2020
42) J. Q. Ran, D. Q. Gao*, Modulation of Electronics of Oxide Perovskites by Sulfur Doping for Electrocatalysis in Rechargeable Zn−Air Batterie, Chemistry of Materials, (2020) accept
41)J. M. Qian, D. Q. Gao*, Engineered Spin State in Ce doped LaCoO3 with Enhanced Electrocatalytic Activity for Rechargeable Zn-Air Batteries, Nano Energy (2020) accept
40)B. R. Xia, Z. X. Liao, Y. G. Liu, C. Chi, W. Xiao, J. Ding, T. T. Wang, D. Q. Gao* and D. S. Xue, Realization of “single-atom ferromagnetism” in graphene by Cu–N4 moieties anchoring, Applied Physics Letters 116 (2020): 113102.
39)J. Y. Zhang, T. T. Wang, D. S. Xue, C. Guan*, P. X. Xi, D. Q. Gao*, W. Huang, Energy-level Engineered Hollow N-doped NiS1.03 for Zn–Air Batteries, Energy Storage Materials, 25 (2020): 202-209.
38)Z. M. Zhang, X. L. Liang, J. F. Li, J. M. Qian, Y. G. Liu, S. L. Yang, Y. Wang, D. Q. Gao, D. S. Xue, Interfacial Engineering of NiO/NiCo2O4 Porous Nanofibers as Efficient Bifunctional Catalysts for Rechargeable Zinc-air Batteries, ACS Applied Materials & Interfaces 12 (2020): 21661-21669
2019
37)B. R. Xia, a T. T. Wang,a X. D. Jiang,a J. Li,b T. M. Zhang,b P. X. Xi,a D. Q. Gao*a and D. S. Xuea, N+-ion irradiation engineering towards the efficient oxygen evolution reaction on NiO nanosheet arrays, Journal of Materials Chemistry A 7 (2019): 4729.
36)J. M. Qian, X. S. Guo, T. T. Wang, P. T. Liu, H. Zhang, D. Q. Gao, Applied Catalysis B-Environmental 250 (2019):71-77.
35)J. Y. Zhang, X. W. Bai, T. T. Wang, W. Xiao, P. X. Xi, J. L. Wang, D. Q. Gao*, J. Wang*, Bimetallic nickel cobalt sulfide as efficient electrocatalyst for Zn–air battery and water splitting, Nano-micro Letters 11 (2019): 2.
34)Liu, Peitao, Y. T. Hu, X. K. Liu, T. T. Wang, P. X. Xi, D. Q. Gao*a and John Wang*b , Cu and Co nanoparticle-Co-decorated N-doped graphene nanosheets: a high efficiency bifunctional electrocatalyst for rechargeable Zn–air batteries. Journal of Materials Chemistry A 7(2019): 12851-12858.
2018
33) P. T. Liu, D. Q. Gao*, W. Xiao, D.S. Xue*, J. Wang, Self-Powered Water-Splitting Devices by Core-Shell NiFe@N-Graphite-Based Zn-Air Batteries, Advanced Functional Materials 28(14):1706928
32) J. Y. Zhang, Y. C. Liu, C. Q. Sun, P. X. Xi, S. L. Peng, Daqiang Gao,* and Desheng Xue*, Accelerated Hydrogen Evolution Reaction in CoS2 by Transition-Metal Doping, ACS Energy Lett. 2018, 3, 779−786.
31) D. Q. Gao, * B. R. Xia, C. R. Zhu, * Y. H. Du, P. X. Xi, D. S. Xue, J. Ding * and J. Wang, Activation of the MoSe2 basal plane and Se-edge by B doping for enhanced hydrogen evolution, J. Mater. Chem. A, 2018, 6, 510
30) TMD-based highly efficient electrocatalysts developed by combined computational and experimental approaches, C. (Rose) Zhu, † D. Q. Gao, † J. Ding, D. L. Chao * and J. Wang*, Chem Soc Rev, DOI: 10.1039/c7cs00705a
29) D. Q. Gao, B. R. Xia, Y. Y. Wang, W. Xiao, P.X. Xi, D. S. Xue,*and J. Ding*, Dual-Native Vacancy Activated Basal Plane and Conductivity of MoSe2 with High-Effciency Hydrogen Evolution Reaction, Small 2018, 1704150
2017
28) B. R. Xia,T. T. Wang,X. Chi, X.J. Yu, P. T. Liu, J. Y. Zhang,S. B. Xi, Y. H. Du, and D. Q. Gao*, Anion vacancy-mediated ferromagnetism in atomic-thick Ni3N nanosheets, Appl. Phys. Lett. 111, 232402 (2017)
27) Y. G. Liu, P. T. Liu, C. Q. Sun, T. T. Wang, K. Tao, and D. Q. Gao*, P dopants induced ferromagnetism in g-C3N4 nanosheets: Experiments and calculations, Appl. Phys. Lett. 2017, 110, 222403.
26) P. T. Liu, J. Y. Zhu, J. Y. Zhang, P. X. Xi, K. Tao, D. Q. Gao*, D. S. Xue, P Dopants Triggered New Basal Plane Active Sites and Enlarged Interlayer Spacing in MoS2 Nanosheets toward Electrocatalytic Hydrogen Evolution, ACS Energy Lett. 2017, 2, 745−752
25) J. Y. Zhang, W. Xiao, P. X. Xi, S. B. Xi, Y. H. Du, D. Q. Gao*,J. Ding* , Activating and Optimizing Activity of CoS2 for Hydrogen Evolution Reaction through the Synergic Effect of N Dopants and S Vacancies, ACS Energy Lett. 2017, 2, 1022−1028.
24) W. Xiao,P. T. Liu,J. Y. Zhang,W. D. Song,Y. P. Feng,D. Q. Gao*,J. Ding*,Dual-Functional N Dopants in Edges and Basal Plane of MoS2 Nanosheets Toward Effcient and Durable Hydrogen Evolution,Adv. Energy Mater.,2017,1602086:1~10
23) P. T. Liu,J. Y. Zhang,D. Q. Gao*,W. C. Ye,Efficient visible light-induced degradation of rhodamine B by W(NxS1−x)2 nanoflowers,Sci. Rep.,2017,7:40784~40784
2016以前
22) D. Q. Gao,J. Y. Zhang,T. T. Wang,W. Xiao,K. Tao,D. S. Xue,J. Ding*,Metallic Ni3N nanosheets with exposed active surface sites for efficient hydrogen evolution,J. Mater. Chem. A,2016,4:17363~17369
21) D. Q. Gao,Y. G. Liu,P. T. Liu,M. S. Si*,D. S. Xue*,Atomically Thin B doped g-C3N4 Nanosheets: High-Temperature Ferromagnetism and calculated Half-Metallicity,Sci. Rep.,2016,6:35768~35768
20) C. Q. Sun,J. Y. Zhang,J. Ma,P. T. Liu,D. Q. Gao*, N-doped WS2 nanosheets: a high-performance electrocatalyst for the hydrogen evolution reaction,J. Mater. Chem. A,2016,4(29):11234~11238
19) P. T. Liu,Y. G. Liu,W. C. Ye*,J. Ma,D. Q. Gao*,Flower-like N-doped MoS2 for photocatalytic degradation of RhB by visible light irradiation,Nanotechnology,2016,27:225403~225403
18) J. Y. Zhang,T. T. Wang,P. T. Liu,Y. G. Liu,J. Ma,D. Q. Gao*, Enhanced Catalytic Activities of Metal-Phase-Assisted 1T@2H-MoSe2 Nanosheets for Hydrogen Evolution,Electrochim. Acta,2016,217:181~186
17) D. Q. Gao,Y. G. Liu,M. Y. Song,S. P. Shi,M. S. Si*,Manifestation of high-temperatureferromagnetism in fluorinated graphitic carbonnitride nanosheets,J. Mater. Chem. C,2015,3:12230~12235
16) D. Q. Gao,S. P. Shi,K. Tao,B. R. Xia,D. S. Xue*,Tunable ferromagnetic ordering in MoS2nanosheets with fluorine adsorption,Nanoscale,2015,7:4211~4215
15) S. P. Shi, B. R. Xia,P. T. Liu,D. Q. Gao*, D. S. Xue,Enhanced hydrogen evolution catalysis in MoS2 nanosheets by incorporation of a metal phase,J. Mater. Chem. A,2015,3:24414~24416
14) B. R. Xia,D. Q. Gao,S. P. Shi,L. An,P. X. Xi,D. S. Xue,Hierarchical ultrathin Mo(SxSe1−x)2 nanosheetswith tunable ferromagnetism and efficienthydrogen evolution reaction activity: towardsdefect site effect,CrystEngComm,2015,17:6420~6424
13) B. R. Xia,D. Q. Gao*,S. P. Shi,Y. G. Liu,P. T. Liu,Zigzag-edge related ferromagnetism in MoSe2 nanoflakes,Phys.Chem.Chem.Phys,2015,17:32505~32510
12) D. Q. Gao, Z. P. Zhang, Y. Li, B. R. Xia, S. P. Shi and D. S. Xue, Abnormal room temperature ferromagnetism in CuO–ZnO heterostructures: interface related or not?, Chem. Commun., 51, 1151, 2015.
11)D. Q. Gao, Q. Xu, J. Zhang, Z. L. Yang, M. S. Si,* Z. J. Yan and D. S. Xue*,Defect-related ferromagnetism in ultrathin metal free g-C3N4 nanosheets, Nanoscale, 6, 2577, 2014.
10) D. Q. Gao, Z. P. Zhang, Q. Xu, J. Zhang, Z. J. Yan, J. Yao, and D. S. Xue*, Room temperature ferromagnetism in CuO/Cu2O microspheres: Towards interface effect, Appl. Phys. Lett., 104, 022406, 2014 .
9) D. Q. Gao, Q. X. Xue, X. Z. Mao, W. X. Wang, Q. Xu and D. S. Xue*, Ferromagnetism in ultrathin VS2 nanosheets, J. Mater. Chem. C, 1, 5909, 2013.
8) J. Zhang, D. Q. Gao*, M. S. Si, Z. H. Zhu, G. J. Yang, Z. H. Shi and D. S. Xue*, Origin of the unexpected room temperature ferromagnetism: formation of articial defects on the surface in NaCl particles, J. Mater. Chem. C, 1, 6216, 2013.
7) D. Q. Gao, Z. P. Zhang, Z. L. Yang, and D. S. Xue*, Interface mediated ferromagnetism in bulk CuO/Cu2O composites, Appl. Phys. Lett., 101, 132416, 2012.
5) D. Q. Gao, G. J. Yang, Z. H. Zhu, J. Zhang, Z. L. Yang, Z. P. Zhang and D. S. Xue*, One-step synthesis of open-cell Ni foams by annealing the Ni2+-based precursor in air, J. Mater. Chem., 22, 9462, 2012.
5) D. Q. Gao, G. J. Yang, J. Zhang, Z. H. Zhu, M. S. Si, and D. S. Xue, d0 ferromagnetism in undoped sphalerite ZnS nanoparticles, Appl. Phys. Lett., 99, 052502, 2011.
4)Y. W. Ma, Y. H. Lu, J. B. Yi, Y. P. Feng,T. S. Herng, X. Liu, D. Q. Gao, D. S. Xue, J. M. Xue, J. Y. Ouyang, J. Ding, “Room temperature ferromagnetism in Teflon due to carbon dangling bonds”, Nat. Commun. 2011, 3, 727.
3)D. Q. Gao, J. Y. Li, Z. X. Li, Z. H. Zhang, J. Zhang and D. S. Xue*, Defect-Mediated Magnetism in Pure CaO Nanopowders, J. Phys. Chem. C, 114, 11703, 2010.
2)D. Q. Gao, J. Zhang, G. J. Yang, J. L. Zhang, Z. H. Zhang and D. S. Xue*, Ferromagnetism in ZnO Nanoparticles Induced by Doping of a Nonmagnetic Element: Al, J. Phys. Chem. C, 114, 13477 , 2010.
1)D. Q. Gao, G. J. Yang, J. Y. Li, J. Zhang, J. L. Zhang, and D. S. Xue*, Room-Temperature Ferromagnetism of Flowerlike CuO Nanostructures, J. Phys. Chem. C, 114,18347, 2010.