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TRI-CAL

Figure 9-21. Elec tri cal circuit portraying a plant component that can store water. The battery represents the drop in water potential along component j. The currents (arrows) represent the flux densities of water, which can come across R as well as from storage in capacitor C and then across Z 7. Figure 9-21. Elec tri cal circuit portraying a plant component that can store water. The battery represents the drop in water potential along component j. The currents (arrows) represent the flux densities of water, which can come across R as well as from storage in capacitor C and then across Z 7.
Calcium phosphate, tribasic Insoluble in water (Tricafos , Tri-Cal , Tri-Tab )... [Pg.3656]

Calcium orthophosphate E341 hydroxylapatite phosphoric acid calcium salt (2 3) precipitated calcium phosphate tertiary calcium phosphate Tri-Cafos tricalcium diorthophosphate tricalcium orthophosphate tricalcium phosphate TRI-CAL WG-, TRI-TAB. [Pg.100]

Calbon [Gelatine Smits Beheer http //www.gsb.net, Smits Vuren BV] Calbon N [Smits Vuren BV] Calfos t[Croda Colloids Ltd] TRI-CAL WG [Rhodia Food http //www.food.us.rhodia.com]... [Pg.704]

Tributyrinase Tributyrin esterase. See Lipase Tributyroin. See Tributyrin Trie. See Trichloroethylene TRi-CAL WG. See Calcium phosphate tribasic Tricalcium aluminate. See Calcium aluminate Tricalcium bis (orthophosphate). See Calcium phosphate tribasic... [Pg.4481]

A few of the above-menti I solutions to cavitation are almost. cal even cost effective. The idea is that they would work to reduce and stop < and the resulting seal, bearing and pump failure. Too many maint. (engineers and mechanics) are running around in circles, wring their h jumping up and down, trying to deal with cavitation. Who would have there are so many solutions, practical or not ... [Pg.36]

One of the few theoretical papers trying to explain acceleration under the action of microwaves has recently been published by A. Miklavc [18]. He stated that large increases in the rates of chemical reactions occur because of the effects of rotational excitation on collision geometry. This could be cautiously considered when one has knowledge of the quasi-nil energy involved by microwave interaction according to Planck s law [E = hc/X = 0.3 cal/mol]. [Pg.63]

On treatment of tri-O-acetyl-D-glucal with chlorine and silver fluoride,198 all four possible isomers were formed tri-0-acetyl-2-chloro-2-deoxy-a-D-mannopyranosyl fluoride (16%), tri-0-acetyl-2-chloro-2-deoxy-/3-D-mannopyranosyl fluoride (16%), tri-0-acetyl-2-chloro-2-deoxy-a-D-glucopyranosyl fluoride (6%), and tri-O-acetyl-2-chloro-2-deoxy-/3-D-glucopyranosyl fluoride (62%). These product ratios differ significantly from those of the corresponding bromofluorination and iodofluorination reactions of tri-O -ace tyl-D-glucal,43,53 and this behavior has been discussed198 in terms of the differences observed between the addition of bromine (or iodine) and chlorine to tri-O-acetyl-D-glu-cal, and the nature of the chlorination reaction itself. [Pg.237]

I would suggest that this emotions model or a similar one with an ethological basis could be used not only as a framework for organizing research on human behavior, but also as a heuristic device for identifying potential areas for future research. To illustrate the breadth of the emotions model, I will try to fit some examples of recent sociobiologi-cal research into it. [Pg.40]

Opticrom 27 Optimine 16 Oramorph SR 50 Organidin 39 Orgaran 27 Orlistat 53 Ornade Sbansule 79 Orphenadrine 54, 78 Ortho Tri-Cyclen 79 Ortho-Cept 79 Ortho-Cyclen 79 Ortho-Novum 79 Ortho-Novum 7/7/7 79 Orudis 43 Oruvail 43 Os-cal 20 Oseltamivir 54 Osmitrol 47 Ovcon 79 Ovral 79 Oxacillin 54... [Pg.106]

We try to make calculations come out in round numbers so in many problems the feed concentrations are 2 moles/bter, conversions are 90%, reactor volumes 100 liters, and feed temperatures 300 or 400 K. We further assume that all heats of reaction and heat capacities are independent of temperature, pressure, and composition. We sometimes even assume the ideal gas constant R=2 cal/mole K, just because it makes it easier to remember than 1.98... . ... [Pg.12]

Figure 6.18 Transmission electron micrographs of protein structures from solutions of 3 wt% a-lactalbumin incubated with 4 wt% Bacillus licheni-forrnis at 50 °C (75 mM Tris-HCl, pH = 7.5) at different values of the cal-cium/a-lactalbumin molar ratio R. The image dimensions are 2100 nrn x 2600 nm Reproduced from Gravcland-Bikkcr et al. (2004) with permission. Figure 6.18 Transmission electron micrographs of protein structures from solutions of 3 wt% a-lactalbumin incubated with 4 wt% Bacillus licheni-forrnis at 50 °C (75 mM Tris-HCl, pH = 7.5) at different values of the cal-cium/a-lactalbumin molar ratio R. The image dimensions are 2100 nrn x 2600 nm Reproduced from Gravcland-Bikkcr et al. (2004) with permission.
With the knowledge that 14 can activate aldehydes in 1, the role of 1 in the reaction was explored further. Specifically, the relative rates of C—H bond activation and guest ejection, and the possibility of ion association with 1, were investigated. The hydrophobic nature of 14 could allow for ion association on the exterior of 1, which would be both cn t h al pi cal I y favorable due to the cation-it interaction, and entropically favorable due to the partial desolvation of 14. To explore these questions, 14 was irreversibly trapped in solution by a large phosphine, which coordinates to the iridium complex and thereby inhibits encapsulation. Two different trapping phosphines were used. The first, triphenylphosphine tris-sulfonate sodium salt (TPPTS), is a trianionic water-soluble phosphine and should not be able to approach the highly anionic 1, thereby only trapping the iridium complex that has diffused away from 1. The second phosphine, l,3,5-triaza-7-phosphaadamantane (PTA), is a water-soluble neutral phosphine that should be able to intercept an ion-associated iridium complex. [Pg.170]

D. L. Chapman, for potassium tri-iodide. 0. Gropp measured the effect of temp, on the conductivity of solid and frozen soln. of sodium iodide. For the effect of press, on the electrical properties, vide alkali chlorides. A. Reis found the free energy for the separation of the ions of K1 to be 144 lrilogrm. cals, per mol. for iN al, 158 Lil, 153 and for HI, 305. S. W. Serkofi 35 measured the conductivity of lithium iodide in methyl alcohol P. Walden, of sodium iodide in acetonitrile P. Dutoit in acetone, benzonitrite, pyridine, acetophenone. J. C. Philip and H. R. Courtman, B. B. Turner, J. Fischler, and P. Walden of potassium iodide in methyl or ethyl alcohol J. C. Philip and H. P. Courtman in nitromethane P. Dutoit in acetone. H. C. Jones, of rubidium iodide in formamide. S. von Lasczynsky and S. von Gorsky, of potassium and sodium iodides in pyridine. A. Heydweiller found the dielectric constants of powdered and compact potassium iodide to be respectively 3 00 and 5 58. [Pg.605]

Many processes hevo been tried to free the coke used for smelting purposes from sulphnr. Mr. Cal-veiit recently proposed to apply small portions of chloride of sodium to the coke in the process of niaiiu. facturo, by which means the fuel was made more suitable foT the iron being freed from its sulphur, and in several experiments the iron made from this prepared coke was found much superior to the ordinary quality but the process has not yet been very ... [Pg.421]

See other pages where TRI-CAL is mentioned: [Pg.312]    [Pg.100]    [Pg.866]    [Pg.656]    [Pg.6248]    [Pg.6873]    [Pg.655]    [Pg.312]    [Pg.100]    [Pg.866]    [Pg.656]    [Pg.6248]    [Pg.6873]    [Pg.655]    [Pg.41]    [Pg.251]    [Pg.251]    [Pg.460]    [Pg.394]    [Pg.607]    [Pg.129]    [Pg.98]    [Pg.151]    [Pg.884]    [Pg.230]    [Pg.126]    [Pg.484]    [Pg.390]    [Pg.522]    [Pg.251]    [Pg.123]    [Pg.184]    [Pg.236]    [Pg.350]    [Pg.485]    [Pg.517]    [Pg.609]    [Pg.504]    [Pg.592]    [Pg.224]    [Pg.528]    [Pg.155]   
See also in sourсe #XX -- [ Pg.100 ]



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