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Temperature selectivity and

For example, porphyrins have been proposed as active elements in gas-sensor devices. This field has become one of the fastest growing areas in both research and commercial respects. Several authors have proposed the use of some organic materials, e.g., phthalocyanine and porphyrin derivatives (15-18) to improve the device s performance characteristics, such as low operating temperature, selectivity, and so on. [Pg.263]

Cherry, D.S., Dickson, K.L. and Cairns, J. (1975). Temperatures selected and avoided by fish at various acclimation temperatures. Journal of the Fisheries Research Board of Canada 32,485-491. [Pg.264]

Table CP5.2c lists some of the restrictions placed on the temperatures selected and the possible range of values for each temperature. Functional relations for the boiling-point curves in terms of weight % distilled (FA, FB, and FC) versus temperature (°F) are... Table CP5.2c lists some of the restrictions placed on the temperatures selected and the possible range of values for each temperature. Functional relations for the boiling-point curves in terms of weight % distilled (FA, FB, and FC) versus temperature (°F) are...
Related to the density of water, also at 15°C. Values will deviate slightly from this with sugar content, and at differing temperatures. Selected and calculated from the data of Lange [40]. [Pg.529]

Crystallization is widely used for chiral purification. Development of such a crystallization method involves determination of racemate type, solvent screening, temperature selection, and definition of system composition. Construction of a ternary solubility phase diagram is instrumental during this process. However, constmcting phase diagrams in different solvents at various temperatures is time consuming and requires a large quantity of compound. Perhaps... [Pg.1676]

It should be emphasized that these recommendations for the initial settings of the reactor conversion will almost certainly change at a later stage, since reactor conversion is an extremely important optimization variable. When dealing with multiple reactions, selectivity is maximized for the chosen conversion. Thus a reactor type, temperature, pressure, and catalyst are chosen to this end. Figure 2.10 summarizes the basic decisions which must be made to maximize selectivity. ... [Pg.64]

Reactor temperature and pressure. If there is a significant difierence between the effect of temperature or pressure on primary and byproduct reactions, then temperature and pressure should be manipulated to improve selectivity and minimize the waste generated by byproduct formation. d. Catalysts. Catalysts cam have a major influence on selectivity. Changing the catalyst can change the relative influence on the primary and byproduct reactions. [Pg.278]

As remarked on p. 214, the validity of the nonane pre-adsorption method when adsorptives other than nitrogen are employed for determination of the isotherms, has been examined by Tayyab. Two organic adsorptives, /i-hexane and carbon tetrachloride, which could be used at or near room temperature, were selected and the adsorbents were the ammonium salts of... [Pg.239]

The selective addition of the second HCN to provide ADN requires the concurrent isomerisation of 3PN to 4-pentenenitrile [592-51 -8] 4PN (eq. 5), and HCN addition to 4PN (eq. 6). A Lewis acid promoter is added to control selectivity and increase rate in these latter steps. Temperatures in the second addition are significandy lower and practical rates may be achieved above 20°C at atmospheric pressure. A key to the success of this homogeneous catalytic process is the abiUty to recover the nickel catalyst from product mixture by extraction with a hydrocarbon solvent. 2-Methylglutaronitrile [4553-62-2] MGN, ethylsuccinonitfile [17611-82-4] ESN, and 2-pentenenitrile [25899-50-7] 2PN, are by-products of this process and are separated from adiponitrile by distillation. [Pg.221]

Early catalysts for acrolein synthesis were based on cuprous oxide and other heavy metal oxides deposited on inert siHca or alumina supports (39). Later, catalysts more selective for the oxidation of propylene to acrolein and acrolein to acryHc acid were prepared from bismuth, cobalt, kon, nickel, tin salts, and molybdic, molybdic phosphoric, and molybdic siHcic acids. Preferred second-stage catalysts generally are complex oxides containing molybdenum and vanadium. Other components, such as tungsten, copper, tellurium, and arsenic oxides, have been incorporated to increase low temperature activity and productivity (39,45,46). [Pg.152]

From 760 to 960°C, circulating fans, normally without baffles, are used to improve temperature uniformity and overall heat transfer by adding some convection heat transfer. They create a directional movement of the air or atmosphere but not the positive flow past the heating elements to the work as in a convection furnace. Heating elements ate commonly chrome—nickel alloys in the forms described previously. Sheathed elements are limited to the very low end of the temperature range, whereas at the upper end silicon carbide resistors may be used. In this temperature range the selection of heating element materials, based on the combination of temperature and atmosphere, becomes critical (1). [Pg.137]

Finally, selective hydrogenation of the olefinic bond in mesityl oxide is conducted over a fixed-bed catalyst in either the Hquid or vapor phase. In the hquid phase the reaction takes place at 150°C and 0.69 MPa, in the vapor phase the reaction can be conducted at atmospheric pressure and temperatures of 150—170°C. The reaction is highly exothermic and yields 8.37 kJ/mol (65). To prevent temperature mnaways and obtain high selectivity, the conversion per pass is limited in the Hquid phase, and in the vapor phase inert gases often are used to dilute the reactants. The catalysts employed in both vapor- and Hquid-phase processes include nickel (66—76), palladium (77—79), copper (80,81), and rhodium hydride complexes (82). Complete conversion of mesityl oxide can be obtained at selectivities of 95—98%. [Pg.491]

The process temperature affects the rate and the extent of hydrogenation as it does any chemical reaction. Practically every hydrogenation reaction can be reversed by increasing temperature. If a second functional group is present, high temperatures often lead to the loss of selectivity and, therefore, loss of desired product yield. As a practical measure, hydrogenation is carried out at as low a temperature as possible which is stiU compatible with a satisfactory reaction rate. [Pg.207]

In 1974, Monsanto brought on-stream an improved Hquid-phase AIQ. alkylation process that significantly reduced the AIQ. catalyst used by operating the reactor at a higher temperature (42—44). In this process, the separate heavy catalyst—complex phase previously mentioned was eliminated. Eliminating the catalyst—complex phase increases selectivities and overall yields in addition to lessening the problem of waste catalyst disposal. The ethylben2ene yields exceed 98%. [Pg.48]

Temperature. Temperature sensor selection and installation should be based on the process-related requirements of a particular situation, ie, temperature level and range, process environment, accuracy, and repeatabiHty. Accuracy and repeatabiHty are affected by the inherent characteristics of the device and its location and installation. For example, if the average temperature of a flowing fluid is to be measured, mounting the device nearly flush with... [Pg.65]

Reverse osmosis membrane separations are governed by the properties of the membrane used in the process. These properties depend on the chemical nature of the membrane material, which is almost always a polymer, as well as its physical stmcture. Properties for the ideal RO membrane include low cost, resistance to chemical and microbial attack, mechanical and stmctural stabiHty over long operating periods and wide temperature ranges, and the desired separation characteristics for each particular system. However, few membranes satisfy all these criteria and so compromises must be made to select the best RO membrane available for each appHcation. Excellent discussions of RO membrane materials, preparation methods, and stmctures are available (8,13,16-21). [Pg.144]

Before a source analysis program is undertaken, it is important to decide which information is really required. Sampling sites must be selected with care. Choice of the site can significantly affect accuracy and cost. Care must also be taken in the selection of sampling points at the site. Measurement usually involves the deterrnination of temperature, concentration, and characterization of the gas contaminants. It also requires the mass rates of emission of each contaminant, therefore concentration and volumetric flow data are required. [Pg.299]


See other pages where Temperature selectivity and is mentioned: [Pg.959]    [Pg.959]    [Pg.2696]    [Pg.505]    [Pg.127]    [Pg.3]    [Pg.203]    [Pg.267]    [Pg.78]    [Pg.132]    [Pg.268]    [Pg.385]    [Pg.512]    [Pg.146]    [Pg.221]    [Pg.459]    [Pg.181]    [Pg.376]    [Pg.303]    [Pg.348]    [Pg.405]    [Pg.311]    [Pg.45]    [Pg.72]    [Pg.508]    [Pg.508]    [Pg.508]    [Pg.35]    [Pg.390]    [Pg.459]    [Pg.520]    [Pg.390]    [Pg.482]    [Pg.316]   
See also in sourсe #XX -- [ Pg.658 , Pg.814 ]

See also in sourсe #XX -- [ Pg.172 ]




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