李超然 研究员-尊龙凯时

发布时间:2020-04-28访问量:10431


李超然  研究员

 

教育经历:

2006/09-2010/07,厦门大学,化学化工学院,化学系,理学学士

2010/09-2015/07,中国科学院福建物质结构研究所,理学博士


工作经历:

2015/12-2020/04,苏州大学,功能纳米与软物质研究院,博士后

2020/04-2024/07,苏州大学,功能纳米与软物质研究院,副研究员

2024/07-至今,苏州大学,功能纳米与软物质研究院,研究员


所在课题组:

何乐教授课题组


尊龙凯时的联系方式:

江苏省苏州市工业园区仁爱路199号,909-3325

邮箱:crli@suda.edu.cn

办公电话:0512-65880226


研究领域:

光催化二氧化碳高值转化


代表性研究成果:

自2013年以来,从事纳米结构的设计、可控合成及催化应用探索。目前已在nat. energy,adv. mater., angew.chem. int. ed., acs nano, adv.sci.等化学、材料领域高水平期刊上发表50余篇学术论文。


近年来代表性论文:

  1. yu, k.#; feng, k.#; cai m.; li, h.; zhou y.; shen j.; liu s.; zhu z.; sohail m.; tolstoy v.; an, x.*;li, c.*; he, l.*, nature-inspired nanoarray catalyst towards balanced heat and mass transport in photothermal catalysis, acs nano, in press.

  2. zhou, y.; li. c.*; wang, z.; liu, s.; hu, x.; zhang j.; dong, x.; zhu, z.; feng, k.; an, x.*;he, l.*,enhanced methanol production through photo-assisted co2 hydrogenation using au@in2o3 core-shell structures, chemnanomat, 2025, e202500129.

  3. liu, s.#; wu, z.#; zhu, z.#; feng, k.; zhou, y.; hu, x.; huang, x.; zhang, b.; dong, x.; ma, y.; nie, k.; shen, j.; wang, z.; he, j.; wang, j.; ji, y.; yan, b.; zhang, q.; genest, a.; zhang, x.; li, c.*; wu, b.; an, x.*;rupprechter, g.; he, l.*, quantifying the distinct role of plasmon enhancement mechanisms in prototypical antenna-reactor photocatalysts, nat. commun., 2025, 16, 2245.

  4. 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, 2025, 19, 1832-1844.

  5. 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, 16, 70656-70664.

  6. chu, m.#; yan, p.#; zhou, y.#; lou, x.; li, c.*; cao, m.*; he, l.; zhang, q.; chen, j.*, plasmonic copper-ruthenium superstructure for ecient photothermal conversion and plastic recycling, adv. funct. mater., 2024, 2417644.

  7. 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.

  8. 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.

  9. 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.

  10. 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.

  11. 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 eects of plasmonic cluster catalysts through aggregated nanostructures, green chem., 2024, 26, 6994-7001.

  12. 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.

  13. 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.

  14. 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.

  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.

  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.

  17. xi, y.#; cai, m.#; wu, z.; zhu, z.; shen, j.; zhang c.; tang, r.; an, x.*; li, c.*; he, l.*, identication of photochemical effects in ni-based photothermal catalysts, chinese j. struct. chem., 2023, 42, 100071.

  18. 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.

  19. 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.

  20. 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.

  21. 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.

  22. 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.

  23. 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.

  24. 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, 33, 2108727.

  25. 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 materials lett., 2021, 3, 1652–1659.

  26. 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.

  27. 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.

  28. 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. a.*; zhang, x.*; he, l.*, niobium and titanium carbides (mxenes) as superior photothermal supports for co2 photocatalysis. acs nano, 2021,15, 5696–5705.

  29. lou, d.#; xu, a. b.#; 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.

  30. lou, d.#; zhu, z.#; xu, y.-f.#; li, c.*; feng, k.; zhang, d.; lv, k.; wu, z.; zhang, c.; ozin, g. a.*;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.

  31. zhang, c.#; wu, z.#; chen, z.; pan, l.*; li, j.; xiao, m.; wang, l.*; li, h.; huang, z.; xu, a.-b.;li, c.*; he, l., photonic nanostructures of nanodiscs with multiple magneto-optical properties. j. mater. chem. c, 2020, 8, 16067–16072.

  32. fang, y.#; lv, k.#; li, z.; kong, n.; wang, s.; xu, a. b.; wu, z.; jiang, f.; li, c.*; ozin, g. a.*; he, l.*, solution–liquid–solid growth and catalytic applications of silica nanorod arrays. adv. sci., 2020, 2000310.

  33. 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.

  34. 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.

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

  36. 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.

  37. 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.

  38. 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, g. a.*; zhang, x.*, single-stimulus-induced modulation of multiple optical properties. adv. mater., 2019, 31, 1900388.

  39. 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.

  40. zhang, s.#; li, c.#; yu, y.; zhu, z.; zhang, w.; tang, r.; sun, w.; xie, w.; li, y.; yu, j.; 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.

  41. li, c.; zhang, s.; zhang, b.; liu, j.; zhang, w.; solovev, a. 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.


主持的主要研究项目:

1. 国家自然科学基金面上项目,no. 52272229,主持,在研。

2. 国家自然科学基金青年基金,no. 21902113,主持,已结题。

3. 中国博士后科学基金面上资助(第61批),2017m611893,主持,已结题。




 


责任编辑:杨娟

 


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