1) critical volume ratio
临界体积比
1.
The effective dielectric constants ( ff) of three structures , namely , face-centred-cubic (fcc ) , body-centred-tetragonal (bct ) and hexagonal close packed (hcp) were calculated , and the specific values of the effective dielectric constants over the critical volume ratios of these structures were compared.
计算了体心四方、六角密堆积、面心立方三种结构的有效介电常数,通过比较上述三种结构的有效介电常数与其临界体积比的比值,证明了电流变液由液相向固相转化后所形成的基态结构为体心四方。
2) critical volume
临界体积
1.
Prediction of the critical volume of alkenes using a quantitative structure property relationship;
应用QSPR方法预测烯烃的临界体积
2.
The quantitative structure-property relationship(QSPR) of structurally diverse organic compounds and their critical volumes was studied using molecule modeling and the stepwise selection regression method.
采用分子模拟和多元线性回归方法,研究了有机物临界体积的定量结构-性质关系(QSPR)。
3.
A new method based on elements and chemical bonds was developed for estimating critical volume of organic compounds.
提出了一种基于元素和化学键的估算有机物临界体积的新方法。
3) supercritical volume
超临界体积
4) critical volume fraction
临界体积分数
1.
An equation of the critical volume fraction, fpc, of particle-reinforcement in a composite, including particle size, yield strength of the matrix, dissipation work in the vicinity of the particles and the width of the interface zone, has been educed by the energy theory on the basis of the types of microscopic failure of the composite.
根据颗粒增强复合材料微观失效方式,从能量角度推导颗粒增强体临界体积分数表达式,该表达式包括增强体颗粒尺寸、基体屈服强度、增强体颗粒附近形变耗散功和界面区宽度等与颗粒增强体临界体积分数之间的关系。
5) Supercritical fluid deposition
超临界流体沉积
1.
Composite preparation of nano Cu/SBA15 by supercritical fluid deposition
超临界流体沉积法制备纳米Cu/SBA-15复合材料
2.
To synthesize a nano-catalyst by using supercritical fluid deposition,it.
由于超临界流体所特有的溶解性和渗透性,采用超临界流体沉积法制备复合纳米材料,特别是制备复合纳米催化剂有许多独到之处,相应的研究工作在国内外得到了广泛开展。
3.
Ag/SBA-15 nanocomposite was prepared by supercritical fluid deposition(SCFD) method,with AgNO3 as the precursor and ethanol or glycol as the cosolvent.
用超临界流体沉积法以无机盐为前驱物制备纳米复合材料。
6) critical molar volume
临界摩尔体积
补充资料:临界体积
临界体积 critical volume 维持裂变链式反应所需的核燃料或反应堆的体积。又称中肯体积。核裂变放出2~3个中子,放出的中子可继续引起核裂变,也可能被吸收而不发生裂变,也可能逸出裂变物质。为了维持裂变链式反应,要求裂变过程得到的中子数(即后一代中子数)同引起裂变的中子数(即前一代中子数)的比值,称为中子增殖系数,k≥1。相应于k=1的核燃料或反应堆的体积就是临界体积。当不是临界体积时,不会发生持续的裂变链式反应,有利于裂变燃料的贮存;当超过临界体积,则可发生持续的裂变反应。临界体积是核裂变技术中的重要参数。临界体积的大小取决于裂变反应中的平均裂变中子数、裂变燃料的纯度以及裂变装置的类型、结构。 |
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