Nonmetals ionic compounds with

The elements show increasing metallic character down the group (Table 14.6). Carbon has definite nonmetallic properties it forms covalent compounds with nonmetals and ionic compounds with metals. The oxides of carbon and silicon are acidic. Germanium is a typical metalloid in that it exhibits metallic or nonmetallic properties according to the other element present in the compound. Tin and, even more so, lead have definite metallic properties. However, even though tin is classified as a metal, it is not far from the metalloids in the periodic table, and it does have some amphoteric properties. For example, tin reacts with both hot concentrated hydrochloric acid and hot alkali ... 

Q. Why do metals tend to form ionic compounds with nonmetals ... 

The elements show increasing metallic character down the group (Table 14.12). Carbon has definite nonmetallic properties it forms covalent compounds with nonmetals and ionic compounds with metals. The oxides of carbon and silicon are acidic. Germanium is a typical metalloid... 

In earlier chapters, we saw examples of how the metallic or nonmetallic character of an element affects its chemistry. Metals tend to form ionic compounds with nonmetals, whereas nonmetals tend to form covalent, molecular compounds with one another. Thus, binary metallic hydrides, such as NaH and CaH2, are ionic solids with high melting points, and binary nonmetallic hydrides, such as CH4, NH3, H20, and HF, are covalent, molecular compounds that exist at room temperature as gases or volatile liquids (Section 14.5). 

Metals form alloys with each other. They form ionic compounds with nonmetals. Nonmetals form only covalently bonded compounds with each other. As a result, metals become only positively (+) charged ions, whereas nonmetals become either negatively (-) or positively (+) charged ions. 

Electrovalent bonds are formed between oppositely charged ions, and typically a metal donates electrons to a nonmetal. For example, sodium chloride (common salt, an important constituent of the body s fluids) is written as Na Cl. For sodium chloride only one electron is involved in the transfer and the molecular formula is written as NaCl. However, if sodium forms an ionic compound with oxygen, an oxygen atom needs two electrons to form an ion, so it will need to have two sodium atoms donating electrons ... 

There are general reactivity trends on the periodic table that are useful to know. Metals and nonmetals usually combine to form ionic compounds with the metal giving up an electron to become positively charged and the nonmetal element gaining an electron to become... 

Carbon forms covalent compounds with nonmetals and ionic compounds with metals. 

Form ionic compounds with metals and molecular (covalent) compounds with other nonmetals... 

Most metals react with most nonmetals to form binary ionic compounds. The Group lA metals combine with the Group VIIA nonmetals to form binary ionic compounds with the general formula MX (Section 7-2) ... 

In Group IA(1), lithium and sodium have the condensed electron configuration [noble gas] ns (where n is the quantum number of the outermost energy level), as do all the other alkali metals (K, Rb, Cs, Fr). All are highly reactive metals that form ionic compounds with nonmetals with formulas such as MCI, M2O, and M2S (where M represents the alkali metal), and all react vigorously with water to displace H2. 

In Group 7A(17), fluorine and chlorine have the condensed electron configuration [noble gas] ns np, as do the other halogens (Br, I, At). Little is known about rare, radioactive astatine (At), but all the others are reactive nonmetals that occur as diatomic molecules, X2 (where X represents the halogen). All form ionic compounds with metals (KX, MgX2), covalent compounds with hydrogen (HX) that yield acidic solutions in water, and covalent compounds with carbon (CX4). 

Nonmetals form simple negative ions. These ions easily form ionic compounds with metallic elements. Examples of compounds containing simple ions are LiH, Fe Oj, NajN, CuS, K Se, and CajP. ... 

As indicated before, the ab initio electronic-structure theory of solid-state materials has largely profited from density-functional theory (DFT), and the performance of DFT has turned out well even when the one of its molecular quantum-chemical competitors - Hartree-Fock theory - has been weakest, namely for metallic materials. For these, and also for covalent materials, DFT is a very reasonable choice. On the other hand, ionic compounds (with both metals and nonmetals present) are often discussed using only the ionic model, on which most of Section 1.2 was based, and the quantum-mechanical approach is not considered at all, at least in introductory textbooks. Nonetheless, let us see, as a first instructive example, how a t5q)ical ionic material can be described and understood by the ionic and the quantum-chemical (DFT and HF) approaches, and let us also analyze the strengths and weaknesses. 

With an electronegativity only slightly above the median value of all the chemical elements, hydrogen behaves like a weakly electronegative non-metal. It forms ionic compounds with very electropositive metals and covalent compounds with nonmetals. It also forms metal hydrides with some of the transition metals. The three major hydrides it forms and with which elements are shown in Figure 10-2. 

With a few exceptions, the ionization potential of an atom increases within a given period with increase in atomic number. Because of this phenomenon, the alkali and alkaline earth metals form ionic compounds with electronegative ligands such as halogens, while the metalloids and nonmetals form compounds with considerable covalent character. Exceptions to the 8 rule are encountered most frequently in ionic compounds as well as in compounds of metalloids and nonmetals. In the latter case, compounds with more than eight valence electrons may be formed. These deviations are a function of properties of the central atom and the ligands. 

They form ionic compounds with nonmetals... 

Metal oxides belong to a class of widely used catalysts. They exhibit acidic or basic properties, which make them appropriate systems to be used as supports for highly dispersed metal catalysts or as precursors of a metal phase or sulfide, chloride, etc. Simple metal oxides range from essentially ionic compounds with the electropositive elements to covalent compounds with the nonmetals. However, taking into account the large variety of metal oxides, the principal objective of this book is to examine only metal oxides that are more attractive from the catalytic point of view, and most specifically transition metal oxides (TMO). In particular, TMO usually exhibit nonstoichiometry as a consequence of the presence of defective structures. The interaction of TMO with surfaces of the appropriate carriers develop monolayer structures of these oxides. The crystal and electronic structure, stoichiometry and composition, redox properties, acid-base character and cation valence sates are major ingredients of the chemistry investigated in the first part of the book. New approaches to the preparation of ordered TMO with extended structure of texturally well defined systems are also included. 

Halogens form ionic compounds with most metals, they form covalent compounds with many nonmetals, and they can bond with themselves to form interhalogen compounds. Here we look at some of these halogen compounds. 

When a metal such as sodium (Na) or calcium (Ca) reacts with a nonmetal such as chlorine (Cl2), the product is ordinarily an ionic compound. The formula of that compound (e.g., NaCl, CaCl2) shows the simplest ratio between cation and anion (one Na+ ion for one Cl ion one Ca2+ ion for two Cl- ions). In that sense, the formulas of ionic compounds are simplest formulas. Notice that the symbol of the metal (Na, Ca) always appears first in the formula, followed by that of the nonmetal. 

When two nonmetals combine with each other, the product is most often a binary molecular compound. There is no simple way to deduce the formulas of such compounds. There is, however, a systematic way of naming molecular compounds that differs considerably from that used with ionic compounds. 

We can often decide whether a substance is an ionic compound or a molecular compound by examining its formula. Binary molecular compounds are typically formed from two nonmetals (such as hydrogen and oxygen, the elements in water). Ionic compounds are typically formed from the combination of a metallic element with nonmetallic elements (such as the combination of potassium with sulfur and oxygen to form potassium sulfate, K2S04). Ionic compounds typically contain one metallic element the principal exceptions are compounds containing the ammonium ion, such as ammonium nitrate, which are ionic even though all the elements present are nonmetallic. 

Elements at the right of the p block have characteristically high electron affinities they tend to gain electrons to complete closed shells. Except for the metalloids tellurium and polonium, the members of Groups 16/VI and 17/VII are nonmetals (Fig. 1.62). They typically form molecular compounds with one another. They react with metals to form the anions in ionic compounds, and hence many of the minerals that surround us, such as limestone and granite, contain anions formed from non-metals, such as S2-, CO,2-, and S042-. Much of the metals industry is concerned with the problem of extracting metals from their combinations with nonmetals. 

Carbon forms ionic carbides with the metals of Groups 1 and 2, covalent carbides with nonmetals, and interstitial carbides with d-block metals. Silicon compounds are more reactive than carbon compounds. They can act as Lewis acids. 

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