Metallic Bonding | Chemistry

Najam Academy

28 Sept 202005:42

Summary

TLDRThis video explains the concept of metallic bonding using the electron sea theory. Unlike ionic and covalent bonds, which involve the transfer or sharing of electrons, metallic bonds are formed when metal atoms lose their valence electrons, creating a 'sea' of free-moving electrons around positively charged metal ions. This electron sea holds the metal structure together through electrostatic forces. The video also covers the malleability and ductility of metals, properties that allow them to be shaped and stretched, respectively, due to the free movement of these delocalized electrons.

Takeaways

😀 Ionic bonds are formed when one atom loses an electron and another gains it, resulting in positive and negative ions. Example: Table salt (NaCl).
😀 Covalent bonds occur when two atoms share electrons to form a stable molecule. Example: Water (H2O).
😀 In metallic bonds, metal atoms lose their valence electrons, which form a sea or cloud of free electrons around positive ions.
😀 The electron sea theory explains metallic bonding by describing the electrostatic attraction between delocalized electrons and metal ions.
😀 The smallest unit of ionic compounds is the formula unit, like NaCl, while the smallest unit of covalent compounds is the molecule, like H2O.
😀 Metallic bonds are responsible for key properties of metals such as electrical and thermal conductivity, due to the free movement of electrons.
😀 Metals are malleable, meaning they can be shaped into different forms without breaking, as seen with gold.
😀 Metals are ductile, meaning they can be stretched into thin wires, as seen with copper used in electrical wiring.
😀 The electrostatic force between positive ions and the sea of electrons in metals is what holds the structure together and forms the metallic bond.
😀 Delocalized electrons, which are free to move within a metal, contribute to the metal's ability to conduct electricity and heat.

Q & A

What is the basic concept of a chemical bond as explained in the script?
-A chemical bond is the force that holds atoms together in a compound. The script explains three main types of bonds: ionic bonds (formed by transferring electrons), covalent bonds (formed by sharing electrons), and metallic bonds (formed by the electrostatic attraction between delocalized electrons and positive ions).
How is a metallic bond different from ionic and covalent bonds?
-In metallic bonds, electrons are not transferred or shared between atoms. Instead, they form a 'sea' or 'cloud' of delocalized electrons that move freely around positive ions. This is different from ionic bonds (where electrons are transferred) and covalent bonds (where electrons are shared).
What is the smallest unit in a metallic bond?
-The smallest unit in a metallic bond is the individual atom, such as an iron atom. The atoms lose their valence electrons, forming positive ions, and these ions are held together by the electrostatic attraction to the 'sea' of delocalized electrons.
What does the electron sea theory explain about metallic bonds?
-The electron sea theory explains that in metallic bonds, metal atoms lose their valence electrons, forming positively charged ions. These electrons do not belong to any individual atom but instead form a sea of electrons that move freely and hold the metal together via electrostatic forces.
Why do metals have good electrical conductivity?
-Metals conduct electricity well because the delocalized electrons in the electron sea are free to move throughout the metal lattice, allowing the flow of electric current.
What makes metals malleable and ductile?
-Metals are malleable because their delocalized electrons allow atoms to slide past each other without breaking the bond. They are ductile because the same flexibility allows them to be drawn into wires without breaking.
How does the electrostatic force contribute to metallic bonding?
-The electrostatic force acts between the positively charged metal ions and the 'sea' of delocalized electrons. This force holds the metal atoms together, creating a strong metallic bond.
Can you provide examples of metals that exhibit metallic bonding?
-Yes, examples of metals that exhibit metallic bonding include zinc, copper, and gold. All these metals have a similar structure with a 'sea' of delocalized electrons surrounding positively charged metal ions.
What role do delocalized electrons play in the properties of metals?
-Delocalized electrons are responsible for the high conductivity, malleability, and ductility of metals. Their free movement allows metals to conduct heat and electricity efficiently and also gives metals the ability to change shape without breaking.
Why are metals like gold considered highly malleable?
-Gold is highly malleable because its metallic bonds are flexible, allowing the atoms to slide past one another easily. The delocalized electrons in the 'sea' of electrons facilitate this process, making gold capable of being molded into various shapes, such as jewelry.