Chapter Menu Section 1Section 1Atomic radius Section 2Section 2 Electronegativity Section 3Section 3 The ionic Bond Section 4Section 4 The Covalent Bond.

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Presentation transcript:

Chapter Menu Section 1Section 1Atomic radius Section 2Section 2 Electronegativity Section 3Section 3 The ionic Bond Section 4Section 4 The Covalent Bond Section 5Section 5 Hybridization Exit Click a hyperlink or folder tab to view the corresponding slides.

Section 6-3 Atomic Radius Atomic size is a periodic trend influenced by electron configuration. For metals, atomic radius is half the distance between adjacent nuclei in a crystal of the element.

Section 6-3 Atomic Radius (cont.) For elements that occur as molecules, the atomic radius is half the distance between nuclei of identical atoms.

Section 6-3 Atomic Radius (cont.) There is a general decrease in atomic radius from left to right, caused by increasing positive charge in the nucleus. Valence electrons are not shielded from the increasing nuclear charge because no additional electrons come between the nucleus and the valence electrons.

Section 6-3 Atomic Radius (cont.)

Section 6-3 Atomic Radius (cont.) Atomic radius generally increases as you move down a group. The outermost orbital size increases down a group, making the atom larger.

Section 8-5 Section Electronegativity Describe how electronegativity is used to determine bond type. electronegativity: the relative ability of an atom to attract electrons in a chemical bond Compare and contrast polar and nonpolar covalent bonds and polar and nonpolar molecules. Generalize about the characteristics of covalently bonded compounds.

Section 8-5 Section Electronegativity (cont.) polar covalent bond A chemical bond’s character is related to each atom’s attraction for the electrons in the bond.

Section 8-5 Electron Affinity, Electronegativity, and Bond Character Electron affinity measures the tendency of an atom to accept an electron. Noble gases are not listed because they generally do not form compounds.

Section 8-5 Electron Affinity, Electronegativity, and Bond Character (cont.) This table lists the character and type of chemical bond that forms with differences in electronegativity.

Section 8-5 Electron Affinity, Electronegativity, and Bond Character (cont.) Unequal sharing of electrons results in a polar covalent bond. polar covalent bond Bonding is often not clearly ionic or covalent.

Section 8-5 Polar Covalent Bonds Polar covalent bonds form when atoms pull on electrons in a molecule unequally. Electrons spend more time around one atom than another resulting in partial charges at the ends of the bond called a dipole.

Section 8-5 Polar Covalent Bonds (cont.) Solubility is the property of a substance’s ability to dissolve in another substance. Polar molecules and ionic substances are usually soluble in polar substances. Non-polar molecules dissolve only in non- polar substances.

Section 8-5 Properties of Covalent Compounds Covalent bonds between atoms are strong, but attraction forces between molecules are weak. The weak attraction forces are known as van der Waals forces. The forces vary in strength but are weaker than the bonds in a molecule or ions in an ionic compound.

Section 8-5 Properties of Covalent Compounds (cont.) Non-polar molecules exhibit a weak dispersion force, or induced dipole. The force between two oppositely charged ends of two polar molecules is a dipole-dipole force. A hydrogen bond is an especially strong dipole-dipole force between a hydrogen end of one dipole and a fluorine, oxygen, or nitrogen atom on another dipole.

Section 8-5 Properties of Covalent Compounds (cont.) Many physical properties are due to intermolecular forces. Weak forces result in the relatively low melting and boiling points of molecular substances. Many covalent molecules are relatively soft solids. Molecules can align in a crystal lattice, similar to ionic solids but with less attraction between particles.

Section 8-5 Properties of Covalent Compounds (cont.) Solids composed of only atoms interconnected by a network of covalent bonds are called covalent network solids. Quartz and diamonds are two common examples of network solids.

A.A B.B C.C D.D STP 2 In general, electronegativity increases as: A.you move up a group B.you move down a group C.you move from right to left across a period D.none of the above

Section 7-1 Section Ion Formation Define a chemical bond. octet rule: atoms tend to gain, lose, or share electrons in order to acquire eight valence electrons chemical bond cation anion Describe the formation of positive and negative ions. Relate ion formation to electron configuration. Ions are formed when atoms gain or lose valence electrons to achieve a stable octet electron configuration.

Section 7-1 Valence Electrons and Chemical Bonds A chemical bond is the force that holds two atoms together.chemical bond Chemical bonds form by the attraction between the positive nucleus of one atom and the negative electrons of another atom.

Section 7-1 Valence Electrons and Chemical Bonds (cont.) Atom’s try to form the octet—the stable arrangement of eight valence electrons in the outer energy level—by gaining or losing valence electrons.

Section 7-1 Positive Ion Formation A positively charged ion is called a cation.cation This figure illustrates how sodium loses one valence electron to become a sodium cation.

Section 7-1 Negative Ion Formation An anion is a negatively charged ion.anion The figure shown here illustrates chlorine gaining an electron to become a chlorine ion.

Section 7-1 Negative Ion Formation (cont.) Nonmetal ions gain the number of electrons required to fill an octet. Some nonmetals can gain or lose electrons to complete an octet.

Section 7-2 Ionic Bonds and Ionic Compounds Describe the formation of ionic bonds and the structure of ionic compounds. compound: a chemical combination of two or more different elements Generalize about the strength of ionic bonds based on the physical properties of ionic compounds. Categorize ionic bond formation as exothermic or endothermic.

Section 7-2 Formation of an Ionic Bond The electrostatic force that holds oppositely charged particles together in an ionic compound is called an ionic bond.ionic bond Compounds that contain ionic bonds are called ionic compounds.ionic compounds Binary ionic compounds contain only two different elements—a metallic cation and a nonmetallic anion.

Section 7-2 Formation of an Ionic Bond (cont.)

Section 8-1 Section The Covalent Bond Apply the octet rule to atoms that form covalent bonds. chemical bond: the force that holds two atoms together Describe the formation of single, double, and triple covalent bonds. Contrast sigma and pi bonds. Relate the strength of a covalent bond to its bond length and bond dissociation energy.

Section 8-1 Section 8.1 The Covalent Bond (cont.) covalent bond molecule sigma bond Atoms gain stability when they share electrons and form covalent bonds. pi bond

Section 8-1 Why do atoms bond? Atoms gain stability when they share electrons and form covalent bonds. Lower energy states make an atom more stable. Gaining or losing electrons makes atoms more stable by forming ions with noble-gas electron configurations. Sharing valence electrons with other atoms also results in noble-gas electron configurations.

Section 8-1 Why do atoms bond? (cont.) Atoms in non-ionic compounds share electrons. The chemical bond that results from sharing electrons is a covalent bond.covalent bond A molecule is formed when two or more atoms bond.molecule

Section 8-1 Why do atoms bond? (cont.) Diatomic molecules (H 2, F 2 for example) exist because two-atom molecules are more stable than single atoms.

Section 8-1 Why do atoms bond? (cont.) The most stable arrangement of atoms exists at the point of maximum net attraction, where the atoms bond covalently and form a molecule.

Section 8-1 Single Covalent Bonds When only one pair of electrons is shared, the result is a single covalent bond. The figure shows two hydrogen atoms forming a hydrogen molecule with a single covalent bond, resulting in an electron configuration like helium.

Section 8-1 Single Covalent Bonds (cont.) The halogens—the group 17 elements—have 7 valence electrons and form single covalent bonds with atoms of other non-metals.

Section 8-1 Single Covalent Bonds (cont.) Atoms in group 16 can share two electrons and form two covalent bonds. Water is formed from one oxygen with two hydrogen atoms covalently bonded to it.

Section 8-1 Single Covalent Bonds (cont.) Atoms in group 15 form three single covalent bonds, such as in ammonia.

Section 8-1 Single Covalent Bonds (cont.) Atoms of group 14 elements form four single covalent bonds, such as in methane.

Section 8-1 Single Covalent Bonds (cont.) Sigma bonds are single covalent bonds.Sigma bonds Sigma bonds occur when the pair of shared electrons is in an area centered between the two atoms.

Section 8-1 Multiple Covalent Bonds Double bonds form when two pairs of electrons are shared between two atoms. Triple bonds form when three pairs of electrons are shared between two atoms.

Section 8-1 Multiple Covalent Bonds (cont.) A multiple covalent bond consists of one sigma bond and at least one pi bond. The pi bond is formed when parallel orbitals overlap and share electrons.pi bond

Section 8-1 The Strength of Covalent Bonds The strength depends on the distance between the two nuclei, or bond length. As length increases, strength decreases.

Section 8-1 The Strength of Covalent Bonds (cont.) The amount of energy required to break a bond is called the bond dissociation energy. The shorter the bond length, the greater the energy required to break it.

A.A B.B C.C D.D Section 8-1 Section Assessment What does a triple bond consists of? A.three sigma bonds B.three pi bonds C.two sigma bonds and one pi bond D.two pi bonds and one sigma bond

A.A B.B C.C D.D Section 8-1 Section Assessment Covalent bonds are different from ionic bonds because: A.atoms in a covalent bond lose electrons to another atom B.atoms in a covalent bond do not have noble-gas electron configurations C.atoms in a covalent bond share electrons with another atom D.atoms in covalent bonds gain electrons from another atom

Section 8-4 atomic orbital: the region around an atom’s nucleus that defines an electron’s probable location hybridization Define hybridization.

Section 8-4 Hybridization Hybridization is a process in which atomic orbitals mix and form new, identical hybrid orbitals.Hybridization Carbon often undergoes hybridization, which forms an sp 3 orbital formed from one s orbital and three p orbitals. Lone pairs also occupy hybrid orbitals.

Section 8-4 Hybridization (cont.) Single, double, and triple bonds occupy only one hybrid orbital (CO 2 with two double bonds forms an sp hybrid orbital).