Avogadro’s Hypothesis (Avogadro’s Law)

 

Avogadro’s Hypothesis—a cornerstone of chemistry and physics—explains the relationship between the volume of gases and the number of particles they contain. This powerful idea makes sense of the “mole concept” and the fundamental laws of gases.

What is Avogadro’s Hypothesis?

Formulated by Amedeo Avogadro in 1811, Avogadro’s Hypothesis (or Avogadro’s Law) states:
“Equal volumes of all gases, at the same temperature and pressure, contain an equal number of molecules.”

In simple words: If you take any two gases at the same temperature and pressure, and their volumes are equal, then the number of molecules in both samples is also equal.

Mathematical Expression of Avogadro’s Law

Mathematically, Avogadro’s Law can be written as:
V ∝ n   or   V/n = k
Where:

  • V = Volume of the gas
  • n = Number of moles of the gas
  • k = constant (for fixed T and P)

Importance of Avogadro’s Law

  • Foundation of the mole concept: Defines the amount of substance (1 mole = 6.022 × 10²³ particles).
  • Allows chemists to calculate molecular masses by comparing gas volumes.
  • Helps explain the ideal gas law: PV = nRT.
  • Critical for stoichiometry—balancing chemical equations with volumes of gases.
  • Useful in industry (gas cylinders, air bags, and chemical reactions involving gases).

Historical Background

  • Amedeo Avogadro (Italy, 1811): First to propose that equal volumes of gases have equal numbers of molecules.
  • Avogadro’s idea was not widely accepted until 50 years later, when Stanislao Cannizzaro clarified atomic and molecular masses using this law.

Avogadro Constant and the Mole

  • Avogadro Constant (NA): 6.022 × 10²³ mol−1 (number of particles in one mole of any substance).
  • At standard temperature and pressure (STP: 0°C, 1 atm), 1 mole of any ideal gas occupies 22.4 liters.
  • Used for converting between number of particles, moles, and gas volumes.

Formula: Number of particles = n × NA

Applications of Avogadro’s Law

  • Calculating molecular weights of gases.
  • Comparing volumes of gases in chemical reactions (e.g., hydrogen + oxygen → water).
  • Determining gas densities and molar masses.
  • Industrial gas preparation, storage, and usage.

Common Misconceptions

  • Not only “same gases”—any gases with same volume, temperature, and pressure will have same number of molecules.
  • Avogadro’s law applies to ideal gases; real gases behave differently under high pressure/low temperature.
  • Volume and number of molecules are directly proportional, not mass.

Practice Questions

  1. State Avogadro’s hypothesis and explain its significance in determining molecular formulae.
  2. How many molecules are present in 44.8 liters of oxygen gas at STP?
  3. At STP, 5.6 L of a gas weighs 12 g. What is the molar mass of the gas?
  4. If 2 liters of nitrogen react with 6 liters of hydrogen, what volume of ammonia is produced (all gases measured at same T & P)?

Summary

Avogadro’s Hypothesis revolutionized science by linking the volume of gases to the number of molecules, leading to the powerful mole concept. It is fundamental for chemistry, physics, and real-world gas applications—master it for academic excellence!

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Last modified: Friday, 18 July 2025, 3:35 PM