Chemical Equations: Understanding Molar Ratio

How is the molar ratio determined in a chemical equation?

A. Divide the molecular weight by Avogadro's number

B. Multiply the molecular weight by Avogadro's number

C. Take the square root of the molecular weight

D. Add the molecular weight to Avogadro's number

Answer:

The molar ratio does not directly connect to the molecular weight or Avogadro's number. Molar ratios are determined from the numbers of moles of the substances involved, which can't be calculated from molecular weights with Avogadro's number.

The molar ratio in a chemical equation is a crucial aspect of stoichiometry, which involves the quantitative relationships between reactants and products in a chemical reaction. It represents the ratio of moles of one substance to another in a balanced chemical equation.

When determining a molar ratio, it is essential to look at the coefficients in the balanced chemical equation. These coefficients provide the ratio in which substances react and produce products. For example, in the equation 2H₂ + O₂ → 2H₂O, the molar ratio between H₂ and O₂ is 2:1.

It's important to note that molar ratios are based on the number of moles of each substance involved, not their molecular weights. Avogadro's number and molecular weight are useful for converting between mass and moles, but they do not directly relate to molar ratios.

Therefore, the options provided (dividing the molecular weight by Avogadro's number, multiplying the molecular weight by Avogadro's number, taking the square root of the molecular weight, adding the molecular weight to Avogadro's number) would not help in calculating a molar ratio. To determine a molar ratio accurately, one needs to consider the coefficients from the balanced chemical equation.

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