology, China 2007 (ChinaNANO 2007), Beijing, China, June, 2007. (Poster: 1P-502)

[3]朱万诚，向兰，朱慎林.一维纳米碱式硼酸镁的形貌演变、择优取向生长及热分解特性. 第三届全国化学工程与生物化工年会，南宁，2006年11月. (Oral: 730)

[2] Zhu, W.C.; Xiang, L.; Zhu, S.L. Hydrothermal synthesis of whisker-like magnesium borate hydroxide (MgBO2(OH))nanoflakes. The 17th international congress of chemical and process engineering (CHISA 2006), Prague, Czech Republic, August, 2006. (Oral: 1009, EI. 074010843467)

[1] Zhu, W.C.; Xiang, L.; He, T.B.; Zhu, S.L. Influence of process parameters on the hydrothermal formation of magnesium borate hydroxide nanowhiskers. International joint meeting of the eighth international symposium on hydrothermal reactions (ISHR-8) and seventh international conference on solvothermal reactions (ISHR & ICSTR 2006), Sendai, Japan, August, 2006. (Poster: P-065)