何乐 教授-尊龙凯时

何乐

教授 博士生导师

2008年于南京大学获得学士学位，2013年于美国加州大学河滨分校获得化学博士学位。2013年至2015年在加拿大多伦多大学从事博士后研究。2015年9月加入苏州大学功能纳米与软物质研究院，被聘为教授、博士生导师。入选国家级青年人才计划、江苏省“双创计划”、江苏省“333人才工程”第二层次、江苏省优青、江苏省六大人才高峰高层次人才。

email:

office：苏州大学独墅湖校区910楼205办公室

研究领域：

本课题组的研究集中于气相光催化二氧化碳还原，致力于解决现有体系在活性、选择性与稳定性方面存在的不足，加深对光催化机制与反应机理的理解。

主要成果和贡献：

• 在nat. energy、nat. commun.、acc. chem. res、adv. mater.、angew. chem. int. ed.、joule、nano lett.等期刊发表文章110篇，论文总引用6000余次，sci h-index为43。已获授权美国发明专利2项，国内发明专利8项；撰写国际专著三部（章）；受邀担任30余个国际主流学术期刊审稿人。

• 加入苏州大学以来，以通讯作者在nat. energy、nat. commun.、adv. mater.、angew. chem. int. ed.、joule、acs nano等国际杂志发表论文50余篇。

• 1名博士毕业生获江苏省优秀博士论文，1名博士毕业生入选博新计划，5名博士毕业生获江苏省卓越博士后计划

近期获奖与荣誉：

• 2022             江苏省“333人才工程”第二层次

• 2021             2021年中美化学与化学生物学教授联合会 “杰出教授奖”

• 2021             journal of materials chemistry c emerging investigator

• 2020             江苏省优秀青年基金获得者

• 2020             ifam第六届优秀青年学者论坛优秀报告奖

• 2019             江苏省双创团队成员

• 2017             “江苏省六大人才高峰”高层次人才

• 2017             苏州市高新区创业领军人才

• 2016             江苏省双创博士

• 2015             加拿大班廷博士后奖学金

招生方向：

本课题组热忱欢迎有志从事科研工作的本科生、硕士研究生和博士研究生加盟。招生方向包括“无机化学”、“物理化学”、以及“材料学”。欢迎具有化学、材料、或物理背景的同学报考。有疑问请随时联系lehe@suda.edu.cn。

招聘信息：

根据课题组发展需要，现拟招收1-2名从事纳米材料合成与光催化二氧化碳还原研究领域的博士后研究人员，纳米材料、自组装、光催化相关研究方向的申请者优先考虑。待遇优厚，且有机会到国外访学。有意者请发简历至。

selective publications after joining funsom:

1. wu, z.^†; shen, j.^†; li, z.^†; liu, s.; zhou, y.; feng, k.; zhang, b.; zhao, s.; xue, d.; he, j.; yu, k.; zhang, j.; dawson, g.; zhang, q.; huang, l.; li, c.*; an, x.*; chi, l.; zhang, x.*; he, l.*, anisotropic plasmon resonance in ti₃c₂tx mxene enables site-selective plasmonic catalysis, acs nano, 2024, in press. (^†equal contribution)

2. li, c.^†; chen, z.^†; xiao, m.^†; liu, j.*; huang, y.; zhu, z.; liu, y.; pan, l.; an, x.; hua, w.*; he, l.*, magneto-photonic effect of fe₃o₄@sio₂ nanorods for visualizing the direction of magnetic fields with high spatiotemporal resolution, acs appl.mater. interfaces, 2024, in press. (^†equalcontribution)

3. zhang, l.; li, c.; witoon, t.; an, x.*; he, l.*, nano-thermometry in photothermal catalysis, chin. j. struct.chem., 2024, 100456.

4. song, r.^†; zhao, g.^†; restrepo-florez, j. m.; viasus, c. j.; chen, z.; ai, c.; wang, a.; jing, d.; tountas, a. a.; mao, c.; li, c.; shen, j.; cai, g.; qiu, c.; ye, j.; fu, y.; wang, l.; sun, j.; xu, y.-f.; li, z.; nguyen, n. t.; maravelias, c.; he, l.*; zhang, x.*; ozin, g. a.*, ethylene production via photocatalytic dehydrogenation of ethane using lamn_1−xcu_xo₃, nat. energy, 2024, 9, 750-760. (^†equal contribution)

5. li, j.^†; zhang, l.^†; an,x.^†; feng, k.; wang, x.; he, j.; huang, y.; liu, j.; zhang, l.; yan, b.; li, c.*; he, l.*, tuning adsorbate-mediated strong metal-support interaction by oxygen vacancy: a case study in ru/tio₂, angew. chem. int. ed., 2024, 136, e202407025. (^†equal contribution)

6. wu, c.^†; shen, j.^†; an,x.^†; wu, z.; qian, s.; zhang, s.; wang, z.; song, b.; cheng, y.; yan, b.; sham, t.-k.; zhang, x.; li, c.*; feng, k.*; he, l.*, phosphorization-induced “fence effect” on the active hydrogen species migration enables tunable co₂ hydrogenation selectivity, acs catal., 2024, 14, 8592-8601. (^†equalcontribution)

7. chen, z.^†; dong, x.^†; sun, z.; an, x.; li, c.; liu, s.; shen, j.; wu, c.; wang, j.; wang, z.; zhu, z.; zhou, y.; yu, k.; ma, y.; he, j.; feng, k.*; he, l.*; hu, z.*, hierarchical carbon nanocages as superior supports for photothermal co₂ catalysis, acs nano, 2024, 18, 19672-19681. (^†equalcontribution)

8. wu, z.^†; li, z.^†; shen, j.; feng, k.; wu, c.; ji, y.; sohail, m.; an, x.*; li, c.*; he, l.*, mxenes: structure, properties, and photothermal applications, chem. phys. rev., 2024, 5, 031308. (^†equalcontribution)

9. xiao, y.; feng, k.; dawson, g.; tolstoy, v. p.; an, x.*; li, c.*; he, l.*, a feasible interlayer strategy for simultaneous light and heat management in photothermal catalysis, iscience, 2024, 27, 109792.

10. hu, x.^†; zhu, z.^†; zhou, y.^†; liu, s.; wu, c.; wang, j.; shen, y.; yan, t.; zhang, l.; chen, j.; feng, k.; genest, a.; rupprechter, g.; an, x.*; li, c.*; he, l.*, enhanced photochemical effects of plasmonic cluster catalysts through aggregated nanostructures, green chem., 2024, 26, 6994-7001. (^†equalcontribution)

11. wang, j.^†; zhu, z.^†; feng, k.^†; liu, s.; zhou, y.; urooj, i.; he, j.; wu, z.; shen, j.; hu, x.; chen, z.; dong, x.; sohail, m.; ma, y.; chen, j.; li, c.*; an, x.*; he, l.*, anisotropic plasmon resonance enables spatially controlled photothermal and photochemical effects in hot carrier-driven catalysis, chin. j. chem., 2024, 42, 1877-1885. (^†equalcontribution)

12. zhang, l.^†; an, x.^†; feng, k.^†; li, j.; liu, j.; chen, j.; li, c.*; zhang, x.*; he, l.*, non-photochemical origin of selectivity difference between light and dark catalytic conditions, acs appl.mater. interfaces, 2024, 16, 21987-21996. (^†equalcontribution)

13. zhong, b.^†; cai, m.^†; liu, s.; he, j.; wang, j.; feng, k.; tolstoy, v. p.; jiang, l.; li, c.*; an, x.*; he l.*, modulation of the structure-function relationship of the “nano-greenhouse effect” towards optimized supra-photothermal catalysis, chem. asian j., 2024, 19, e202301077. (^†equalcontribution)

14. zhang, c.^†; wu, z.^†; shen, j.; he, l.*; sun, w.*, silicon nanostructure arrays: an emerging platform for photothermal co₂ catalysis, acta phys.-chim. sin., 2024, 40, 2304004. (^†equalcontribution)

15. cai, m.^†; li, c.^†; an, x.^†; zhong, b.; zhou, y.; feng, k.; wang, s.; zhang, c.; xiao, m.; wu, z.; he, j.; wu, c.; shen, j.; zhu, z.; feng,k.; zhong, j.; he, l.*, supra-photothermal co₂ methanation over greenhouse-like plasmonic superstructures of ultra-small cobalt nanoparticles, adv. mater., 2024, 36, 2308859. (^†equalcontribution)

16. zhu, z.^†; tang, r.^†; li, c.*; an, x.*; he, l.*, promises of plasmonic antenna-reactor systems in gas-phase co₂ photocatalysis, adv. sci., 2023, 10, 2302568. (^†equalcontribution)

17. xi, y.^†; cai, m.^†; wu, z.; zhu, z.; shen, j.; zhang c.; tang, r.; an, x.*; li, c.*; he, l.*, identification of photochemical effects in ni-based photothermal catalysts, chin. j. struct.chem., 2023, 42, 100071. (^†equalcontribution)

18. wu, z.^†; shen, j.^†; li, c.; zhang, c.; wu, c.; li, z.; an, x.*; he, l.*, niche applications of mxene materials in photothermal catalysis, chemistry, 2023, 5, 492-510. (^†equalcontribution)

19. wu, z.^†; shen, j.^†; li, c.*; zhang, c.; feng, k.; wang, z.; wang, x.; meira, d.; cai, m.; zhang, d.; wang, s.; chu, m.; chen, j.; xi, y.; zhang, l.; sham, t.; genest, a.; rupprechter, g.; zhang, x.*; he, l.*, mo₂tic₂ mxene-supported ru clusters for efficient photothermal reverse water−gas shift, acs nano, 2023, 17, 1550-1559. (^†equalcontribution)

20. zhong, g.; zhao, r.; shi, y.; li, c.; he, l.*; he, l.; huang, y.*; thermal shock synthesis of carbon nanotubes supporting small-sized rhenium nanoparticles for efficient electrocatalytic hydrogen evolution, rare met., 2023, 42, 2166-2173.

21. zhu, z.^†; feng, k.^†; li, c.*; tang, r.; xiao, m.; song, r.; yang, d.; yan, b.*; he, l.*, stabilization of exposed metal nanocrystals in high-temperature heterogeneous catalysis, adv. mater., 2022, 34, 2108727. (^†equalcontribution)

22. wang, s.^†; zhang, d.^†; wang, w.; zhong, j.; feng, k.; wu, z.; du, b.; he, j.; li, z.; he, l.*; sun, w.*; yang, d.*; ozin, g.*, grave-to-cradle upcycling of ni from electroplating wastewater to photothermal co₂ catalysis, nat. commun., 2022, 13, 5305.

23. zhang, c.^†; kang, q.^†; chu, m.; he, l.*; chen, j.*, solar-driven catalytic plastic upcycling, trendschem., 2022, 4, 822-834.

24. shen, x.; li, c.*; wu, z.; tang, r.; shen, j.; chu, m.; xu, a.; zhang, b.*; he, l.*; zhang, x., rationally designed nanoarray catalysts for boosted photothermal co₂ hydrogenation, nanoscale, 2022, 14, 11568-11574.

25. chen, z.^†; li, h.^†; li, c.*; liu, j.; hua, w.; zhang, x.; zhang, c.; xiao, m.; xu, a.b.; he, l.*; zhang, x.*, shear-induced alignment of low-aspect-ratio nanorods for modulations of multiple optical properties, j.mater. chem. c, 2022, 10, 9478-9483

26. guo, j.^†*; song, r.^†; li, z.; pan, d.; xie, h.; ba, y.; xie, m.; fan, s.; yang, x.; zhang, h.; yu, h.; zhang, s.; du, j.*; he, l.*; wang, l.*, gold decorated hydroxyapatite–ceo₂ enabled surface frustrated lewis pairs for co oxidation, adv. energy sustainabilityres., 2022, 3, 2200106.

27. zhu, z.^†; hu, x.^†; an, x.; xiao, m.; zhang, l.; li, c.*; he, l.*, photothermal catalytic co₂ hydrogenation with high activity and tailored selectivity over monodispersed pd-ni nanoalloys, chem. asian j., 2022, 17, e202200993.

28. shen, j.^†; tang, r.^†; wu, z.; wang x.; chu, m.; cai, m.; zhang, c.; zhang, l.; yin, k.; he, l.*; li, c.*, integrated photothermal nanoreactors for efficient hydrogenation of co₂, trans. tianjin univ., 2022, 28, 236–244.

29. wang, x.; zhu, z.; wu, z.; zhang, c.; chen, z.; xiao, m.; li, c.*; he, l.*, preparation and photothermal catalytic application of powder-form cobalt plasmonic superstructures. j. inorg.mater., 2022, 37, 22-28.

30. cai, m.^†; wu, z.^†; li, z.^†; wang, l.; sun, w.; tountas, a. a.; li, c.; wang, s.; feng, k.; xu, a. b.; tang, s.; tavasoli, a.; peng, m.; liu, w.; helmy, a. s.; he, l.*; ozin, g.*; zhang, x.*, greenhouse inspired supra-photothermalco₂ catalysis, nat. energy, 2021, 6, 807-814. (^†equalcontribution)

31. wu, z.; li, c.*; li, z.; feng, k.; cai, m.; zhang, d.; wang, s.; chu, m.; zhang, c.; shen, j.; huang, z.; xiao, y.; ozin, g.*; zhang, x.*; he, l.*, niobium and titanium carbides (mxenes) as superior photothermal supports for co₂ photocatalysis, acs nano, 2021, 15, 5696-5705.

32. feng, k.; tian, j.; guo, m.; wang, y.; wang, s.; wu, z.; zhang, j.; he, l.*; yan, b.*, experimentally unveiling the origin of tunable selectivity for co₂ hydrogenation over ni-based catalysts, appl.catal., b, 2021, 292, 120191.

33. lou, d.^†; zhu, z.^†; xu, y. f.^†; li, c.*; feng, k.; zhang, d.; lv, k.; wu, z.; zhang, c.; ozin, g.*; he, l.*_; zhang, x., a core-shell catalyst design boosts the performance of photothermal reverse water gas shift catalysis, sci.china mater., 2021, 64, 2212-2220. (^†equalcontribution)

34. tang, r.^†; zhu, z.^†; li, c.*; xiao, m.; wu, z.; zhang, d.; zhang, c.; xiao, y.; chu, m.; genest, a.; rupprechter, g.; zhang, l.; zhang, x.*; he, l.*, ru-catalyzed reverse water gas shift reaction with near-unity selectivity and superior stability, acs materialslett., 2021, 3, 1652-1659. (^†equalcontribution)

35. xiao, m.; liu, j.*; chen, z.; liu, w.; zhang, c.; yu, y.; li, c.*; he, l.*, magnetic assembly and manipulation of janus photonic crystal supraparticles from a colloidal mixture of spheres and ellipsoids, j.mater. chem. c, 2021, 9, 11788-11793.

36. lou, d.^†; xu, a.^†; fang, y.; cai, m.; lv, k.; zhang, d.; wang, x.; huang, y.*; li, c.*; he, l.*, cobalt-sputtered anodic aluminum oxide membrane for efficient photothermal co₂ hydrogenation, chemnanomat, 2021, 7, 1008-1012. (^†equalcontribution)

37. shen, j.^†; wu, z.^†; li, c.*; zhang, c.; genest, a.; rupprechter, g.; he, l.*, emerging applications of mxene materials in co₂ photocatalysis, flatchem, 2021, 28, 100252. (^†equalcontribution)

38. wu, z.; zhang, c.; li, c.*; he, l.*, research progress on magnetically responsive smart optical nanomaterials, materials china, 2021, 40, 1-10.

39. zhang, d.^†; lv, k.^†; li, c.; fang, y.; wang, s.; chen, z.; wu, z.; guan, w.; lou, d.; sun, w.*; yang, d.; he, l.*; zhang, x.*, all-earth-abundant photothermal silicon platform for co₂ catalysis with nearly 100% sunlight harvesting ability, solar rrl, 2021, 5, 2000387. (^†equalcontribution)

40. feng, k.^†; wang, s.^†; zhang, d.^†; wang, l.; yu, y.; feng, k.; li, z.; zhu, z.; li, c.; cai, m.; wu, z.; kong, n.; yan, b.; zhong, j.*; zhang, x.*; ozin, g.*; he, l.*, cobalt plasmonic superstructures enable almost 100% broadband photon efficient co₂ photocatalysis, adv. mater., 2020, 32, 2000014. (^†equalcontribution)

41. fang, y.^†; lv, k.^†; li, z.; kong, n.; wang, s.; xu, a.b.; wu, z.; jiang, f.; li, c.*; ozin, g.*; he, l.*, solution-liquid-solid growth and catalytic applications of silica nanorod arrays, adv. sci., 2020, 7, 2000310. (^†equalcontribution)

42. li, c.^†; zhang, j.^†; wang, s.; zhu, z.; li, h.*; xu, a. b.; yu, y.; wang, x.; yao, j.; wang, l.*; solovev, a. a.; he, l.*, silica nanocapsules with unusual shapes accessed by simultaneous growth of the template and silica nanostructure, chem. mater., 2020, 32, 575-581. (^†equalcontribution)

43. cai, m; li, c.*; he, l.*, enhancing photothermal co₂ catalysis by thermal insulating substrates, raremet., 2020, 39, 881–886.

44. kong, n.; han, b.; li, z.; fang, y.; feng, k.; wu, z.; wang, s.; xu, a. b.; yu, y.; li, c.*; lin, z.*; he, l.*, ruthenium nanoparticles supported on mg(oh)₂ microflowers as catalysts for photothermal carbon dioxide hydrogenation, acs appl. nano mater., 2020, 3, 3028-3033.

45. li, c.^†; yu, y.^†; wang, l.*; zhang, s.; liu, j.; zhang, j.; xu, a.b.; wu, z.; tong, j.; wang, s; xiao, m.; fang, y.; yao, j.; solovev, a. a.; dong, b.; he, l.*, a step-by-step strategy for controlled preparations of complex heterostructured colloids, chem. mater., 2019, 31, 9513-9521. (^†equalcontribution)

46. liu, j.^†; xiao, m.^†; li, c.*; li, h.; wu, z.; zhu, q.; tang, r.; xu, a.b.; he, l.*, rugby-ball-like photonic crystal supraparticles with non-close-packed structures and multiple magneto-optical responses, j.mater. chem. c, 2019, 7, 15042-15048. (^†equalcontribution)

47. zhang, b.; jie, j.*; shao. z.; huang, s.; he, l.*; zhang, x.*, one-step growth of large-area silicon nanowire fabrics for high performance multifunctional wearable sensors, nano res., 2019, 12, 2723-2728.

48. li, h.^†; li, c.^†; sun, w.; wang, y.; hua, w.; liu, j.; zhang, s.; chen, z.; wang, s.; wu, z.; zhu, q.; tang, r.; yu, j.; he, l.*; ozin,a.g.*; zhang, x.*, single-stimulus-induced modulation of multiple optical properties, adv.mater., 2019, 31, 1900388. (^†equalcontribution)

49. li, c.^†; yao, j.^†; huang, y.; xu, c.; lou, d.; wu, z.; sun, w.; zhang, s.; li, y.; he, l.*; zhang, x.*, salt-templated growth of monodisperse hollow nanostructures, j.mater. chem. a, 2019, 7, 1404-1409. (^†equalcontribution)

50. wang, s.; li, c.; chen, z.; zhu, z.; zhu, q.; tang, r.; sun, w.; he, l.*; zhang, x.*, anomalous effect of the aging degree on the ionic permeability of silica shells, rsc adv., 2018, 8, 38499-38505.

51. zhang, s.^†; li, c.^†; zhang, j.; yu, y.; zhou, h.; tang, r.; li, y.; yu, j.; du, x.; he, l.*; zhang, x.*, a general and mild route to highly dispersible anisotropic magnetic colloids for sensing weak magnetic fields, j.mater. chem. c, 2018, 6, 5528-5535. (^†equalcontribution)

52. wang, l.^†; ghoussoub, m.^†; wang, h.; dong, y.; shao, y.; tountas, a.; wood, t.; li, h.; sun, w.; xia, m.; li, y.; wang, s.; jia, j.; qiu, c.; qian, c.; he, l.*; zhang, x.*; ozin, g.*, photocatalytic hydrogenation of carbon dioxide with high selectivity to methanol at atmospheric pressure, joule, 2018,2, 1369-1381. (^†equalcontribution)

53. li, c.; zhang, s.; zhang, b.; liu, j.; zhou, h.; solovev, a.; tang, r.; bao, f.; yu, j.; zhang, q.; lifshitz, y.*; he, l.*; zhang, x.*, local-curvature-controlled non-epitaxial growth of hierarchical nanostructures, angew. chem. int. ed., 2018, 57, 3772-3776.

54. wang, l.^†; cai, m.^†; sun, w.*; he, l.*; zhang, x.*, promoting charge separation in semiconductor nanocrystal superstructures for enhanced photocatalytic activity, adv.mater. interfaces, 2018, 5, 1701694. (^†equalcontribution)

55. zhu, z.^†; zhang, s.^†; li, c.; zhang, j.; yu, j.; du, x.; he, l.*; zhang, x.*, a mechanistic study of silica-etching by hot water, phys. chem. chem. phys., 2018, 20, 1440-1446. (^†equalcontribution)

56. cao, m.^†; liu, q.^†; chen, m.^†; yang, p.; xu, y.; wu, h.; yu, j.; he, l.*; zhang, x.*; zhang, q.*, dispersing hydrophilic nanoparticles in nonaqueous solvents with superior long-term stability, rsc adv., 2017, 7, 25535-25541. (^†equalcontribution)

57. yang, p.^†; li, h.^†; zhang, s.; chen, l.; zhou, h.; tang, r.; zhou, t.; bao, f.; zhang, q.*; he, l.*; zhang, x.*, gram-scale synthesis of superparamagnetic fe₃o₄ nanocrystal clusters with long-term charge stability for highly stable magnetically responsive photonic crystals, nanoscale, 2016, 8, 19036-19042. (^†equalcontribution)

58. sun, w.^†; qian, c.^†; he, l.*; ghuman, k.; wong, a.; jia, j.; o'brien, p.; reyes, l.; wood, t.; helmy, a.; mims, c.; singh, c.; ozin, g.*, heterogeneous reduction of carbon dioxide by hydride-terminated silicon nanocrystals, nat. commun., 2016, 7, 12553. (^†equalcontribution)

59. he, l.*; wood, t.; wu, b.; dong, y.; hoch, l.; reyes, l.; wang, d.; kübel, c.; qian, c.; jia, j.; liao, k.; o'brien, p.; sandhel, a.; loh, j.; szymanski, p.; kherani, n.; sum, t.; mims, c.; and ozin, g.*, spatial separation of charge carriers in in₂o_3-x(oh)_y nanocrystal superstructures for enhanced gas phase photocatalytic activity, acs nano, 2016, 10, 5578-5586.

    
    

    selective publications before joining funsom:

60. he, l.^†; janner, m.^†; lu, q.; wang, m.; ma, h. and yin, y.*, magnetochromatic thin film microplates, adv.mater., 2015, 27, 86-92. (^†equalcontribution)

61. he, l.; wang, m.; zhang, q.; lu, y.; yin, y.*, magnetic assembly and patterning of general nanoscale materials through nonmagnetic templates, nano lett., 2013, 13, 264-271.

62. he, l.; wang, m.; ge, j.; yin, y.*, magnetic assembly route to colloidal responsive photonic nanostructures, acc. chem. res., 2012, 45, 1431-1440.

63. he, l.; hu, y.; wang, m.; yin, y.*, determination of solvation layer thickness byamagneto-photonic approach, acs nano, 2012, 6, 4196-4202.

64. he, l.^†; malik, v.^†; wang, m.; hu, y.; yin, y.*, self-assembly and magnetically induced phase transition of three-dimensional colloidal photonic crystals, nanoscale,2012, 4, 4438-4442. (^†equalcontribution)

65. he, l.; hu, y.; han, x.; lu, y.; lu, z.; yin, y.*, assembly and photonic properties of superparamagnetic colloids in complex magnetic fields, langmuir, 2011, 27, 13444-13450.

66. he, l. and yin, y., “magnetically responsive photonic nanostructures: making color using magnets”, proc. spie 2011, 8031, 80310u2-7.

67. he, l.; hu y.; kim, h.; ge, j.; kwon, s. and yin, y.*, magnetic assembly of nonmagnetic particles into photonic crystal structures, nano lett., 2010, 10, 4708–4714.