买球最好的网站(中国)有限公司

个人简介

教育经历

1999年9月-2003年7月   山东大学化学与化工学院（本科）

2003年9月-2008年7月   山东大学化学与化工学院（硕博连读）

工作经历

2008年7月 至今 买球最好的网站(中国)有限公司

研究方向

“化学---无机化学（硕士生导师、博士生导师）；材料科学与工程---材料物理与化学（硕士生导师）

配位化学，卟啉酞菁化学，光催化，太阳能电池，超分子组装”

代表成果

1. Electron-rich pincer ligand-coupled cobalt porphyrin polymer with single-atom sites for efficient (photo)electrocatalytic CO₂reduction at ultralow overpotential,T. Wang, L. Guo, H, Pei,R. Li*,J. Zhang,T. Peng*,Small.2021,ASAP,DOI: 10.1002/smll.202102957.

2. Ru-pincer complex-bridged Cu-porphyrin polymer for robust (photo)electrocatalytic H₂evolution via single-atom active sites,T. Wang, L. Guo, Z. Jiang, S. Chen, S, Xu, Y. Zhang, J. Zhang,R. Li*, T. Peng*,Adv. Funct. Mater.2021,202107290.

3. Porphyrin conjugated polymer grafted onto BiVO₄nanosheets for efficient Z-scheme overall water splitting via cascade charge transfer and single-atom catalytic sites,J. Wang, L. Xu, T. Wang,R. Li*,Y. Zhang, J. Zhang,T. Peng*,Adv. Energy Mater.2021,11, 2003575.

4. Z-scheme photocatalyst based on porphyrin derivative decorated few-layer BiVO₄nanosheets for efficient visible-light-driven overall water splitting,J. Wang, L. Guo, L. Xu, P. Zeng*,R. Li*, T. Peng*,Nano Res.2021,14, 1294-1304.

5. Porphyrin conjugated polymer with periodic type II-Like heterojunctions and single-atom catalytic sites for broadband-responsive hydrogen evolution,J. Wang, L. Xu, T. Wang, S. Chen, Z. Jiang,R. Li*,Y. Zhang*,T. Peng*,Adv. Funct. Mater.2021,31, 2009819.

6. Porphyrin-based metal−organic frameworks for efficient photocatalytic H₂production under visible-light irradiation,C. Lin, C. Han, H. Zhang, L. Gong, Y. Gao, H. Wang, Y. Bian*,R. Li*, J. Jiang*,Inorg. Chem.2021,60, 3988-3995.

7. Central site regulation of cobalt porphyrin conjugated polymer to give highly active and selective CO2 reduction to CO in aqueous solution,T. Wang, L. Xu, Z. Chen, L. Guo, Y. Zhang,R. Li*, T. Peng*,Applied Catalysis B: Environmental2021,291, 120128.

8. Review of Z-scheme heterojunctions for photocatalytic energy conversion,D. Liu, S. Chen,R. Li*, T. Peng*,Acta Phys.-Chim. Sin.2021,37, 2010017.

9. Facile preparation process of NiCoP−NiCoSe₂nano-bilayer films for oxygen evolution reaction with high efficiency and long duration, T. Wang, X. Liu, Z. Yan, Y. Teng,R. Li*,J. Zhang,T. Peng*,ACS Sustainable Chem. Eng.2020,8, 1240-1251.

10. Asymmetric zinc porphyrin derivatives bearing three pseudo-pyrimidine meso-position substituents and their photosensitization for H₂evolution, P. Zeng, Y. Zheng, S. Chen, H. Liu,R. Li*,T. Peng*,New J. Chem.2020,44, 11237.

11. Efficiently enhanced N₂photofixation performance of sea-urchin-like W₁₈O₄₉microspheres with Mn-doping,Z. Ying, S. Chen, S. Zhang,T. Peng*,R. Li*,Applied Catalysis B: Environmental2019,254, 351-359.

12. Direct Z-scheme 2D/2D photocatalyst based on ultrathin g-C₃N₄and WO₃nanosheets for efficient visible-light-driven H₂generation, D. Liu, S. Zhang, J. Wang,T. Peng*,R. Li*,ACS Appl. Mater. Interfaces2019,11, 27913-27923.

13. Synthesis of an A₂BC-type asymmetric zinc phthalocyanine derivative for efficient visible/near-infrared-driven H₂evolution on g-C₃N₄,P. Zeng, J. Wang, Y. Guo,R. Li*,T. Peng*,Chemical Engineering Journal2019, 373,651-659.

14. Effects of the central metal ions on the photosensitization of metalloporphyrins over carbon nitride for visible-light-responsive H₂production, J. Wang, D. Liu, Q. Liu,T. Peng*,R. Li*, S. Zhou*,Applied Surface Science,2019,464, 255-261.

15. Porphyrin-based conjugated polymers as intrinsic semiconducting photocatalysts for robust H₂generation under visible light,Z. Chen, J. Wang, S. Zhang, Y. Zhang, J. Zhang,R. Li*,T. Peng*,ACS Appl. Energy Mater.2019,2, 5665-5676.

16. Solution-processable Cu(II) phthalocyanine derivative as dopant free hole transport layer for efficient and low-cost rutile TiO₂array-based perovskite solar cells, S. Wu, C. Chen, Q. Liu,T. Peng*,R. Li*,ACS Appl. Energy Mater.2018,1, 5539-5547.

17. Photosensitization of zinc phthalocyanine bearing 15-crown-5 ether moieties on carbon nitride for H₂production: effect of co-existing alkali metal ions, Q. Liu, J. Wang, D. Liu,R. Li*, T. Peng*Journal of Power Sources2018,396, 57-63.

18. Improved photovoltaic performance of perovskite solar cells based on three-dimensional rutile TiO₂nanodendrite array film, C. Chen, S. Wu, J. Wang, S. Chen,T. Peng*,R. Li*,Nanoscale2018,10, 20836-20843.

19. Asymmetric zinc porphyrin derivative-sensitized graphitic carbon nitride for efficient visible-light-driven H₂production, J. Wang, Y. Zheng,T. Peng*, J. Zhang,R. Li*,ACS Sustainable Chem. Eng.2017,5, 7549-7556.

20. Syntheses of asymmetric zinc porphyrins bearing different pseudo-pyridine substituents and their photosensitization for visible-light-driven H2 production activity, Y. Zheng, J. Wang, J. Zhang,T. Peng,R. Li*,Dalton Trans.2017,46, 8219-8228.

21. Synthesis and characterization of an A2BC type phthalocyanine and its visible-light-responsive photocatalytic H₂production performance on graphitic carbon nitride, Y. Guo, S. Song, Y. Zheng,R. Li*,T. Peng*,Dalton Trans.,2016,45, 14071-14079. (Front Cover)

22. Low cost and solution-processable zinc phthalocyanine as alternative hole transport material for perovskite solar cells, S. Wu, Y. Zheng, Q. Liu,R. Li*,T. Peng*,RSC Advances,2016,6, 107723-107731.

23. Effects of the symmetry and carboxyl anchoring group of zinc phthalocyanine derivatives on g-C₃N₄for photosensitized H₂production, S. Song, Y. Guo,T. Peng*, J. Zhang,R. Li*,RSC Advances,2016,6, 77366-77374

24. Preparation of a single-walled carbon nanotube/Cd_0.8Zn_0.2S nanocomposite and its enhanced photocatalytic hydrogen production activity, B. Peng, X. Liu,R. Li*,Eur. J. Inorg. Chem.2016,3204-3211.

25. Synthesis of asymmetric zinc phthalocyanine with bulky diphenylthiophenol substituents and its photovoltaic performance for dye-sensitized solar cells, W. Shi, B. Peng, Y. Guo, L. Lin,T. Peng*,R. Li*J. Photochemistry and photobiology A: Chemistry2016,321, 248-256.

26. New Ni(II) complexes based on N’NN’ pincer ligands: syntheses, structures and B-F cleavage of BF₄^-promoted by a di-cationic Ni(II) center, W. Xiang, Q. Luo, H. Jiang, X. Meng,R. Li,J. Zhang*, T. Peng*,J. Coord. Chem.2016,69, 2353-2363.

27. Effect of carboxyl anchoring groups in asymmetric zinc phthalocyanine with large steric hindrance on the dye-sensitized solar cell performance, W. Shi, B. Peng, L. Lin,R. Li,J. Zhang*, T. Peng*,Materials Chemistry and Physics2015,163, 348-354.

28. Visible/near-infrared-light-induced H₂production over g-C₃N₄Co-sensitized by organic dye and zinc phthalocyanine derivative, X. Zhang, T. Peng*, L. Yu,R. Li, Q. Li, Z. Li,ACS Catal.,2015,5, 504-510.

29. Asymmetric zinc porphyrin-sensitized nanosized TiO₂for efficient visible-light-driven CO₂photoreduction to CO/CH₄, K. Li, L, Lin, T. Peng*, Y. Guo,R. Li, J. Zhang,Chem. Commun,2015,51, 12443-12446.

30. A new route for visible/near-infrared-light-driven H₂production over titania: Co-sensitization of surface charge transfer complex and zinc phthalocyanine, X. Zhang, B. Peng, T. Peng*, L. Yu,R. Li, J. Zhang,J. Power Sources2015,298, 30-37.

31. Investigation of benzo(1,2-b:4,5-b)dithiophene as a spacer in organic dyes for high efficient dye-sensitized solar cell, X. Zhou, X. Li, Y. Liu,R. Li*,K. Jiang*,J. Xia*Organic Electronics2015,25, 245-253.

32. Asymmetric zinc phthalocyanines with large steric hindrance as efficient red/near-IR responsive sensitizer for dye-sensitized solar cells, L. Yu, W. Shi, L. Lin,Y. Guo,R. Li*, T. Peng*,Dyes and Pigments2015,114, 231-238.

33. Theoretical investigation of self-assembled donor–acceptor phthalocyanine complexes and their application in dye-sensitized solar cells, L. Yu, L. Lin,Y. Liu,R. Li*,J. Molecular Graphics and Modelling2015,59, 100-106.

34. Synthesis of zinc phthalocyanine with large steric hindrance and its photovoltaic performance for dye-sensitized solar cells, L. Lin,B. Peng, W. Shi, Y. Guo,R. Li*,Dalton Trans.,2015,44, 5867-5874.

35. Rice-like brookite titania as an efficient scattering layer for nanosized anatase titania film-based dye-sensitized solar cells, J. Xu, K. Li, W. Shi,R. Li,T. Peng*,J. Power Sources2014,260, 233-242.

36. Asymmetry and electronic directionality: a means of improving the red/near-IR-light-responsive photoactivity of phthalocyanine-sensitized carbon nitride, X. Zhang, L. Yu,R. Li*, T. Peng*, X. Li.Catal. Sci. Technol.2014,4, 3251-3260.

37. Efficientof benzo-annelation of asymmetric phthalocyanine on the photovoltaic performance of dye-sensitized solar cells, L. Yu, W. Shi, L. Lin, Y. Liu,R. Li*, T. Peng*.Dalton Trans.,2014,43, 8424-8430.

38. Syntheses of asymmetric zinc phthalocyanines as sensitizer of Pt-loaded graphitic carbon nitride for efficient visible/near-IR-light-driven H₂production,L. Yu, X. Zhang, C. Zhuang, L. Lin,R. Li*, T. Peng*.Phys. Chem. Chem. Phys.,2014,16, 4106-4114.

39. Efficient panchromatic light harvesting with co-sensitization of zinc phthalocyanine and bithiophene-based organic dye for dye-sensitized solar cells, L. Yu, K. Fan, T. Duan, X. Chen,R. Li*, T. Peng*.ACS Sustainable Chem. Eng,2014,2, 718-725.

40. Highly asymmetric phthalocyanine as a sensitizer of graphitic carbon nitride for extremely efficient photocatalytic H₂production under near-infrared light,X. Zhang, L. Yu, C. Zhuang, T. Peng*,R. Li*, X. Li.ACS Catal.,2014,4, 162-170.

41. An efficient binary ionic liquid based quasi solid-state electrolyte for dye-sensitized solar cells,J. Chen,T. Peng*, W. Shi,R. Li,X. Jia.Electrochimica Acta,2013,107, 231-237.

42. Optimization of plastic crystal ionic liquid electrolyte for solid-state dye-sensitized solar cell,J. Chen,T. Peng*, K. Fan,R. Li,X. Jia*.Electrochimica Acta,2013,94, 1-6.

43. A simple preparation method for quasi-solid-state flexible dye-sensitized solar cells by using sea urchin-like anatase TiO₂microspheres, K. Fan,T. Peng*, J. Chen, X. Zhang,R. Li,J. Power Sources2013,222, 38-44.

44. Highly asymmetric phthalocyanine-sensitized solar cells: The effect of coadsorbent and adsorption temperature of phthalocyanine,L. Yu, L. Lin, X. Zhang,R. Li*, T. Peng*, X. Li.Eletctrochimica Acta,2013,111, 344-350.

45. Highly efficient visible/near-IR-light-driven photocatalytic H₂production over asymmetric phthalocyanine-sensitized TiO₂, X. Zhang, L. Yu, C. Zhuang,T. Peng*,R. Li*, X. Li.RSC Advances,2013,3, 14363-14370.

46. Recentdevelopment of dye-sensitized solar cells based on flexible substrates TiO₂, K. Fan,R. Li*, J. Chen, W. Shi, T. Peng*.Sci. Adv. Mater.,2013,5, 1596-1626.

47. Linear perylenetetracarboxylic monoanhydried derivatives for the sensitization of dye-sensitized solar cells, G. Qi,R. Li, L. Wang, X. Li*,J. Photochemistry and photobiology A: Chemistry2012,239, 28-36.

48. Low-cost, quasi-solid-state and TCO-free highly bendable dye-sensitized cells on paper substrate, K. Fan,T. Peng*, J. Chen, X. Zhang,R. Li,J. Mater. Chem.,2012,22, 16121-16126.

49. Highly symmetric tribenzonaphtho-condensed porphyrazinatozinc complex: An efficient near-infrared sensitizer for dye-sensitized solar cells,L. Yu, X. Zhou, Y. Yin, Y. Liu,R. Li*, T. Peng*.ChemPlusChem,2012,77, 1022-1027.

50. Effects of metal oxide modifications on photoelectrochemical properties of mesoporous TiO₂nanoparticles electrodes for dye-sensitized solar cells,T. Peng*, K. Fan,D. Zhao,L. Yu,R. Li*.Chin. J. Chem. Phys.,2012,5, 609-616.

51. Effects of rare earth ions modification on the photoelectrochemical properties of ZnO-based dye-sensitized solar cells,L. Lu,R. Li*, T. Peng*, K. Fan, K. Dai.Renewable Energy,2011,36, 3386-3393.

52. Effects of annealing conditions on the photoelectrochemical properties of dye-sensitized solar cells made with ZnO nanoparticles, L. Lu,R. Li*, K. Fan, T. Peng*.Solar Energy,2010,84, 844-853.