1) buffer menstruum
缓冲溶媒
2) buffer solution
缓冲溶液
1.
The effects of the buffer solution in treatments after dyeing and printing;
印染后处理中缓冲溶液的作用
2.
Teaching and analysis of calculating pH Value of buffer solution;
缓冲溶液pH值计算的教学与解析
3.
In order to theoretically elucidate the mechanism of absorption and desorption of sulfur dioxide by citrate solution and provide theoretical instruction for experiments and industrial application, the influence of initial pH, distribution coefficient, buffer index and buffer capacity on the properties of the buffer solution were studied in this work.
为了从理论上阐明柠檬酸盐溶液吸收和解吸二氧化硫的机理,为脱硫实验和工业应用提供理论指导,本文应用多元缓冲溶液理论和计算机数值计算方法相结合,通过对柠檬酸盐溶液吸收二氧化硫过程中形成的柠檬酸-柠檬酸钠-亚硫酸多元缓冲溶液体系的研究,从理论上分析和计算了多元缓冲溶液的初始pH值、分布系数、缓冲指数和缓冲容量对缓冲溶液性质的影响。
3) buffer
[英]['bʌfə(r)] [美]['bʌfɚ]
缓冲溶液
1.
A 1-D mathematical model,including the electrical potential distribution equation,the buffer concentration equation,as well as the sample electromigration and diffusion equation,is developed through proper simplifications and assumptions to study the sample stacking process in capillary electrophoresis.
本文通过合理的简化和假设,把毛细管中电堆积富集过程中所涉及的主要变量根据电势分布方程、缓冲溶液的浓度方程和样品粒子的质量传输方程进行耦合求解,建立了一个一维的数学模型,并应用有限元的方法对该模型进行了求解。
2.
Sample stacking in capillary electrophoresis can concentrate sample species through the electrical field strength gradient caused by the inhomogeneous buffer concentration field in capillary.
毛细管电泳样品电堆积富集是一种通过缓冲溶液浓度的差异在毛细管中形成电场强度梯度,从而对样品进行浓缩的富集技术。
3.
A 1-D mathematical model including electrical potential distribution equation,buffer concentration equation,as well as sample electromigration and diffusion equation was developed through proper simplification and assumption to study sample stacking process in microfluidic chips.
通过合理的简化和假设,建立了一个包括电势分布方程、缓冲溶液浓度方程和样品粒子电迁移扩散方程的一维数学模型,并应用有限元方法对该模型进行了求解。
5) streaming media buffer
流媒体缓冲
6) Solvent-riffle drum
溶剂缓冲罐
补充资料:非极性溶媒
分子式:
CAS号:
性质:由非极性分子所构成的溶剂,此类溶剂不形成离子化的溶剂。根据非极性化合物较易溶解于非极性溶剂中的溶解度规律,多数有机化合物为非极性或极性较小的化合物,较易溶于非极性溶剂中,如烷烃、苯等为典型的非极性溶媒,它们较多用于有机化合物的萃取、分离、纯化和分析等。
CAS号:
性质:由非极性分子所构成的溶剂,此类溶剂不形成离子化的溶剂。根据非极性化合物较易溶解于非极性溶剂中的溶解度规律,多数有机化合物为非极性或极性较小的化合物,较易溶于非极性溶剂中,如烷烃、苯等为典型的非极性溶媒,它们较多用于有机化合物的萃取、分离、纯化和分析等。
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