Ultramicropore

The term supermicropores has been proposed for the pores in which adsorption occurs by the secondary process the pores in which the primary process operates would then be termed, simply, micropores (or alternatively ultramicropores, or ultrapores ). 

To ensure a better separation, molecular sieving will act much better This size exclusion effect will require an ultramicroporous (i.e pore size D < 0.7 nm) membrane Such materials should be of course not only defect-free, but also present a very narrow pore size distribution. Indeed if it is not the case, the large (less separative and even non separative, if Poiseuille flow occurs) pores will play a major role in the transmembrane flux (Poiseuille and Knudsen fluxes vary as and D respectively). The presence of large pores will therefore cancel any sieving effect... 

Advanced Materials Experimental membranes have shown remarkable separations between gas pairs such as O2/N2 whose kinetic diameters (see Table 20-26) are quite close. Most prominent is the carbon molecular sieve membrane, which operates by ultramicro-porous molecular sieving. Preparation of large-scale permeators based on ultramicroporous membranes has proven to be a major challenge. 

Further subdivided into ultramicropores and supermicropores (Gregg and Sing, gen. refs.). 

Type VI, corresponding to uniform ultramicroporous sohds, where the pressure at which adsorption takes place depends on surface-adsorbate interactions, and shows isotherms with various steps each corresponding to adsorption on one group of energetically uniform sites. 

Recently, the micropore range has been subdivided into two additional categories very narrow pores or ultramicropores (<0.7 to 1.0 nm), where the enhancement effect is found and supermi-cropores (0.7 to 2.0 nm), which fill the gap between the ultramicropores and mesopore ranges [53, 115], This classification has become widespread, but it only takes into account adsorption effects and ignores the morphology of PS elements and their integrity. 

Spherical particles of various metal phosphate particles can be prepared by precipitation using urea as a homogeneous precipitation agent. Surface-active agents, such as SDS and CTAC, are effective in preparation of uniform-size spherical particles. The formed spherical particles are amorphous and contain OH- and H20, except cobalt phosphate particles with layered structure. These panicles are agglomerates of primary particles, and have pores of different sizes ranging from ultramicropore to mesopore. 

Everett and Powl51 (1976) have developed a pore size distribution model for the slit shaped pores of ultramicroporous carbons. This model has been further elaborated by Horvath and Kawazoe.52... 

Adsorption in ultramicroporous carbon was treated in terms of a slit-potential model by Everett and Powl51 and was later extended by Horvath and Kawazoe.52 They assumed a slab geometry with the slit walls comprised of two infinite graphitic planes. Adsorption occurs on the two parallel planes, as shown in figure 2.7. 

FIGURE 2.19 Progressive change from ultramicropores through supermicropores to mesopores during air activation of glass-like carbon spheres. 

Kaneko K, Setoyama N, and Suzuki T. Ultramicropore characterization by He adsorption. In Rouquerol J, et al., eds. Characterization of Porous Solids III. Studies in Surface Science and Catalysis, vol. 87, the Netherlands Elsevier Science. 1994 pp. 593-602. 

Setoyama N, Kaneko K, and Rodrfguez-Reinoso F. Ultramicropore characterization of microporous carbons by low temperature helium adsorption. J. Phys. Chem., 1996 100(24) 10331-10336. 

FIGURE 8.12 Capacitance in lmol L 1 H2S04 and lmol L 1 TEABF4 in acetonitrile vs. ultramicropore volume for various templated carbons. (Adapted from Vix-Guterl, C., et al., Carbon, 43, 1293, 2005.)... 

The results presented in this section confirm that an adequate pore size is more important than a high surface area for an optimization of the capacitance values. For the production of compact systems, an important objective is to limit as much as possible the useless porosity in order to enhance the volumetric capacity. Moderately activated carbons, with pores at the boarder of the ultramicropore region, e.g., 0.7-0.9 nm, are the most profitable for ions electrosorption. 

Koresh J, Soffer A. Double layer capacitance and charging rate of ultramicroporous carbon electrodes. Journal of the Electrochemical Society 1977 124(9) 1379—1385. 

Water in pores of about this Residual pores Ultramicropores... 

Abstract Makrolon , a commercially available polycarbonate with a glassy ultramicroporous structure (mean pore-volume 0.1 nm3), was often employed as sensitive layer for optical sensors in recent years. Due to the definite pore volume-distribution, it can be used as a size-selective sensitive layer. The interaction behaviour of Makrolon of different layer-thicknesses under the influence of methanol, ethanol and 1-propanol is characterized by Spectral El-lipsometry (SE), Surface Plasmon Resonance Spectroscopy (SPR)... 

Spectral Ellipsometry Surface Plasmon Resonance Spectroscopy Ultramicroporous Polymer... 

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