納米碳管 的英文怎麼說

中文拼音 [tànguǎn]
納米碳管 英文
carbon nanotube
  • : Ⅰ動詞1 (收進來; 放進來) receive; admit 2 (接受) accept; take in 3 (享受) enjoy; take deligh...
  • : Ⅰ名詞1. (稻米) rice 2. (泛指去殼或皮的可吃的種子) shelled or husked seed 3. (姓氏) a surname Ⅱ量詞(公制長度的主單位) metre
  • : 名詞[化學] (非金屬元素) carbon (c)
  • : Ⅰ名詞1 (管子) pipe; tube 2 (吹奏的樂器) wind musical instrument 3 (形狀似管的電器件) valve;...
  • 納米 : aalbert
  1. Applications of nm carbon pipe in the field of biomedicine engineering

    納米碳管在生物醫學工程領域中的應用
  2. Carbon nanotubes modified amperemetric glucose biosensor

    納米碳管葡萄糖生物傳感器的研究
  3. The present status of activated carbon fibers, carbon nanotubes and expansile graphites as the electrode materials for electrical double - layer capacitors were discussed respectively

    對目前已用做電雙層電容器電極材料的活性纖維、納米碳管和膨脹性石墨的研究情況分別做了論述。
  4. Electronic transport properties of single - wall carbon nanotube with pentagon - heptagon - pair defect

    七邊形缺陷的單壁納米碳管的輸運性質研究
  5. The carbon nanotubes ( cnts ) are attractive materials for electrodes of supercapacitors due to their superb characteristics : chemical stability, low mass density, low resistivity, and large specific surface area

    納米碳管導電性好、比表面積大、微孔集中在一定范圍內,從理論上講是製作超級電容器的理想材料。
  6. Because of novel physical and chemical characteristics, carbon nanotubes are widely used as new sensing materials or modified materials. this paper mainly introduced the characteristic study of biosensors and gas sensors modified by carbon nanotubes. with large aspect ratio, carbon nanotubes have excellent biocatalysis

    納米碳管具有新穎的物理化學特性,為傳感器提供了新敏感或修飾材料,將其用於生物酶傳感器和氣敏傳感器,能夠使傳感器具有更好的敏感性。
  7. While still not evidenced in our experiment, liquid - phase doping of ammonium molybdate solution has been broadly agreed to be able to significantly increase the yield of swnts. we have developed another doping method, solid - phase doping of metal molybdenum at elevated temperature, and discovered that sol - gel prepared catalyst with such doping can be used to grow multi - wall carbon nanotube bundles in a very large scale

    對催化劑進行摻鉬處理表明,它可顯著提高催化劑催化裂解甲烷合成納米碳管的能力:作者在高溫下進行了催化劑摻入金屬鉬的實驗,得到了一種性能優異的催化劑,以此制備的多壁納米碳管的呈束狀分佈,所得的粗產物與催化劑之間的重量比達15倍以上。
  8. The hydrogen source used is high purity of 99. 9999 %. for comparison, the annealing treatments were processed under ambient pressure in air and nitrogen atmosphere respectively

    在kno3溶液中進行液相攙雜的納米碳管,其儲氫能力明顯提高,並且隨摻雜濃度增加而提高。
  9. Kno3 solutions ( 0. 1 mol / l and 1. 0 mol / l ) were used to dope carbon nanotubes. the results show that mwnts annealed in nitrogen adsorbed more hydrogen than those annealed in air

    室溫下納米碳管吸附的氫氣不能完全脫附,說明納米碳管的吸氫方式包括物理吸附和化學吸附,其中化學吸附比較難于釋放。
  10. A carbon nanotube - based normal on under - gate field emission display panel

    一種基於納米碳管的常開型后柵極場致發射顯示板
  11. Ammonia played a critical role in the vertical alignment of cnts, and the possible reason was that in 850 the atomic hydrogen decomposed from ammonia reacted with amorphous carbon to form volatile products to keep the metal surface clean, and mechanical leaning against neighboring tu bes established a morphology of vertical alignment

    當基體為單晶硅、催化劑鎳膜厚度為20nm 、氨氣氣氛、生長溫度為850時,得到了定向生長的納米碳管。其原因可能是850時氨氣分解的氫原子和無定形炭生成了易揮發物質,從而保持催化劑的活性使納米碳管依靠相鄰之間的斥力定向生長。
  12. This kind of catalyst was very fine, with strong interaction between the support and the active component particle, and high dispersion of such particles on the surface of the support. yield of carbon nanotubes can also be improved greatly by the doping of molybdenum to catalyst

    本文所採用的檸檬酸法瞬時燒爆工藝制備的催化劑,顆粒小,載體與活性組分接觸好,活性組分分散均勻,可望實現單壁納米碳管的大規模製備。
  13. Effect of moulding techniques on electro - adsorption desalination of carbon nanotube electrodes

    納米碳管電極成型工藝對其電吸附脫鹽性能影響的研究
  14. The development of research on perovskite materials doped with ions and particles, sol - gel technique and sol - gel processing of pbtio3 ( pt ) based materials were intensively reviewed. the luminescence theory of rare earth ions and the properties of carbon nanotube ( cnt ) were introduced briefly

    本文全面回顧了離子和微粒摻雜改性鈣鈦礦相鐵電材料的研究進展,總結了溶膠凝膠技術在制備此類材料中的應用,並簡要介紹了稀土離子發光機理和納米碳管的性能。
  15. In this paper we investigate the effect of intershell coupling effect to nonlinear photoluminescence in multiwalled carbon nanotubes

    摘要研究了耦合效應對多壁納米碳管非線性光致發光的影響。
  16. The prospect of mwnt ' s potential application for the negative electrode of rechargeable battery was also discussed

    最後展望了納米碳管作為可充式電池負極的可能性。
  17. It is very important to produce carbon nanotubes on large scale with a relative low cast for their potential applications. three methods are expatiated : " floating catalyst ", " catalyst driven by gases " and " ferrocene vaporizing " in second part of this paper

    我們在700 800攝氏度下用鈷為催化劑以較大產量制備納米碳管,採用了流化床法、催化劑氣動輸運法和二茂鐵蒸發法三種方法。
  18. " floating catalyst " and " catalyst driven by gases " method can synthesize powder of carbon nanotubes on large scale. " vaporizing ferrocene " method can synthesize bulk carbon nanotube array. the production of the first method is 2000g / day, the second one is 500g / day and the third one is loog / day

    流化床法和催化劑氣動輸運法主要產物為納米碳管粉體,分別每天可以制備2000和500克粗產物;二茂鐵蒸發法制備的產物則是定向納米碳管塊體,每天可制備100克納米碳管陣列塊體。
  19. Another possible reason for this phenomenon is that with higher temperature, the mobility near defects of carbon atoms in grown carbon nanotubes would be also elevated, which gave carbon atoms higher mobility and have chance to readjus to decrease or eliminate some defects. a series of pretreatments and modifications including purification, annealing and doping were performed before hydrogen storage experiments carried out at room temperature under modest pressure ( 12mpa )

    在氮氣中進行退火處理納米碳管的儲氫性能高於在空氣中退火的納米碳管,主要原因是在空氣中退火時,納米碳管的表面引入了大量的氧官能團,而氧官能團能夠占據納米碳管的缺陷位,減少了氫的可吸附位置,阻礙氫進入納米碳管,從而降低了納米碳管的儲氫能力。
  20. Abstract : this paper describes the prospect of nanomaterials, the preparing methods of carbon nanotubes, nanozeolites and nano metal cluster particles, the excellent properties of nanomaterials as catalyst supports and catalysts, and the study status of nano supports and nano catalysts applied to catalysis yield in china

    文摘:介紹了材料的發展前景,納米碳管分子篩以及金屬簇粒子的制備方法,材料用作載體或催化劑的優異性能,載體或催化劑的催化應用領域的研究開發概況。
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