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C Schematic of the hydrophobic bonding of the adsorbed protein and the mode of ionic clustering. This ionic clustering the ionic subsurface template for surface ordering. Key

C section of the Sc-Mg-Zn phase distribution according to power diffraction results, roughly outlining the phase regions of the 1 1 AC, 2 1 AC and Tsai-type i-QC

C SEM micrographs of silicalite-1 films on silicon wafer by in-situ crystallization

C Separation of Type II pheromone components by HPLC with an ODS column

C Sequential expression of neural and neuronal progenitor markers in cells within DG. A The neural progenitor marker Nestin is expressed on cells negative for the neuronal progenitor marker PSA-NCAM . PSA-NCAM 3III-tubuli

C shift changes of pyridine carbon nuclei induced by dilution with water .

C shope headers vnth lorge-rcidius corners minimum stress concentration and Flat weld joint For easy radiography. Courtesy Ecodyne MRM Division

C show that the influence of growing season depends on the type or class of wheat. The influence of growing season is further illustrated by

C show the source fragmentation spectra of poly. A number of fragment ions are generated in source fragmentation however, the ions from the Gn series at miz 148,192, and 236 are preferentially formed

C show the typical HPLC of DNPH of urinary carbonyls. The Maillard reactants such as acetone, methylglyoxal, glyoxal, crotonal, were tentatively identified among these peaks, because identification was based only on retention times of HPLC .

C show time spectra when two successive laser pulses are applied. In

C shows a model representing the thylakoid membrane of a cyanobacterium or a red alga, consisting of photosystems I and II interconnected by the cytochrome- complex, and the ATP synthase, CFo CFi. The phycobilisomes are seen as attached to the stromal surface at the PS-II reaction-center core complex.

C shows a plot of data points obtained in a manner similar to that illustrated in panel but at other temperatures ranging from 13 to 225 K and for times ranging from 25 s to 10 m, as tabulated in

C shows a reflux assembly with a stirrer fitted. The stirrer A is both held in position in the tube B and allowed to rotate freely by the lubricated rubber sleeve C, as described on p. 39, and is connected to a vertical motor above. The extent to which the stirrer dips into the liquid in the flask can readily be adjusted. The condenser is fitted into D. This constitutes for many purposes the best type of stirrer. If desired, the rubber sleeve C can be replaced by a metal fitting E for a horizontal drive. The gas-inlet F is closed when not in use.

C shows a relationship in which the dependent variable changes significantly. The slope ranges from positive to negative. At the apex of the plot, the slope is momentarily zero. This condition, a zero slope, is called equilibrium because the dependent variable does not change as the independent variable changes.

C shows AA at 694 nm produced by a 708-nm excitation pulse in TSF-I particles poised at - 200 mV. The AA reached a maximum in 30 ps and decayed in two phases with lifetimes of -45 and 2 0ps, respectively, to a level corresponding to P700 photooxidation alone, as shown in

C shows an additional movement of radioactivity following foliar application of C14-gibberellin. This was a wedge-shaped movement from the site of application towards the leaf tip and has been ascribed by Strugger to transpira-tional movement in the cell walls .

C shows an electron photomicrograph of a broken planar SOFC. The thick portion on the left is the porous anode structure. This is an anode-supported cell, meaning that in addition to collecting current and supporting the anode reaction, the anode layer stiffens the whole cell. The layer on the right is the cathode, and the interface between the two is the thin electrolyte. One of the challenges of this design is to ensure that the rates of expansion of the cathode and the anode match. If the anode expands faster than the cathode, the planar cell tends to curl like a potato chip when the temperature changes.

C shows an extreme case of the dependence of a substitution reaction rate on the nature of the incoming group. This happens to be the hydrolysis of the trisacetylacetonate complex of silicon for processes that seem to be Sn2 bimolecular displacement processes.

C shows carbon monoxide insertion reactions. There are a number of reduction reactions of carbon monoxide catalyzed by transition metals, and these, I believe, all involve an insertion of carbon monoxide into a metal hydride as an initial step. Cobalt hydrocarbonyl reacts with carbon monoxide to give formate derivatives. This is probably an insertion reaction also.

C shows for niobium the increased rate of oxidation as temperature is raised. In the case of the 450 C curve this also shows no difiference for dry and wet oxygen over the relatively short time of 7 h whereas

C shows Helena with the three children a few months after Sam died.

C shows sets of admissible states M starting from initial state 0, Ct

C shows sputter depth profile of OH. Distribution of OH is found to be the highest in BHAC. On BHAC, OH ions provide selective adsorption sites and react widi NOj, as seen in Eq. , and evaporate into H2O. According, after adsorption of NO2, a substantial reaction of OH was observed regardless of surface depths. However, after desorption, OH ions increased on die surface which may be explained by two possibilities

C shows sputter depth profile of OH. Distribution of OH is found to be the highest in BHAC. On BHAC, OH ions provide selective adsorption sites and react with NO2, as seen in Eq. , and evaporate into H2O. Accordingly, after adsorption of NO2, a substantial reduction of OH was observed regardless of surface depths. However, after desorption, OH ions increased on the surface which may be explained by two possibilities



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