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Valence of groups

Uv Binary variable indicating whether the ith position in a molecule has structural group j. v Valence of group j. [Pg.144]

The principal valence of Group IV elements is 4, each element of the group except lead forming its principal series of compounds in the quadrivalent state. Valences of 2 are common, and 3 occasional. The quadrivalent halogen compounds of most of the elements form characteristic double derivatives with the alkali halides, of the type M12MlTX. These compounds, especially the fluorides, are of much importance. [Pg.129]

All automatic procedures and more recent methods " generate feasible chemical structures from groups by relying primarily on the valence of groups. Examples of groups of valence 1, 2, and 3 are shown in Table I. Some methods take a symbolic and qualitative approach in constructing compounds while others adopt a quantitative optimization-oriented approach. We will keep our discussion away from such algorithmic and computer implementation details, so that it encompasses both types of techniques. [Pg.703]

Mendeleef drew up a table of elements considering the chemical properties, notably the valencies, of the elements as exhibited in their oxides and hydrides. A part of Mendeleefs table is shown in Figure 1.2 -note that he divided the elements into vertical columns called groups and into horizontal rows called periods or series. Most of the groups were further divided into sub-groups, for example Groups... [Pg.2]

From the tables it is clear that elements in Groups I-IV can display a valency equal to the group number. In Groups V-VII. however, a group valency equal to the group number (x) can be shown in the oxides and fluorides (except chlorine) but a lower valency (8 — x) is displayed in the hydrides. This lower valency (8 — x) is also found in compounds of the head elements of Groups V-VII. [Pg.20]

One of the cornerstones of the chemistry of carbon compounds (organic chemistry) is Kekule s concept, proposed in 1858, of the tetra-valence of carbon. It was independently proposed in the same year by Couper who, however, got little recognition (vide infra). Kekule realized that carbon can bind at the same time to not more than four other atoms or groups. It can, however, at the same time use one or more of its valences to form bonds to another carbon atom. In this way carbon can form chains or rings, as well as multiple-bonded compounds. [Pg.153]

Examine the unfilled valences of the carboxylic acid group and find the one marked by a small circle If necessary click on the group to make this circle move to the va lence on carbon... [Pg.1261]

Other Polyatomic Anions. Names for other polyatomic anions consist of the root name of the central atom with the ending -ate and followed by the valence of the central atom expressed by its oxidation number. Atoms and groups attached to the central atom are treated as ligands in a complex. [Pg.219]

The usual valence of indium is three, although monovalent and bivalent compounds of indium with oxygen, halogens, and Group 15 (VA) and 16 (VIA) elements ate well known. The lower valence compounds tend to disproportionate into the trivalent compound and indium metal the trivalent compounds ate stable. [Pg.81]

Lead (qv) is a member of Group 14 (IVA) of the Periodic Table because it has four electrons in its outer, or valence, shell. However, the usual valence of lead is +2, rather than +4. The two s electrons have higher ionisation energies. As a result, tetravalent lead exists as a free, positive ion only in minimal concentrations. Furthermore, the bivalent or plumbous ion differs from the other Group 14 bivalent ions, such as the starmous ion of tin, because Pb " does not have reducing properties. [Pg.67]

Magnesium [7439-95-4] atomic number 12, is in Group 2 (IIA) of the Periodic Table between beryllium and calcium. It has an electronic configuration of 1T2T2 3T and a valence of two. The element occurs as three isotopes with mass numbers 24, 25, and 26 existing in the relative frequencies of 77, 11.5, and 11.1%, respectively. [Pg.313]

Silicon (3), which resembles metals in its chemical behavior, generally has a valence of +4. In a few compounds it exhibits a +2 valence, and in silicides it exists as a negative ion and largely violates the normal valency rules. Silicon, carbon, germanium, tin, and lead comprise the Group 14 (IVA) elements. Silicon and carbon form the carbide, SiC (see Carbides). Silicon and germanium are isomorphous and thus mutually soluble in all proportions. Neither tin nor lead reacts with silicon. Molten silicon is immiscible in both molten tin and molten lead. [Pg.525]

Antimony [7440-36-0J, Sb, belongs to Group 15 (VA) of the periodic table which also includes the elements arsenic and bismuth. It is in the second long period of the table between tin and tellurium. Antimony, which may exhibit a valence of +5, +3, 0, or —3 (see Antimony compounds), is classified as a nonmetal or metalloid, although it has metallic characteristics in the trivalent state. There are two stable antimony isotopes that ate both abundant and have masses of 121 (57.25%) and 123 (42.75%). [Pg.194]

Arsenic [7440-38-2J, although often referred to as a metal, is classified chemically as a nonmetal or metalloid and belongs to Group 15 (VA) of the periodic table (as does antimony). The principal valences of arsenic are +3, +5, and —3. Only one stable isotope of arsenic having mass 75 (100% natural abundance) has been observed. [Pg.326]

Cadmium is a member of Group 12 (Zn, Cd, Hg) of the Periodic Table, having a filled d shell of electrons which dictates the usual valence state of... [Pg.391]

If pure, the carbides of Groups 1 and 2 are characterized by their transparency and lack of conductivity. The carbides of Group 3, ie. Sc, Y, the lanthanides, and the actinides, ate opaque. Some, depending on composition, show metallic luster and electroconductivity. The cation may exist in the MC2 phases of this group, and the remaining valence electron apparendy imparts pardy metaUic character to these compounds. [Pg.439]

P4) is closely similar with P-P distances of 216 pm (smaller than for P4 itself, 221pm). Indeed, a whole series of complexes has now been established with the same structure-motif and differing only in the number of valency electrons in the cluster some of these are summarized in Table 13.11. The number of valence electrons in all these complexes falls in the range 30-34 as predicted by R. Hoffmann and his colleagues.Many other cluster types incorporating differing numbers of Group 15 and transition metal atoms are now known and have been fully reviewed. ... [Pg.588]

The concept of isosterism 481 has been used in medicinal chemistry. Molecules or groups which possess physicochemical similarity (e.g., similarity in size or the number of valence electrons) are called isosteres. The classical isosteres include, for instance, the following two pairs of groups ... [Pg.109]

In the same wray, compounds of group 3A elements, such as BF3 and AICI3, are Lewis acids because they have unfilled valence orbitals and can accept electron... [Pg.57]

See other pages where Valence of groups is mentioned: [Pg.5]    [Pg.3]    [Pg.72]    [Pg.5]    [Pg.3]    [Pg.72]    [Pg.169]    [Pg.14]    [Pg.1014]    [Pg.31]    [Pg.149]    [Pg.123]    [Pg.4]    [Pg.300]    [Pg.433]    [Pg.50]    [Pg.52]    [Pg.53]    [Pg.119]    [Pg.92]    [Pg.469]    [Pg.117]    [Pg.67]    [Pg.419]    [Pg.183]    [Pg.203]    [Pg.67]    [Pg.306]    [Pg.112]    [Pg.552]    [Pg.889]    [Pg.1038]    [Pg.173]    [Pg.128]   
See also in sourсe #XX -- [ Pg.221 ]



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