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Oxygen practical

Studies of the photobleaching reaction of chlorophyll have shown that the presence of oxygen practically eliminates the reversibility of the system (79). In such cases as this, extensive degassing and solvent purification are necessary to obtain meaningful data. [Pg.312]

At this time, some investigators consider that oxygen practically disappears at the density of nitrate maximum [14] or quite the contrary traces, that oxygen penetrates down into the hydrogen sulfide zone for 10-20 m [23]. In our opinion oxygen disappears at the level of onset of deep ammonia and dissolved Mn(II) and is consumed in reactions with these species. This situation appears stable from a hydrophysical point of view. [Pg.285]

Due to its high sensitivity to oxygen, practical applications of (CH)X may be limited. Polyacetylenes with various substituents have been synthesized, and... [Pg.168]

One of the main areas of research in the past decade included the preparation of aza and oxa steroids produced by replacement of carbon atoms in the steroid skeleton by nitrogen and oxygen. Practically all positions were replaced and the only successful modification of the natural isocyclic skeleton was obtained by replacing the carbon-2 atom by oxygen (E-21, E-22, E-29). [Pg.51]

In practice, for motors, turbines or furnaces, the conditions of combustion are frequently far from those corresponding to stoichiometry and are characterized either by an excess or by an insufficiency of fuel with respect to oxygen. The composition of the fuel-air mixture is expressed by the equivalence ratio, (p, defined by the relation / 5 r)... [Pg.179]

Thus, it can basically be predicted under what conditions (pH, concentration of redox species) tire metal dissolution reaction (Fe Fe ) proceeds tliennodynamically. From a practical point of view, tire rate of tire reaction and tlierefore tire fate of tire oxidized species (Fe ) is extremely important tliey can eitlier be solvated, i.e., to fonn Fe (H20) complexes, and tlierefore be efficiently dissolved in tire solution, or tliey can react witli oxygen species of... [Pg.2716]

The final products are then sulphuric acid, nitrogen oxide and oxygen the two latter react and the cycle goes on. Theoretically therefore, the nitrous fumes are never used up. In practice, however, some slight replacement is needed and this is achieved by adding a little concentrated nitric acid to the mixture in the Glover tower ... [Pg.299]

The reactivity of the transition metals towards other elements varies widely. In theory, the tendency to form other compounds both in the solid state (for example reactions to form cations) should diminish along the series in practice, resistance to reaction with oxygen (due to formation of a surface layer of oxide) causes chromium (for example) to behave abnormally hence regularities in reactivity are not easily observed. It is now appropriate to consider the individual transition metals. [Pg.369]

From the perspective of laboratory practice, the sensitivity of many indoles to acids, oxygen and light prescribes the use of an inert atmosphere for most reactions involving indoles and the avoidance of storage with exposure to light. This sensitivity is greatly attenuated by electron-withdrawing (EW) substituents. [Pg.3]

As you practice you will begin to remember patterns of electron distribution A neutral oxygen with two bonds has two unshared electron pairs A neutral nitro gen with three bonds has one unshared pair ... [Pg.22]

The metal-ion complexmg properties of crown ethers are clearly evident m their effects on the solubility and reactivity of ionic compounds m nonpolar media Potassium fluoride (KF) is ionic and practically insoluble m benzene alone but dissolves m it when 18 crown 6 is present This happens because of the electron distribution of 18 crown 6 as shown m Figure 16 2a The electrostatic potential surface consists of essentially two regions an electron rich interior associated with the oxygens and a hydrocarbon like exterior associated with the CH2 groups When KF is added to a solution of 18 crown 6 m benzene potassium ion (K ) interacts with the oxygens of the crown ether to form a Lewis acid Lewis base complex As can be seen m the space filling model of this... [Pg.669]

In practice, other elemental compositions could add up to 17. For example, OH (oxygen = 16, hydrogen = 1), CDHj (carbon = 12, deuterium = 2). [Pg.416]

In normal practice, inhibitors such as hydroquinone (HQ) [123-31 -9] or the monomethyl ether of hydroquinone (MEHQ) [150-76-5] are added to acrylic monomers to stabilize them during shipment and storage. Uninhibited acrylic monomers should be used prompdy or stored at 10°C or below for no longer than a few weeks. Improperly iahibited monomers have the potential for violent polymerizations. HQ and MEHQ require the presence of oxygen to be effective inhibitors therefore, these monomers should be stored in contact with air and not under inert atmosphere. Because of the low concentration of inhibitors present in most commercial grades of acrylic monomers (generally less than 100 ppm), removal before use is not normally required. However, procedures for removal of inhibitors are available (67). [Pg.165]

The question of whether adsorption should be done ia the gas or Hquid phase is an interesting one. Often the choice is clear. Eor example, ia the separation of nitrogen from oxygen, Hquid-phase separation is not practical because of low temperature requirements. In C q—olefin separation, a gas-phase operation is not feasible because of reactivity of feed components at high temperatures. Also, ia the case of substituted aromatics separation, such as xylene from other Cg aromatics, the inherent selectivities of iadividual components are so close to one another that a simulated moving-bed operation ia hquid phase is the only practical choice. [Pg.303]

Two main operational variables that differentiate the flotation of finely dispersed coUoids and precipitates in water treatment from the flotation of minerals is the need for quiescent pulp conditions (low turbulence) and the need for very fine bubble sizes in the former. This is accompHshed by the use of electroflotation and dissolved air flotation instead of mechanically generated bubbles which is common in mineral flotation practice. Electroflotation is a technique where fine gas bubbles (hydrogen and oxygen) are generated in the pulp by the appHcation of electricity to electrodes. These very fine bubbles are more suited to the flotation of very fine particles encountered in water treatment. Its industrial usage is not widespread. Dissolved air flotation is similar to vacuum flotation. Air-saturated slurries are subjected to vacuum for the generation of bubbles. The process finds limited appHcation in water treatment and in paper pulp effluent purification. The need to mn it batchwise renders it less versatile. [Pg.52]

In low temperature fuel ceUs, ie, AEG, PAEC, PEEC, protons or hydroxyl ions are the principal charge carriers in the electrolyte, whereas in the high temperature fuel ceUs, ie, MCEC, SOEC, carbonate and oxide ions ate the charge carriers in the molten carbonate and soHd oxide electrolytes, respectively. Euel ceUs that use zitconia-based soHd oxide electrolytes must operate at about 1000°C because the transport rate of oxygen ions in the soHd oxide is adequate for practical appHcations only at such high temperatures. Another option is to use extremely thin soHd oxide electrolytes to minimize the ohmic losses. [Pg.577]

Sulfur dioxide [7446-09-5] is formed as a result of sulfur oxidation, and hydrogen chloride is formed when chlorides from plastics compete with oxygen as an oxidant for hydrogen. Typically the sulfur is considered to react completely to form SO2, and the chlorine is treated as the preferred oxidant for hydrogen. In practice, however, significant fractions of sulfur do not oxidi2e completely, and at high temperatures some of the chlorine atoms may not form HCl. [Pg.58]


See other pages where Oxygen practical is mentioned: [Pg.314]    [Pg.238]    [Pg.313]    [Pg.13]    [Pg.314]    [Pg.238]    [Pg.313]    [Pg.13]    [Pg.188]    [Pg.387]    [Pg.630]    [Pg.77]    [Pg.2779]    [Pg.395]    [Pg.475]    [Pg.28]    [Pg.134]    [Pg.195]    [Pg.226]    [Pg.11]    [Pg.73]    [Pg.348]    [Pg.30]    [Pg.88]    [Pg.119]    [Pg.126]    [Pg.374]    [Pg.213]    [Pg.577]    [Pg.577]    [Pg.19]    [Pg.129]    [Pg.203]    [Pg.4]    [Pg.10]    [Pg.11]    [Pg.281]   
See also in sourсe #XX -- [ Pg.196 ]




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Practical oxygen separation process

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