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Crystallization: A Novel Acoustomicrofluidic Nebulization Technique Yielding New Crystallization Morphologies (Adv. Mater. 3/2018)
Advanced Materials ( IF 29.4 ) Pub Date : 2018-01-15 , DOI: 10.1002/adma.201870018 Heba Ahmed 1 , Lillian Lee 1 , Connie Darmanin 2 , Leslie Y. Yeo 1
Advanced Materials ( IF 29.4 ) Pub Date : 2018-01-15 , DOI: 10.1002/adma.201870018 Heba Ahmed 1 , Lillian Lee 1 , Connie Darmanin 2 , Leslie Y. Yeo 1
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New crystal morphologies, previously undiscovered, for both organic and inorganic materials are obtained by Leslie Y. Yeo and co‐workers, as discussed in article number 1602040, as a consequence of the unique intermediate evaporation rate regime to which aerosol droplets, generated from a microfluidic nebulization platform utilizing a recently discovered novel class of hybrid surface and bulk acoustic waves, are subjected.
中文翻译:
结晶:产生新结晶形态的新型声微流雾化技术(Adv。Mater。3/2018)
如文章编号1602040所述,Leslie Y. Yeo和他的同事获得了有机和无机材料的新晶体形态,这是以前未发现的,这是由于独特的中间蒸发速率机制所产生的气溶胶液滴是由微流体雾化平台,利用最近发现的新型混合表面和体声波的一类。
更新日期:2018-01-15
中文翻译:
结晶:产生新结晶形态的新型声微流雾化技术(Adv。Mater。3/2018)
如文章编号1602040所述,Leslie Y. Yeo和他的同事获得了有机和无机材料的新晶体形态,这是以前未发现的,这是由于独特的中间蒸发速率机制所产生的气溶胶液滴是由微流体雾化平台,利用最近发现的新型混合表面和体声波的一类。
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