Stoikiometri (1) | Menentukan Ar dan Mr | Kimia Kelas 10

Kimatika

6 Apr 202118:43

Summary

TLDRThis educational video script focuses on teaching stoichiometry to 10th-grade chemistry students. It covers the calculation of relative atomic mass (Ar) and relative molecular mass (Mr). The script explains how to determine Ar by comparing the average mass of an atom to 1/12th the mass of a carbon-12 atom. It also demonstrates how to calculate Mr by summing the Ar of all atoms in a molecule. The video includes examples to clarify concepts, such as calculating the Ar of silver and determining the abundance of copper isotopes. It concludes with practical problems to solve, like finding Mr for various compounds, reinforcing the lesson's understanding.

Takeaways

🔬 The video discusses stoichiometry in chemistry, focusing on determining relative atomic mass (Ar) and relative molecular mass (Mr).
📚 Relative atomic mass (Ar) is the average mass of an atom compared to 1/12th the mass of a carbon-12 atom.
🧬 The script explains how to calculate Ar using the formula Ar = (mass of one atom X / (1/12 * mass of one C12 atom)).
🌐 It covers the concept that Ar can also be determined by considering the natural abundance and mass of isotopes.
📈 An example is provided to calculate the relative atomic mass of silver using the given mass of C12 and silver.
🔋 The script includes a calculation for boron's relative atomic mass, considering its isotopes and their abundance.
🧩 The video also addresses how to determine the relative molecular mass (Mr) of a molecule by summing the relative atomic masses of all atoms within it.
🍬 An example calculation is shown for the Mr of glucose (C6H12O6) using the known Ar values for carbon, hydrogen, and oxygen.
🌿 The process is further illustrated with the calculation of Mr for Fe2(SO4)3 and K2SO4·2H2O, considering multiple atoms and their respective Ar values.
📊 The video concludes with a summary that emphasizes the importance of knowing the number of atoms and their Ar values to calculate Mr accurately.

Q & A

What is the topic discussed in the video?
-The video discusses stoichiometry in chemistry for 10th-grade students, focusing on determining relative atomic mass (Ar) and relative molecular mass (Mr).
What is the relative atomic mass (Ar)?
-Relative atomic mass (Ar) is the ratio of the average mass of a specific atom to 1/12 of the mass of an atom of carbon-12.
How is the relative atomic mass of an element calculated?
-The relative atomic mass of an element is calculated by taking the average mass of one atom of the element and dividing it by 1/12 of the mass of one carbon-12 atom.
What is the significance of carbon-12 in determining atomic mass?
-Carbon-12 is significant because its mass is used as a standard to determine the atomic mass of other elements, with its mass set to exactly 12 atomic mass units (amu).
How can you calculate the relative atomic mass of silver given the mass of one atom of carbon-12 and one atom of silver?
-You can calculate the relative atomic mass of silver by dividing the average mass of one silver atom by 1/12 of the mass of one carbon-12 atom.
What is the formula used to calculate the relative atomic mass when there are multiple isotopes of an element?
-The formula used to calculate the relative atomic mass when there are multiple isotopes is Ar = (percentage of isotope 1 * mass of isotope 1) + (percentage of isotope 2 * mass of isotope 2) + ...
What is the relative molecular mass (Mr)?
-Relative molecular mass (Mr) is the average mass of a molecule relative to 1/12 of the mass of a carbon-12 atom, which is the sum of the relative atomic masses of all atoms in the molecule.
How do you determine the relative molecular mass of a compound?
-To determine the relative molecular mass of a compound, you multiply the relative atomic mass of each atom in the molecule by the number of atoms of that element in the molecule and then sum these values.
What is the relative molecular mass of C6H12O6?
-The relative molecular mass of C6H12O6 is calculated by multiplying the number of carbon atoms (6) by their relative atomic mass (12), adding the number of hydrogen atoms (12) times their relative atomic mass (1), and adding the number of oxygen atoms (6) times their relative atomic mass (16), which sums up to 180.
How can you find the percentage abundance of isotopes in nature if given the relative atomic mass?
-You can find the percentage abundance of isotopes in nature by setting up an equation that represents the weighted average of the isotopes' masses equaling the relative atomic mass and solving for the unknown percentage abundance.
What is the relative molecular mass of K2SO4·2H2O?
-The relative molecular mass of K2SO4·2H2O is calculated by summing the relative atomic masses of 2 potassium atoms, 1 sulfur atom, 4 oxygen atoms in the sulfate ion, and 2 water molecules (2 hydrogen atoms and 2 oxygen atoms), which results in a total of 474.