Problem 9
Question
Quartz, \(\mathrm{SiO}_{2}\), is a very high melting, hard solid. Place a point for \(\mathrm{SiO}_{2}\) on the bondtype triangle. What type of bonding would you predict to be predominant in quartz?
Step-by-Step Solution
Verified Answer
Based on the analysis, the predominant type of bonding in quartz (SiO2) is covalent, therefore it is placed closer to the covalent vertex on the bond type triangle.
1Step 1: Understanding the Bond Type Triangle
The bond type triangle is a diagram that illustrates the three principal types of chemical bonding: ionic, covalent, and metallic. The three vertices of the triangle each stand for one of the bond types. The position of a substance on this triangle implies its bonding characters.
2Step 2: Quartz Composition and Bonding
In quartz, each silicon (Si) atom is surrounded by four oxygen (O) atoms in a tetrahedral arrangement. This suggests that there is a sharing of electrons between the silicon and oxygen, rather than a full exchange, which would create an ionic bond, or metallic bonding which involves a 'sea of electrons'. Therefore, the predominant bonding in Quartz can be predicted as covalent.
3Step 3: Placement on the Bond Type Triangle
Quartz, having a prevalent covalent bonding, would be positioned closer to the covalent vertex of the triangle.
Key Concepts
Understanding the Bond Type TriangleCovalent BondsQuartz Composition
Understanding the Bond Type Triangle
The bond type triangle is a fundamental concept in chemistry that helps students and scientists alike to predict and understand the nature of the bonds within substances. It represents the three primary types of chemical bonding: ionic, covalent, and metallic. Each corner of the triangle represents one type of bond, with ionic bonding at one vertex, covalent bonding at another, and metallic bonding at the third.
When you place a substance on the triangle, its position provides insight into the bonding characteristics of the substance. A compound that is purely ionic, for example, would be placed at the vertex representing ionic bonds. Conversely, a substance that is purely covalent would be located at the covalent vertex. Metallic bonding, characterized by a delocalized 'sea of electrons', would be positioned at the metallic vertex. The bond type triangle is a valuable tool for visualizing and understanding these bonding properties in a simple, visual way.
When you place a substance on the triangle, its position provides insight into the bonding characteristics of the substance. A compound that is purely ionic, for example, would be placed at the vertex representing ionic bonds. Conversely, a substance that is purely covalent would be located at the covalent vertex. Metallic bonding, characterized by a delocalized 'sea of electrons', would be positioned at the metallic vertex. The bond type triangle is a valuable tool for visualizing and understanding these bonding properties in a simple, visual way.
Covalent Bonds
Covalent bonds are a type of chemical bonding where pairs of electrons are shared by atoms. This sharing allows each atom to achieve a full outer shell of electrons, which is associated with stability in the atomic world. Covalent bonds are often found in molecular compounds like water (H2O), oxygen (O2), and in this case, quartz (SiO2).
In covalent compounds, the strength of the bond can vary based on the number of shared electron pairs. A single covalent bond shares one pair of electrons, a double shares two, and so on. In molecules with covalent bonds, the shape and arrangement of atoms are also determined by the electrons' desire to minimize repulsion between each other, further adding to the diversity seen in covalent compounds.
In covalent compounds, the strength of the bond can vary based on the number of shared electron pairs. A single covalent bond shares one pair of electrons, a double shares two, and so on. In molecules with covalent bonds, the shape and arrangement of atoms are also determined by the electrons' desire to minimize repulsion between each other, further adding to the diversity seen in covalent compounds.
Quartz Composition
Quartz is an abundant mineral composed of silicon dioxide, or SiO2. In its crystal structure, each silicon atom is tetrahedrally coordinated, meaning it is surrounded by four oxygen atoms. This arrangement forms a strong, rigid lattice that gives quartz its excellent stability and high melting point. The silicon-oxygen bonds in quartz are highly covalent because the electrons are shared evenly between the silicon and oxygen atoms.
Despite silicon and oxygen being different elements, the difference in their electronegativities is not enough to create an ionic bond. Quartz does not conduct electricity in its pure state, further implying that its bonds are not metallic. Thus, quartz is a perfect example of covalent bonding, where the atoms create a stable, extensive network by sharing electrons.
Despite silicon and oxygen being different elements, the difference in their electronegativities is not enough to create an ionic bond. Quartz does not conduct electricity in its pure state, further implying that its bonds are not metallic. Thus, quartz is a perfect example of covalent bonding, where the atoms create a stable, extensive network by sharing electrons.