Some Basic Concepts of Chemistry

'Chemistry is the melodies you can play on vibrating strings.' — Michio Kaku

1. Chapter Overview

Chemistry is the study of MATTER and its TRANSFORMATIONS. This FOUNDATIONAL chapter introduces the LANGUAGE and TOOLS of chemistry: the MOLE CONCEPT (counting atoms and molecules), EMPIRICAL and MOLECULAR FORMULAS, STOICHIOMETRY (quantitative relationships in reactions), and the LIMITING REAGENT concept. Master these — they are used in EVERY subsequent chemistry chapter.

2. Matter and Its Classification

States of Matter

Pure Substances vs Mixtures

• Pure substances: Fixed composition, distinct properties
  • Elements: Made of ONE type of atom (H, O, Fe)
  • Compounds: Two+ elements chemically combined (H₂O, NaCl)
• Mixtures: Variable composition, physical combination
  • Homogeneous: Uniform throughout (air, salt solution)
  • Heterogeneous: Non-uniform (sand and water, oil and water)

3. Measurement and SI Units

SI Base Units Used in Chemistry

Mass and Weight

• Mass: Amount of matter (CONSTANT everywhere)
• Weight: Mass × g (VARIES with location)

4. Mole Concept — The Chemist's Counting Unit

Avogadro's Number

• 1 mole = 6.022 × 10²³ particles (atoms, molecules, ions)
• N_A = 6.022 × 10²³ mol⁻¹ (Avogadro constant)

Molar Mass

• Mass of ONE mole of a substance
• Numerically EQUAL to atomic/molecular mass in grams
• Examples: H₂O = 18 g/mol, CO₂ = 44 g/mol, NaCl = 58.5 g/mol

Key Formulas

• Number of moles (n) = Given mass (m) / Molar mass (M)
• n = Number of particles / N_A
• n = Volume of gas (at STP) / 22.4 L (for gases at 0°C, 1 atm)

Worked Problem

Q: How many moles and molecules are in 9 g of water? A: n = 9/18 = 0.5 mol. Molecules = 0.5 × 6.022 × 10²³ = 3.011 × 10²³ molecules.

5. Empirical and Molecular Formulas

• Empirical Formula: Simplest WHOLE-NUMBER ratio of atoms in a compound
• Molecular Formula: ACTUAL number of atoms in a molecule
• Relation: Molecular formula = n × Empirical formula (n = 1, 2, 3...)

Steps to Determine Empirical Formula

1. Convert given mass percentages to GRAMS
2. Divide by ATOMIC MASS to get moles
3. Divide ALL mole values by the SMALLEST mole value
4. Multiply to get whole numbers if needed

Worked Problem

Q: A compound has C = 40%, H = 6.67%, O = 53.33%. Find EF. If M = 60 g/mol, find MF. A: Moles: C = 40/12 = 3.33, H = 6.67/1 = 6.67, O = 53.33/16 = 3.33. Ratio: C:H:O = 1:2:1. EF = CH₂O. n = 60/(12+2+16) = 60/30 = 2. MF = C₂H₄O₂.

6. Stoichiometry and Balancing Equations

Balancing Chemical Equations

• Law of Conservation of Mass: Atoms are NEITHER created nor destroyed
• Balanced equation: Equal atoms of each element on BOTH sides

Stoichiometric Calculations

• Mole ratios from balanced equations direct the calculations
• Mass-Mass problems: Mass → Moles → Mole ratio → Mass

Worked Problem

Q: How many grams of O₂ are needed to completely burn 24 g of CH₄? A: CH₄ + 2O₂ → CO₂ + 2H₂O. n(CH₄) = 24/16 = 1.5 mol. n(O₂) = 2 × 1.5 = 3 mol. Mass O₂ = 3 × 32 = 96 g.

7. Limiting Reagent

• Definition: The reactant that gets COMPLETELY CONSUMED first, LIMITING the amount of product formed
• How to find: Calculate moles of EACH reactant. Divide by stoichiometric coefficient. The Smallest value = limiting reagent

Worked Problem

Q: 2 g H₂ reacts with 16 g O₂ to form water. Find limiting reagent and mass of water formed. A: 2H₂ + O₂ → 2H₂O. n(H₂) = 2/2 = 1 mol. n(O₂) = 16/32 = 0.5 mol. Required H₂ for 0.5 mol O₂ = 1 mol. Available H₂ = 1 mol. BOTH consumed completely. Water = 1 mol = 18 g.

8. Concentration Units

9. Common Mistakes

1. Mole ≠ Mass: One mole is 6.022×10²³ particles, NOT 6.022×10²³ grams
2. STP conditions: T = 0°C (273 K), P = 1 atm (1.013 bar). Molar volume = 22.4 L
3. Limiting reagent ≠ smaller mass: You must convert to moles and use stoichiometric ratios
4. Molarity is temperature-dependent (volume changes with T); molality is NOT
5. Empirical formula ≠ molecular formula: Many compounds share the same EF (e.g., CH₂O for sugars)

10. CBSE Exam Focus

1. Mole concept numericals (3/5-mark)
2. Empirical and molecular formula determination (5-mark)
3. Stoichiometry — mass-mass, mass-volume calculations
4. Limiting reagent problems (3/5-mark)
5. Concentration units — molarity, mole fraction (3-mark)

11. Key Formulas

• n = m/M = N/N_A = V/22.4 (STP)
• N_A = 6.022 × 10²³ mol⁻¹
• MF = n × EF
• M = n/V(L)
• m = n/m_solvent(kg)

12. Self-Test (5+ Q&A)

Q1: Calculate the mass of 0.5 moles of CaCO₃. (Ca = 40, C = 12, O = 16) A: M = 40 + 12 + 48 = 100 g/mol. Mass = 0.5 × 100 = 50 g.

Q2: How many atoms are in 5.6 L of CO₂ at STP? A: n = 5.6/22.4 = 0.25 mol. Molecules = 0.25 × 6.022 × 10²³ = 1.505 × 10²³. Each molecule has 3 atoms. Total atoms = 4.515 × 10²³.

Q3: A compound contains 92.3% C and 7.7% H by mass. Find EF. If vapour density = 13, find MF. A: C = 92.3/12 = 7.69, H = 7.7/1 = 7.7. Ratio = 1:1. EF = CH. Molar mass = 2 × VD = 2 × 13 = 26. n = 26/13 = 2. MF = C₂H₂ (acetylene).

Q4: Explain why molarity is temperature-dependent but molality is not. A: Molarity uses volume of solution, which EXPANDS with temperature. Molality uses mass of solvent, which is temperature-independent.

Q5: Define limiting reagent with an example. A: The reactant completely consumed first in a reaction, determining maximum product. Example: 1 mol N₂ + 1 mol H₂ to make NH₃. Required H₂ = 3 mol but only 1 mol available, so H₂ is limiting.

13. Conclusion

Basic concepts of chemistry are the FOUNDATION for all quantitative chemistry. The mole is the CENTRAL unit that connects the microscopic (atoms/molecules) to the macroscopic (grams/litres). Stoichiometry teaches you to PREDICT product quantities from balanced equations. The limiting reagent tells you what actually limits the reaction. These tools are ESSENTIAL for organic chemistry, physical chemistry, and analytical chemistry.