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Porous Materials: Direct Laser Writing of Low‐Density Interdigitated Foams for Plasma Drive Shaping (Adv. Funct. Mater. 43/2017)
Advanced Functional Materials ( IF 18.5 ) Pub Date : 2017-11-15 , DOI: 10.1002/adfm.201770257
James S. Oakdale 1 , Raymond F. Smith 1 , Jean-Baptiste Forien 1 , William L. Smith 1 , Suzanne J. Ali 1 , Leonardus B. Bayu Aji 1 , Trevor M. Willey 1 , Jianchao Ye 1 , Anthony W. van Buuren 1 , Matthew A. Worthington 1 , Shon T. Prisbrey 1 , Hye-Sook Park 1 , Peter A. Amendt 1 , Theodore F. Baumann 1 , Juergen Biener 1
Affiliation  

James S. Oakdale, Juergen Biener, and co‐workers report 3D‐printing of low density foams with submicrometer features in article number 1702425. The foam is successfully applied in plasma drive shaping: A plasma shock wave travels through the foam before impinging upon and ramp compressing an aluminum sample to pressures of over 50 GPa. The 3D printed foam helps to smoothen and shape the plasma piston drive, thereby ensuring uniform compression.
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中文翻译:

多孔材料:用于等离子驱动整形的低密度叉指式泡沫的直接激光写入(高级功能材料,第43/2017页)

James S. Oakdale,Juergen Biener及其同事报告了编号为1702425的具有亚微米级特征的低密度泡沫的3D打印。该泡沫已成功应用于等离子驱动成型:等离子冲击波穿过泡沫传播,然后撞击并撞击斜面将铝样品压缩到超过50 GPa的压力。3D打印的泡沫有助于使等离子活塞驱动装置平滑和成形,从而确保均匀的压缩。
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更新日期:2017-11-15
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