INTRAMOLECULAR BONDING - COVALENT, IONIC, METALLIC

Neural Academy

4 Jan 202106:06

Summary

TLDRThis script explores the fundamental concept of chemical bonding, focusing on intramolecular bonds. It explains how atoms achieve stability by completing their outer electron orbits through covalent, ionic, and metallic bonds. Covalent bonds are common in organic molecules, with polar and nonpolar variations depending on electronegativity differences. Ionic bonds form between atoms with significant electronegativity differences, like in sodium chloride, and metallic bonds occur in metals, characterized by a 'sea of electrons.' The script also highlights the properties and formation conditions of each bond type, emphasizing their distinct characteristics.

Takeaways

🔬 Bonding occurs to achieve the most stable electron configuration, typically the octet rule in the valence shell.
🔗 Intramolecular bonds link atoms within a compound, while intermolecular forces attract separate molecules to each other.
🧪 Covalent bonds are formed by the sharing of electron pairs between atoms, creating molecular orbitals and molecules.
🌐 Covalent bonds can result in various structures, including linear, branched, cross-linked, and crystal lattices.
💎 Allotropes, like graphite and diamond, are different forms of the same element with distinct bonding and properties.
⚛️ Covalent bonds can be polar or nonpolar, depending on the electronegativity difference between the atoms involved.
🌡 Polar covalent bonds result in molecules with higher melting and boiling points and are soluble in polar solvents.
🌫 Nonpolar covalent bonds form between atoms with similar electronegativity, leading to lower melting and boiling points and solubility in nonpolar solvents.
🚫 Covalent bonds form when electronegativity differences are insufficient for electron transfer, and atoms have high ionization energies.
⚡ Ionic bonds result from the transfer of electrons from a less to a more electronegative atom, forming ions that attract each other.
🧲 Ionic compounds can dissociate into ions when in solution, and their formation likelihood depends on atomic radius and electronegativity differences.
🌌 Metallic bonds involve positively charged atoms sharing a 'sea' of valence electrons, common in metals, metalloids, and alloys.

Q & A

Why do atoms form bonds with each other?
-Atoms form bonds to achieve stability by completing their outermost electron orbits, thus obtaining the octet configuration in the valence shell and satisfying the octet rule.
What is the difference between intramolecular bonds and intermolecular forces?
-Intramolecular bonds are the chemical bonds that bond atoms to other atoms within a molecule, creating compounds. Intermolecular forces, on the other hand, are the forces that attract atoms and molecules to other atoms and molecules.
What is a covalent bond and how is it formed?
-A covalent bond, also known as a molecular bond, is formed when a pair or pairs of electrons are shared between two atoms to form a covalently bonded species or a molecular compound, resulting in a new molecular orbital extending around the nuclei of both atoms.
How do covalent bonds differ between polar and nonpolar bonds?
-Covalent bonds are polar if they are formed between two different non-metal atoms with different electronegativities, resulting in unequal electron sharing and a molecule with a slight charge distribution. Nonpolar covalent bonds are formed between atoms with the same or very similar electronegativities, sharing electrons equally.
What are allotropes and how do they relate to covalent bonding?
-Allotropes are different forms of an element in its natural state. They differ in the way atoms form covalent bonds, such as graphite where carbon forms three covalent bonds with delocalized electrons in planes, and diamond where carbon atoms form tetrahedral covalent bonds.
Why do substances with polar covalent bonds have higher melting and boiling points?
-Substances with polar covalent bonds have higher melting and boiling points because the polar bonds create stronger intermolecular forces due to the uneven distribution of charge, which requires more energy to overcome.
What is the role of electronegativity in the formation of covalent bonds?
-Electronegativity determines the tendency of an atom to attract a shared pair of electrons in a bond. It influences whether a bond is polar or nonpolar and affects the distribution of charge within the molecule.
What is ionization energy and how does it relate to the formation of covalent bonds?
-Ionization energy is the energy needed to remove an electron from a neutral atom to form a positively charged ion. The difference in ionization energies between atoms influences whether they form covalent bonds or ionic bonds, with covalent bonds more likely when the difference is small.
How does the formation of ionic bonds differ from covalent bonds?
-Ionic bonds form between atoms with significantly different electronegativities, typically a metal and a non-metal, where one atom transfers electrons to the other, resulting in the formation of an anion and a cation that are attracted to each other due to their opposite charges.
What is a metallic bond and how does it differ from covalent and ionic bonds?
-A metallic bond is formed between metals, metalloids, and alloys where positively charged atoms share valence electrons that move freely throughout the structure, described as a 'sea of electrons.' This is different from covalent bonds, which involve electron sharing, and ionic bonds, which involve electron transfer.
Why do covalent bonds rarely break spontaneously?
-Covalent bonds rarely break spontaneously because they are stronger than ionic bonds due to the direct sharing of electrons between atoms, creating a stable molecular orbital.