共查询到20条相似文献,搜索用时 578 毫秒
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Carlota Oleaga Andrea Lavado Anne Riu Sandra Rothemund Carlos A. Carmona‐Moran Keisha Persaud Andrew Yurko Jennifer Lear Narasimhan Sriram Narasimhan Christopher J. Long Frank Sommerhage Lee Richard Bridges Yunqing Cai Candace Martin Mark T. Schnepper Arindom Goswami Reine Note Jessica Langer Silvia Teissier Jos Cotovio James J. Hickman 《Advanced functional materials》2019,29(8)
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Superstructures: Enzyme‐Driven Hasselback‐Like DNA‐Based Inorganic Superstructures (Adv. Funct. Mater. 45/2017)
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Jae Sung Lee Hyejin Kim Changshin Jo Jaepil Jeong Jeonghyun Ko Sangwoo Han Min Sun Lee Ho‐Young Lee Jeong Woo Han Jinwoo Lee Jong Bum Lee 《Advanced functional materials》2017,27(45)
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John D. Berrigan Tae‐Sik Kang Ye Cai James R. Deneault Michael F. Durstock Kenneth H. Sandhage 《Advanced functional materials》2011,21(9):1537-1537
An aqueous, protein‐enabled (biomimetic), layer‐by‐layer titania deposition process is developed, for the first time, to convert aligned‐nanochannel templates into high‐aspect‐ratio, aligned nanotube arrays with thin (34 nm) walls composed of co‐continuous networks of pores and titania nanocrystals (15 nm ave. size). Alumina templates with aligned open nanochannels are exposed in an alternating fashion to aqueous protamine‐bearing and titania precursor‐bearing (Ti(IV) bis‐ammonium‐lactato‐dihydroxide, TiBALDH) solutions. The ability of protamine to bind to alumina and titania, and to induce the formation of a Ti–O‐bearing coating upon exposure to the TiBALDH precursor, enables the layer‐by‐layer deposition of a conformal protamine/Ti–O‐bearing coating on the nanochannel surfaces within the porous alumina template. Subsequent protamine pyrolysis yields coatings composed of co‐continuous networks of pores and titania nanoparticles. Selective dissolution of the underlying alumina template through the porous coating then yields freestanding, aligned, porous‐wall titania nanotube arrays. The interconnected pores within the nanotube walls allow enhanced loading of functional molecules (such as a Ru‐based N719 dye), whereas the interconnected titania nanoparticles enable the high‐aspect‐ratio, aligned nanotube arrays to be used as electrodes (as demonstrated for dye‐sensitized solar cells with power conversion efficiencies of 5.2 ± 0.4%). 相似文献
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Field‐Effect Transistors: High Performance p‐ and n‐Type Light‐Emitting Field‐Effect Transistors Employing Thermally Activated Delayed Fluorescence (Adv. Funct. Mater. 28/2018)
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Jan Sobus Fatima Bencheikh Masashi Mamada Robert Wawrzinek Jean‐Charles Ribierre Chihaya Adachi Shih‐Chun Lo Ebinazar B. Namdas 《Advanced functional materials》2018,28(28)