Answer:
Ionic
Explanation:
Step 1: Define
1s²2s¹ is Lithium (Li)
1s²2s²2p⁵ is Chlorine (Cl)
Step 2: RxN
2Li (s) + Cl₂ (g) → 2LiCl (s)
Step 3: Identify
LiCl is a metal and a non-metal bonded together. Therefore, it will be an ionic bond. The Lithium would transfer it's electron to Chlorine (since it wants a full outer shell 0f 8 and it currently as 7) and form a salt.
B. Drying wood in a shed
C. Melting ice to obtain water
D. Evaporating alcohol into vapor
Coal combustion causes a chemical change. Burning coal in a furnace will result in a chemical change. Therefore, option A is correct.
A chemical change is the transformation of one material into another, the formation of new materials with different properties, and the formation of one or more new substances. It occurs when one substance reacts with another to form a new substance.
Coal combustion causes a chemical change. The main component, carbon, is converted to carbon dioxide when coal is burned. This process is irreversible.
When carbon is burned, it produces carbon dioxide, and hydrogen produces water. Each of these reactions generates a different amount of heat. Because this process cannot be reversed, coal combustion is a chemical change.
Thus, option A is correct.
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When a metal reacts with a nonmetal, the resulting reaction often involves the transfer of electrons from the metal to the nonmetal, leading to the formation of ions with different charges. This type of reaction is known as a redox (reduction-oxidation) reaction. Redox reactions involve changes in the oxidation states (or oxidation numbers) of the elements involved, and they are fundamental in understanding chemical reactions.
Here's why such reactions are typically redox reactions:
Metals tend to lose electrons: Metals are located on the left side of the periodic table, and they have relatively low electronegativities. This means they have a tendency to lose electrons to achieve a stable, positively charged ion (cation) with a filled outer electron shell.
Nonmetals tend to gain electrons: Nonmetals are usually located on the right side of the periodic table and have higher electronegativities. They have a tendency to gain electrons to achieve a stable, negatively charged ion (anion) with a filled outer electron shell.
When a metal reacts with a nonmetal, the metal atoms lose electrons (undergo oxidation) and form positively charged ions, while the nonmetal atoms gain electrons (undergo reduction) and form negatively charged ions. This exchange of electrons leads to a change in the oxidation states of the elements involved, and it's the hallmark of a redox reaction.
For example, consider the reaction between sodium (a metal) and chlorine (a nonmetal) to form sodium chloride:
2Na (sodium) + Cl2 (chlorine) → 2NaCl (sodium chloride)
In this reaction, sodium loses one electron to become Na+ (oxidation), while chlorine gains one electron to become Cl- (reduction). The transfer of electrons between the two elements results in the formation of the ionic compound sodium chloride, and it's a classic example of a redox reaction.
While many metal-nonmetal reactions are redox reactions, it's important to note that not all reactions between metals and nonmetals involve a transfer of electrons. Some reactions can be purely ionic or involve covalent bonding without a net exchange of electrons, depending on the specific elements and conditions involved. However, the tendency for metals to lose electrons and nonmetals to gain electrons often makes redox reactions a common occurrence in these reactions