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1) Carbon nanofibers
纳米炭纤维
1.
The paper introduces the new technique of electroless copper deposition on the carbon nanofibers directly under absence of palladium as catalyzer.
研究了不用贵重金属钯催化,直接在纳米炭纤维上化学镀铜的新方法。
2.
Vapor grown carbon nanofibers(VGCNFs) were prepared by catalytic decomposition of benzene using Fe as catalysts and Micro-coiled carbon nanofibers(MCCNFs) were prepared by catalytic decomposition of acetylene using Ni as catalyst.
研究了以Fe或 Ni为催化剂采用有机物催化热解法制备的纳米炭纤维的形貌和结构,发现在 两种情况下纳米炭纤维的生长机理完全不同:以Fe为催化剂纳米炭纤维基本符合气-液-固(VLS)催 化生长机制(也称溶解扩散机制);而以Ni为催化剂纳米炭纤维则符合固相催化生长机制。
3.
Carbon nanofibers with diameters in the range of 100nm to 300nm were obtained by stabilizing and carbonizing electrospun polyacrylonitrile (PAN) precursors.
通过稳定化、炭化静电纺制的聚丙烯腈(PAN)前驱体纤维制备了直径为100nm~300nm的纳米炭纤维。
2) Carbon nanofibre
炭纳米纤维
3) activated carbon nano fiber
纳米活性炭纤维
1.
The main properties,processes of producing and optimum conditions and new development of activated carbon nano fiber described and theirstatus quo and development tendency at home and abroad have been presented and for future development of application and marked demand are evaluated.
介绍了纳米活性炭纤维的性能、生产的主要技术路线与最佳的操作条件及有关进展情况。
4) activated carbon nanofiber
活性炭纳米纤维
1.
Preparation of PAN-based activated carbon nanofiber and study on its adsorbability to gold;
PAN基活性炭纳米纤维的制备及其对金的吸附研究
5) Porous carbon nanofiber
多孔炭纳米纤维
6) carbon nanofibers/carbon nanotubes
纳米炭纤维/纳米碳管
1.
In order to select suitable catalyst from four metals(Fe、Co、Ni、Mo)to synthesize carbon nanofibers/carbon nanotubes on carbon fibers,by the impregnation-reduction method and chemical vapor deposition method were used four metal—salts separately as catalyst precursor,CO as carbon source,H_2 as reduction gas,N_2 as carrier gas.
为了选择合适的催化剂,来催化炭纤维生长纳米炭纤维/纳米碳管,分别以Fe、Co、Ni和Mo的金属盐为催化剂前驱体,H_2为还原气体,N_2为载气,采用浸渍—还原法在炭纤维表面制备纳米催化剂颗粒,再以CO为碳源,催化热解生长纳米炭纤维/纳米碳管。
2.
In order to in situ growing carbon nanofibers/carbon nanotubes on carbon fibers for further investigating the application of carbon nanofibers/carbon nanotubes in C/C composites,nano-nickel catalyst particles were coated on the carbon fibers' surfaces by KOH-impregnation-reduction method.
为了催化炭纤维原位生长纳米炭纤维/纳米碳管,研究纳米炭纤维/纳米碳管在炭/炭复合材料中的应用,采用KOH-浸渍-还原法在炭纤维上制备纳米催化剂颗粒。
3.
In order to grow carbon nanofibers/carbon nanotubes on carbon fibers,and further investigate their effect on the interface microstructure and thermal conductivity of C/C composites,nano Ni catalyst particles were coated on the surfaces of carbon fibers by impregnation-reduction method using Ni(NO3)2 as catalyst precursor,H2 as reduction gas and N2 as carrier gas.
为了在炭纤维表面原位生长纳米炭纤维/纳米碳管,研究它对炭/炭复合材料微观界面结构和导热性能的影响,以硝酸镍为催化剂前驱体,H2为还原气体,N2为载气,采用浸渍-还原技术在炭纤维表面制备纳米Ni催化剂颗粒。
补充资料:看纺织印染中应用纳米材料和纳米技术
纺织印染中应用纳米材料和纳米技术时,除了要解决纳米材料的制备技术之外,重要的是要解决好纳米材料的应用技术,其中关键问题是使纳米粒子和纺织印染材料的基本成分(即聚合物材料)之间处于适当的结合状态。印染中,纳米粒子在聚合物基体中的分散和纳米粒子在聚合物表面的结合是主要的应用技术问题。 制备聚合物/无机纳米复合材料的直接分散法,适用于各种形态的纳米粒子。印染中纳米粒子的使用一般采用直接分散法。但是由于纳米粒子存在很大的界面自由能,粒子极易自发团聚,利用常规的共混方法不能消除无机纳米粒子与聚合物基体之间的高界面能差。因此,要将无机纳米粒子直接分散于有机基质中制备聚合物纳米复合材料,必须通过必要的化学预分散和物理机械分散打开纳米粒子团聚体,将其均匀分散到聚合物基体材料中并与基体材料有良好的亲和性。直接分散法可通过以下途径完成分散和复合过程: 高分子溶液(或乳液)共混:首先将聚合物基体溶解于适当的溶剂中制成溶液(或乳液),然后加入无机纳米粒子,利用超声波分散或其他方法将纳米粒子均匀分散在溶液(或乳液)中。有人将环氧树脂溶于丙酮后加入经偶联剂处理过的纳米TiO2,搅拌均匀,再加入 40wt%的聚酰胺后固化制得了环氧树脂/TiO2纳米复合材料。还有人将纳米SiO2粒子用硅烷偶联剂处理后,改性不饱和聚酯。 熔融共混:将纳米无机粒子与聚合物基体在密炼机、双螺杆等混炼机械上熔融共混。如将PMMA和纳米SiO2粒子熔融共混后,双螺杆造粒制得纳米复合材料。又如利用偶联剂超声作用下处理纳米载银无机抗菌剂粒子,分散制得PP/抗菌剂、PET/抗菌剂、PA/抗菌剂等复合树脂,然后经熔融纺丝工艺加工成抗菌纤维。研究表明,将经过表面处理的纳米抗菌剂粒子通过双螺杆挤出机熔融混炼,在聚合物中可以达到纳米尺度分散,获得了具有良好综合性能的纳米抗菌纤维,对大肠杆菌、金黄色葡萄球菌的抗菌率达到95%以上(美国AATCC-100标准)。 机械共混:将偶联剂稀释后与碳纳米管混合,再与超高分子量聚乙烯(UHMWPE)混合放入三头研磨机中研磨两小时以上。将研磨混合物放入模具,热压,制得功能型纳米复合材料。 聚合法:利用纳米SiO2粒子填充(Poly(HEMA))制备了纳米复合材料。纳米SiO2粒子首先被羟乙基甲基丙烯酸(HEMA)功能化,然后与HEMA单体在悬浮体系中聚合。还有利用SiO2胶体表面带酸性,加入碱性单体4-乙烯基吡咯进行自由基聚合制得包覆型纳米复合材料。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条
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