Oxidation state maximum

Figure 10.3-16. The principle of similarity searches. The query (target, precursor) as well as the catalog compound are transformed by the criterion maximum oxidation state". Since the transformation for both compounds results in the samie transformed structure, the catalog compound is presented to the user as a suitable starting material. The comparison of the structure is performed by a hashcode algorithm.

Peroxohydrates are crystalline adducts containing molecular hydrogen peroxide. These are commonly called perhydrates, but this name is better avoided because historically implied the maximum oxidation state and hjdrate implies the presence of water, neither of which apply to peroxohydrates. They have also been called hydroperoxidates (92). 

Plutonium oxidation state Wavelength maximum, nm Molar ah sorptivities, L/(molcm) ... 

The maximum oxidation state observed for the elements first increases and then decreases as we go across the transition row. Thus we have 4-3 for scandium, 4-4 for titanium, 4-5 for vanadium, 4-6 for chromium, and 4-7 for manganese. The 4-7 represents the highest value observed for this transition row. After manganese, the maximum value diminishes as we continue toward the end of the transition row. 

Molybdenum blue method. When arsenic, as arsenate, is treated with ammonium molybdate solution and the resulting heteropolymolybdoarsenate (arseno-molybdate) is reduced with hydrazinium sulphate or with tin(II) chloride, a blue soluble complex molybdenum blue is formed. The constitution is uncertain, but it is evident that the molybdenum is present in a lower oxidation state. The stable blue colour has a maximum absorption at about 840 nm and shows no appreciable change in 24 hours. Various techniques for carrying out the determination are available, but only one can be given here. Phosphate reacts in the same manner as arsenate (and with about the same sensitivity) and must be absent. 

Chlorine can exist in both positive and negative oxidation states. What is the maximum (a) positive and (b) negative oxidation number that chlorine can have (c) Write the electron configuration for each of these states, (d) Explain how you arrived at these values. 

Note that the occurrence of a maximum oxidation state, corresponding to the removal of all the valence shell electrons and the adoption of a configuration, does not occur after manganese. In Chapter 9 we see how this reflects the contraction of the poorly penetrating 3d orbitals as the nuclear charge increases and it becomes progressively more difficult to remove electrons. 

The reaction between Co(III) and Ce(III) has been the subject of a detailed study in a series of papers by Sutcliffe and Weber . Of particular value is the thorough investigation of the influence of anions on the rate in perchlorate media. The reaction was followed by measuring the disappearance of Co(IIl) at its absorption maximum of 650 m/i, a wavelength where both oxidation states of cerium are transparent and Co(II) absorbs only slightly. Changes in temperature and ionic strength affect the spectrum of Ce(III) at the 296 m/i maximum, but the... 

The curves of Figure 2.9 exhibit the complex structure of the surface film. With increasing depth there is a peak of iron in the oxidized state at approximately 0.3 nm, and a peak of chromium in the oxidized state at about 1 nm irrespective of immersion time. The maximum concentration of oxidized iron decreases and the maximum concentration of oxidized chromium increases with increasing immersion time. 

The oxidation number of oxygen in its compounds is -2 except in peroxides (where it is -1), superoxides (where it is - ), or in OF2 and 02F2 (where it is positive). The peroxides and superoxides generally occur only with other elements in their maximum oxidation states. You will be able to recognize peroxides or superoxides by the presence of pairs of oxygen atoms and by the fact that if the compounds were normal oxides, the other element present would have too high an oxidation number (Sec. 13.3). 

No. Its maximum oxidation state is +4 since it is in group IV in the periodic table. 

The more electronegative element will take the negative oxidation state, (a) The maximum oxidation state of sulfur is +6 the most common negative oxidation number of oxygen is -2. Therefore, it takes three oxygen atoms to balance one sulfur atom, and the formula is SO v (b) The maximum oxidation state of carbon is +4 the only oxidation number of fluorine in its compounds is - 1. Therefore, it takes four fluorine atoms to balance one carbon atom, and the formula is CF4,... 

The rules above gave maximum and minimum oxidation numbers, but those might not be the only oxidation numbers or even the most important oxidation numbers for an element. Elements of the last six groups of the periodic table for example may have several oxidation numbers in their compounds, most of which vary from each other in steps of 2. For example, the major oxidation states of chlorine in its compounds are -1, +1, +3, +5, and +7. The transition metals have oxidation numbers that may vary from each other in steps of 1. The inner transition elements mostly form oxidation states of + 3, but the first part of the actinoid series acts more like transition elements and the elements have... 

The oxygen must exist in a -2 oxidation state, because it is more electronegative than is sulfur. Therefore, sulfur must exist in two different positive oxidation states in the two compounds. Its maximum oxidation state is + 6, corresponding to its position in periodic group VIA. It also has an oxidation state of +4. 2 less than its maximum (see Fig. 13-1). The formulas therefore arc SO, and SO,. 

Ans. (a) Pb4 + and Pb2+. (The maximum oxidation state of a group IV element and the state 2 less than the maximum.) (b) Tl3+ and Tl+. (The maximum oxidation state of a group III element and the state 2 less than the maximum.) (c) Sn4+ and Sn2+. (The maximum oxidation state of a group IV element and the state 2 less than the maximum.) (d) Cu+ and Cu2 +. (The maximum oxidation state for the coinage metals is greater than the group number.)... 

Ans. SF6, SF4, and SF2. The oxidation states of sulfur in these compounds correspond to the maximum oxidation state for a group VI element and to states 2 and 4 lower. (See Fig. 13-1.)... 

Ans. (a) Since one half-reaction is a reduction, the other half-reaction must be an oxidation. (b) The maximum oxidation state for nitrogen is +5, because nitrogen is in periodic group V. Since it starts out in oxidation number +4, it must be oxidized to +5. 

What is the maximum oxidation state of fluorine in any compound ... 

The possible oxidation states of the metals from Mn to Zn are shown in Figure 2.6. (Note that oxidation states are defined by ion charge, n in M"+.) The way the maximum values increase and then decrease in the series is a consequence of... 

The maximum oxidation states for the metals in Groups 3B through 7B are given by the element s group number. However, this is unlikely to be the element s most stable oxidation state. 

In some applications, additional components acting as reactors for specific chemical pretreatment are incorporated within the flow manifold. Typical examples are ion-exchange microcolumns for preconcentration of the analyte or removal of interferences and redox reactors, which are used either to convert the analyte into a more suitable oxidation state or to produce online an unstable reagent. Typical examples of online pretreatment are given in Table 2. Apart from these sophisticated reactors, a simple and frequently used reactor is a delay coil (see also Fig. 4), which may be formed by knitting a segment of the transfer line. This coil allows slow CL reactions to proceed extensively and enter into the flow cell at the time required for maximum radiation. The position of the reactors within the manifold is either before or after the injection port depending on the application. 

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