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Hydrogen covalent bond with

Towards a simple Lewis base, for example the proton, phosphine is a poorer electron donor than ammonia, the larger phosphorus atom being less able to form a stable covalent bond with the acceptor atom or molecule. Phosphine is, therefore, a much weaker base than ammonia and there is no series of phosphonium salts corresponding to the ammonium salts but phosphonium halides. PH4X (X = Cl, Br, I) can be prepared by the direct combination of phosphine with the appropriate hydrogen halide. These compounds are much more easily dissociated than ammonium halides, the most stable being the iodide, but even this dissociates at 333 K PH4I = PH3 -t- HI... [Pg.226]

Chemical compounds that contain methylol groups (-CH2 OH) form stable, covalent bonds with cellulose fibers. Those compounds are well known and widely used in textile chemistry. Hydrogen bonds with cellulose can be formed in this reaction as well. The treatment of cellulose with methylolmelamine compounds before forming cellulose unsaturated polyesters (UP) composites decreases the moisture pickup and increases the wet strength of reinforced plastic [48,49]. [Pg.797]

Here is a situation we haven t met before. After using the two available partially filled orbitals to form covalent bonds with hydrogen atoms, there remains a vacant valence orbital. In the electron dot formulation (36) we see that the carbon atom finds itself near only six electrons in CH2. The valence orbitals will accommodate eight electrons. Because one valence or-... [Pg.284]

Hydrogen is unusual because it can form both a cation (1I+) and ail anion (11 ). Moreover, its intermediate electronegativity (2.2 on the Pauling scale) means that it can also form covalent bonds with all the nonmetals and metalloids. Because hydrogen forms compounds with so many elements (Table 14.2 also see Section 14.2), we shall meet more of its compounds when we study the other elements. [Pg.706]

B Aluminum forms an amphoteric oxide in which it has the oxidation state +3 therefore, aluminum is the element. 14.3B Hydrogen is a nonmetal and a diatomic gas at room temperature. It has an intermediate electronegativity (x — 2.2), so it forms covalent bonds with nonmetals and forms anions in combination with metals. In contrast, Group 1 elements are solid metals that have low electronegativities and form cations in combination with nonmetals. [Pg.979]

If two atoms have the same electronegativity, then the bond between them is purely covalent. Hydrogen, for instance, occurs as two joined atoms, H-H. Since both atoms in the molecule have the same electronegativity, they form a pure covalent bond with two electrons shared equally by the atoms. [Pg.85]

The small size of the proton relative to its charge makes the proton very effective in polarizing the molecules in its immediate vicinity and consequently leads to a very high degree of solvation in a polar solvent. In aqueous solutions, the primary solvation process involves the formation of a covalent bond with the oxygen atom of a water molecule to form a hydronium ion H30 +. Secondary solvation of this species then occurs by additional water molecules. Whenever we use the term hydrogen ion in the future, we are referring to the HsO + species. [Pg.221]

Figure 10-4 shows the hybridization that occurs in ethylene, H2C=CH2. Each carbon has sp2 hybridization. On each carbon, two of the hybrid orbitals overlap with an s-orbital on a hydrogen atom to form a carbon-to-hydrogen covalent bond. The third sp2 hybrid orbital overlaps with the sp2 hybrid on the other carbon to form a carbon-to-carbon covalent bond. Note that each carbon has a remaining p-orbital that has not undergone hybridization. These are also overlapping above and below a line joining the carbons. [Pg.150]

This Lewis structure shows methane, the simplest organic compound. The carbon atom has four valence electrons, and it obtains four more electrons by forming four covalent bonds with the four hydrogen atoms. [Pg.5]

In the adsorption of water molecules on metal electrodes in aqueous solutions, unpaired electrons in the frontier orbital of oi en atoms in water molecules form covalent bonds with surface metal atoms. Then, the adsorbate water molecules act as a Lewis base (covalent-electron providers) and the adsorbent surface metal atoms act as a Lewis acid (covalent-electron receivers). Since the bond energy (0.4 to 0.7 eV) of water molecules with the surface metal atoms is close to the energy of hydrogen bond (0.2 to 0.4 eV) between water molecules, the adsorbed water molecule is combined not only with the metallic surface atoms but also with the acijacent water molecules to form a bi-molecular layer rather than a monomer layer as shown in Fig. 5-31. [Pg.158]

Fig. 4.18 The different degree to which electrons move collectively in various forms of carbon material as evidenced by distinct intensity of the plasmon peak located about 6 eV in EELS spectra (arrow). Hydrogen atoms can make less strong covalent bonds with participation of n electrons if the interplanar distance is increased in layered graphitic nanocrystals as seen in carbon nanosheUs (frame in Fig. 4.17) and in disordered graphitic carbons (Sect. 4.3.1). After [60]... Fig. 4.18 The different degree to which electrons move collectively in various forms of carbon material as evidenced by distinct intensity of the plasmon peak located about 6 eV in EELS spectra (arrow). Hydrogen atoms can make less strong covalent bonds with participation of n electrons if the interplanar distance is increased in layered graphitic nanocrystals as seen in carbon nanosheUs (frame in Fig. 4.17) and in disordered graphitic carbons (Sect. 4.3.1). After [60]...
During the chemisorptions of Ru3(CO)i2 or Os3(CO)i2 on silica, the first step with the surface silanols was to produce a covalent bonding with the silica surface by oxidative addition of the silanol group to the metal-metal bond of the clusters. The nature of surface molecular species [=Si-0)(M3( x-H)(CO)io)j covalently linked to the silica surface (M = Ru, Os) was clearly defined and structurally characterized by a series of physical and chemical techniques, including mass balance taking into account the evolution of two molecules of CO and one molecule of hydrogen [27, 33, 35]. [Pg.10]

The dihydrogen molecule is the smallest molecule in existence. It has a strong covalent bond with a dissociation energy of 103 kcal mol [1], In a hydrogenation reaction, this bond has to be broken and two new C-H bonds are formed, one of the simplest forms of chemical reaction. [Pg.360]

The two atoms in the hydrogen molecule are identical, so we have a covalent bond with equal sharing of the electrons by the two nuclei. When the two atoms are not identical, such as in HCl, we have a partially ionic bond with unequal sharing of electrons—which are clustered more around the Cl nucleus than the H nucleus. [Pg.81]

In the same year that Bronsted and Lowry proposed their definition of acids and bases, an American chemist named Gilbert Lewis proposed an alternative definition that not only encompassed Bronsted-Lowry theory but also accounted for acid-base reactions in which a hydrogen ion isn t exchanged. Lewis s definition relies on tracking lone pairs of electrons. Under his theory, a base is any substance that donates a pair of electrons to form a coordinate covalent bond with another substance, while an acid is a substance that accepts that electron pair in such a reaction. As we explain in Chapter 5, a coordinate covalent bond is a covalent bond in which both of the bonding electrons are donated by one of the atoms forming the bond. [Pg.225]

Salt and chelate formation with edetate (ethylenediaminetetraacetate, EDTA). A In a solution of calcium disodium salt of EDTA, the sodium and hydrogen ions are chemically and biologically available. B In solutions of calcium disodium edetate, calcium is bound by coordinate-covalent bonds with nitrogens as well as by the usual ionic bonds. C In the lead-edetate chelate, lead is incorporated into five heterocyclic rings. [Pg.1238]


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