Chemical Bonds.

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Presentation transcript:

Chemical Bonds

Chemical Bonds Stability in Bonding Types of Bonds Writing Formulas and Naming Compounds

Combined Elements Some of the matter around you is in the form of uncombined elements such as copper, sulfur, and oxygen. Like many other sets of elements, these three elements unite chemically to form a compound when the conditions are right. The green coating on the Statue of Liberty and some old pennies is a result of this chemical change.

New Properties The compound formed when elements combine often has properties that aren’t anything like those of the individual elements. Sodium chloride, for example, is a compound made from the elements sodium and chlorine. Sodium is a shiny, soft metal that reacts violently with water. Chlorine is a poisonous greenish-yellow gas. Would you have guessed that these elements combine to make ordinary table salt?

Formulas A chemical formula tells what elements a compound contains and the exact number of the atoms of each element in a unit of that compound. The compound that you are probably most familiar with is H2O, more commonly known as water. This formula contains the symbols H for the element hydrogen and O for the element oxygen. Notice the subscript number 2 written after the H for hydrogen. A subscript written after a symbol tells how many atoms of that element are in a unit of the compound.

Formulas (2) If a symbol has no subscript, the unit contains only one atom of that element. A unit of H2O contains two hydrogen atoms and one oxygen atom. Look at the formulas for each compound listed in the table. How many atoms of each element are required to form each of the compounds?

Atomic Stability Why do atoms form compounds? An atom is stable when its outer energy level is complete. The atoms of noble gases are unusually stable. Why is this so?

The Unique Noble Gases Look at the electron dot diagrams in the figure. Electron dot diagrams show that they all have a stable, filled outer energy level. Compounds of these atoms rarely form because they are almost always less stable than the original atoms.

Energy Levels and Other Elements When you look at the elements in Groups 1, 2, 13 – 17, you see that each of them falls short of having a stable energy level. Each group contains too few electrons for a stable level of eight electrons. So how can these atoms gain a stable level of eight electrons?

The Octet Rule Atoms with partially stable outer energy levels can lose, gain, or share electrons to obtain a stable outer energy level. They can do this by combining with other atoms that also have partially complete outer energy levels. As a result, each achieves stability. This is known as the Octet Rule. Chemical compounds tend to form so that each atom, by gaining, losing, or sharing electrons, has an octet of electrons in its highest occupied energy level.

Atomic Stability The figure shows the energy levels for sodium and chlorine atoms. When they combine, sodium loses one electron and chlorine gains one electron. By gaining one electron, chlorine now has a stable outer energy level similar to a noble gas.

Atomic Stability (2) Sodium had only one electron in its outer energy level, which it lost to combine with chlorine in sodium chloride. However, look at the next outermost energy level of sodium. This is now the new outer energy level of sodium and it is stable with eight electrons. Sodium and chlorine are stable now because of the exchange of an electron.

Chemical Bonds When atoms gain, lose, or share electrons, an attraction forms between the atoms, pulling them together to form a compound. This attraction is called a chemical bond. A chemical bond is the force that holds atoms together in a compound.

Types of Bonds Remember when atoms gain, lose, or share electrons, an attraction forms between the atoms, pulling them together to form a compound. This attraction is called a chemical bond. A chemical bond is the force that holds atoms together in a compound.

Ionic Bonding An ionic bond is the force of attraction between the opposite charges of the ions in an ionic compound. In an ionic bond, a transfer of electrons takes place. The result of this bond is a neutral compound.

Ionic Bonds The compound as a whole is neutral because the sum of the charges on the ions is zero. In the figure below, the positive charge of the magnesium ion is exactly equal to the negative charge of the two chloride ions. In other words, when atoms form an ionic compound, their electrons are shifted to other atoms, but the overall number of protons and electrons remains equal. Therefore, the compound is neutral.

Ionic Bonding

Ionic Compounds Ionic bonds usually are formed by bonding between metals and nonmetals. Ionic compounds are often crystalline solids with high melting points. At the right are sodium chloride crystals.

Covalent Bonding The attraction that forms between atoms when they share electrons is known as a covalent bond. A neutral particle that forms as a result of electron sharing is called a molecule (water molecule at right). A single covalent bond is made up of two shared electrons. Usually, one of the shared electrons comes from one atom in the bond and the other comes from the other atom in the bond.

Covalent Bonding (2) A covalent bond also can contain more than one pair of electrons. An example of this is the bond in nitrogen (N2) shown below. A nitrogen atom has five electrons in its outer energy level and needs to gain three electrons to become stable. It does this by sharing its three electrons with another nitrogen atom. When each atom contributes three electrons to the bond, the bond contains six electrons, or three pairs of electrons. Each pair of electrons represents a bond. Therefore, three pairs of electrons represent three bonds, or a triple bond.

Covalent Bonding (3) Covalent bonds form between nonmetal elements. Many covalent compounds are liquids or gases at room temperature. Propane gas and isopropyl alcohol are examples of covalently bonded compounds.

Covalent Bonding (4) Electrons are not always shared equally between atoms in a covalent bond. In the picture at right, the chlorine atom has a stronger attraction for electrons than hydrogen atom do. As a result, the electrons shared in hydrogen chloride will spend more time near the chlorine atom than near the hydrogen atom.

Covalent Bonding (5) A polar molecule is one that has a slightly positive end and a slightly negative end although the overall molecule is neutral. Water, like hydrogen chloride, is a polar molecule. A nonpolar molecule is one in which electrons are shared equally in bonds. An example would be oxygen gas, O2.

Writing Formulas and Naming Compounds Binary Ionic Compounds Binary Covalent Compounds

Binary Ionic Compounds The first formulas of compounds you will write are for binary ionic compounds. A binary compound is one that is composed of two elements. Potassium iodide (KI) would be an example. Before you can write a formula, you must have all the needed information at your fingertips. You need to know which elements are involved and what number of electrons they lose, gain, or share in order to become stable. The relationship between an element’s position on the periodic table and the number of electrons it gains or loses is called the oxidation number of an element.

Binary Ionic Compounds (2) An oxidation number tells you how many electrons an atom has gained, lost to become stable. For ionic compounds the oxidation number is the same as the charge on the ion. For example, a sodium ion has a charge of 1+ and an oxidation number of 1+. When writing formulas it is important to remember that although the individual ions in a compound carry charges, the compound itself is neutral. A formula must have the right number of positive ions and the right number of negative ions so the charges balance.

Criss – Cross Method 1. Write the symbol of the element or polyatomic ion (ions containing more than one atom) that has the positive oxidation number or charge. 2. Write the symbol of the element or polyatomic ion with the negative oxidation number. 3. The charge (without the sign) of one ion becomes the subscript of the other ion. Reduce the subscripts to the smallest whole numbers that retain the ratio of ions.