Some Basic Concepts of Chemistry: Guide for Class 11, JEE & NEET | Chemca

Some Basic Concepts of Chemistry: The Ultimate Guide for Class 11, JEE, and NEET

Mastering chemistry starts with a rock-solid foundation. Whether you are a Class 11 student just beginning your journey or a JEE/NEET aspirant looking to polish your fundamentals, the chapter "Some Basic Concepts of Chemistry" is the gateway to the entire subject.

In this guide, we break down the essential topics, from the laws of chemical combination to the ever-important Mole Concept, and provide you with exclusive resources to ace your exams.

Why is this Chapter Important?

This chapter isn't just a requirement for your syllabus; it’s the language of chemistry. It introduces the quantitative side of science. Without understanding molarity, stoichiometry, or atomic masses, Physical Chemistry becomes an uphill battle.

If you are looking for a deep dive into the syllabus-specific notes, check out our Detailed Guide on Basic Concepts of Chemistry for JEE & NEET.

Core Topics You Must Master

1. Matter and Its Classification

Matter is anything that has mass and occupies space. Understanding the difference between mixtures (homogeneous and heterogeneous) and pure substances (elements and compounds) is fundamental to identifying how chemicals react.

2. The Laws of Chemical Combination

Chemistry is governed by rules. These laws explain how elements combine to form compounds:

• Law of Conservation of Mass: Mass is neither created nor destroyed.
• Law of Definite Proportions: A compound always contains the same elements in the same proportion by mass.
• Law of Multiple Proportions: Formulated by Dalton, this explains how elements like Carbon and Oxygen can form both \(CO\) and \(CO_2\).

3. Dalton’s Atomic Theory

Dalton proposed that matter consists of indivisible atoms. While we now know about subatomic particles, his theory laid the groundwork for the concept of atomic mass and chemical reactions.

4. Atomic and Molecular Masses

• Atomic Mass: Expressed in \(u\) (unified mass), it is relative to \(1/12^{th}\) of the mass of a Carbon-12 atom.
• Molecular Mass: The sum of atomic masses of the elements in a molecule. For example, for \(H_2O\): \((2 \times 1.008) + 16.00 = 18.016 \, u\).

The Heart of Chemistry: The Mole Concept

The Mole is the bridge between the microscopic world of atoms and the macroscopic world of the laboratory. One mole of any substance contains exactly \(6.022 \times 10^{23}\) particles. This number is known as Avogadro’s Number (\(N_A\)).

\[\text{Number of Moles (n)} = \frac{\text{Given Mass (m)}}{\text{Molar Mass (M)}}\]

Struggling with the math? Don't worry! We have prepared a dedicated resource for you. Download our Chemca Formula Sheet: Mole Concept & Stoichiometry to keep all the vital equations at your fingertips.

Empirical and Molecular Formulas

• Empirical Formula: Represents the simplest whole-number ratio of various atoms present in a compound.
• Molecular Formula: Shows the exact number of atoms of different elements present in a molecule.

Relationship: \(\text{Molecular Formula} = n \times (\text{Empirical Formula})\), where \(n\) is a simple whole number.

Stoichiometry and Limiting Reagents

Stoichiometry deals with the calculation of masses and volumes of reactants and products involved in a chemical reaction.

Pro Tip: Always identify the Limiting Reagent—the reactant that is completely consumed in a reaction and limits the amount of product formed.

Boost Your Preparation with Chemca Resources

• Interactive Learning: Use our Basic Concepts of Chemistry Flashcards.
• Formula Mastery: Keep the Mole Concept Formula Sheet handy.
• Complete Study Material: Access our Exclusive Notes & PDF Folder.

Final Thoughts

"Some Basic Concepts of Chemistry" is more than just Chapter 1; it is the foundation of your career in science. Focus on units, practice numericals, and ensure your basics are clear.

Happy Learning with Chemca!

Quiz Revision Notes Downloads Class Notes Video Lectures

Ionic Equilibrium - JEE Advanced Numerical Challenge | Chemca.in

Ionic Equilibrium Challenge

30 Advanced Numerical Problems for JEE | www.chemca.in

Course Progress 0/30 Solved

Targeting JEE Advanced?

Analyze every solution carefully to understand common-ion effects, salt hydrolysis, and complexation concepts.

© 2026 Chemca.in — Advanced Chemistry Learning

Quiz Revision Notes Downloads Class Notes Video Lectures

Redox Reactions Balancing Practice

Master Redox Balancing

20 Advanced Practice Problems | Acidic & Basic Medium

Instructions: Try to balance these equations on paper first. When you are ready, click the "Submit & Show Detailed Solutions" button at the bottom to reveal the step-by-step answers.

Part I: Acidic Medium

Acidic

1. Permanganate and Oxalate ion

MnO₄^- + C₂O₄^2- → Mn²⁺ + CO₂

Detailed Solution

1. Oxidation: C₂O₄^2- → 2CO₂ + 2e^-

2. Reduction: MnO₄^- + 8H⁺ + 5e^- → Mn²⁺ + 4H₂O

3. Balance Electrons: Multiply Oxidation by 5 and Reduction by 2.

Final: 2MnO₄^- + 5C₂O₄^2- + 16H⁺ → 2Mn²⁺ + 10CO₂ + 8H₂O

Acidic

2. Dichromate and Iron(II)

Cr₂O₇^2- + Fe²⁺ → Cr³⁺ + Fe³⁺

Detailed Solution

1. Oxidation: Fe²⁺ → Fe³⁺ + 1e^-

2. Reduction: Cr₂O₇^2- + 14H⁺ + 6e^- → 2Cr³⁺ + 7H₂O

3. Balance Electrons: Multiply Oxidation by 6.

Final: Cr₂O₇^2- + 6Fe²⁺ + 14H⁺ → 2Cr³⁺ + 6Fe³⁺ + 7H₂O

Acidic

3. Arsenic Sulfide and Nitrate (Challenging)

As₂S₃ + NO₃^- → H₃AsO₄ + SO₄^2- + NO

Detailed Solution

1. Oxidation: As₂S₃ + 20H₂O → 2H₃AsO₄ + 3SO₄^2- + 34H⁺ + 28e^-

2. Reduction: NO₃^- + 4H⁺ + 3e^- → NO + 2H₂O

3. Balance Electrons: Multiply Oxidation by 3 and Reduction by 28.

Final: 3As₂S₃ + 28NO₃^- + 4H₂O + 10H⁺ → 6H₃AsO₄ + 9SO₄^2- + 28NO

Acidic

4. Copper and Nitrate

Cu + NO₃^- → Cu²⁺ + NO

Detailed Solution

1. Oxidation: Cu → Cu²⁺ + 2e^-

2. Reduction: NO₃^- + 4H⁺ + 3e^- → NO + 2H₂O

3. Balance Electrons: Multiply Oxidation by 3 and Reduction by 2.

Final: 3Cu + 2NO₃^- + 8H⁺ → 3Cu²⁺ + 2NO + 4H₂O

Acidic

5. Iodate and Iodide (Comproportionation)

IO₃^- + I^- → I₃^-

Detailed Solution

1. Oxidation: 3I^- → I₃^- + 2e^-

2. Reduction: 3IO₃^- + 18H⁺ + 16e^- → I₃^- + 9H₂O

3. Balance Electrons: Multiply Oxidation by 8.

Final: IO₃^- + 8I^- + 6H⁺ → 3I₃^- + 3H₂O

Acidic

6. Zinc and Nitrate (Formation of Ammonium)

Zn + NO₃^- → Zn²⁺ + NH₄⁺

Detailed Solution

1. Oxidation: Zn → Zn²⁺ + 2e^-

2. Reduction: NO₃^- + 10H⁺ + 8e^- → NH₄⁺ + 3H₂O

3. Balance Electrons: Multiply Oxidation by 4.

Final: 4Zn + NO₃^- + 10H⁺ → 4Zn²⁺ + NH₄⁺ + 3H₂O

Acidic

7. Thiosulfate and Iodine

S₂O₃^2- + I₂ → S₄O₆^2- + I^-

Detailed Solution

1. Oxidation: 2S₂O₃^2- → S₄O₆^2- + 2e^-

2. Reduction: I₂ + 2e^- → 2I^-

3. Balance Electrons: Electrons already balanced (2e-).

Final: 2S₂O₃^2- + I₂ → S₄O₆^2- + 2I^-

Acidic

8. Sulfite and Permanganate

SO₃^2- + MnO₄^- → SO₄^2- + Mn²⁺

Detailed Solution

1. Oxidation: SO₃^2- + H₂O → SO₄^2- + 2H⁺ + 2e^-

2. Reduction: MnO₄^- + 8H⁺ + 5e^- → Mn²⁺ + 4H₂O

3. Balance Electrons: Multiply Oxidation by 5 and Reduction by 2.

Final: 5SO₃^2- + 2MnO₄^- + 6H⁺ → 5SO₄^2- + 2Mn²⁺ + 3H₂O

Acidic

9. Chlorate and Sulfur Dioxide

ClO₃^- + SO₂ → Cl^- + SO₄^2-

Detailed Solution

1. Oxidation: SO₂ + 2H₂O → SO₄^2- + 4H⁺ + 2e^-

2. Reduction: ClO₃^- + 6H⁺ + 6e^- → Cl^- + 3H₂O

3. Balance Electrons: Multiply Oxidation by 3.

Final: ClO₃^- + 3SO₂ + 3H₂O → Cl^- + 3SO₄^2- + 6H⁺

Acidic

10. Hydrogen Peroxide and Dichromate

H₂O₂ + Cr₂O₇^2- → O₂ + Cr³⁺

Detailed Solution

1. Oxidation: H₂O₂ → O₂ + 2H⁺ + 2e^-

2. Reduction: Cr₂O₇^2- + 14H⁺ + 6e^- → 2Cr³⁺ + 7H₂O

3. Balance Electrons: Multiply Oxidation by 3.

Final: 3H₂O₂ + Cr₂O₇^2- + 8H⁺ → 3O₂ + 2Cr³⁺ + 7H₂O

Part II: Basic Medium

Basic

11. Phosphorus Disproportionation (Classic)

P₄ → PH₃ + H₂PO₂^-

Detailed Solution

1. Oxidation: P₄ + 8OH^- → 4H₂PO₂^- + 4e^-

2. Reduction: P₄ + 12H₂O + 12e^- → 4PH₃ + 12OH^-

3. Balance Electrons: Multiply Oxidation by 3.

Final: P₄ + 3OH^- + 3H₂O → PH₃ + 3H₂PO₂^-

Basic

12. Chlorine Disproportionation

Cl₂ → Cl^- + ClO₃^-

Detailed Solution

1. Oxidation: Cl₂ + 12OH^- → 2ClO₃^- + 6H₂O + 10e^-

2. Reduction: Cl₂ + 2e^- → 2Cl^-

3. Balance Electrons: Multiply Reduction by 5.

Final: 3Cl₂ + 6OH^- → 5Cl^- + ClO₃^- + 3H₂O

Basic

13. Aluminum and Nitrite

Al + NO₂^- → AlO₂^- + NH₃

Detailed Solution

1. Oxidation: Al + 4OH^- → AlO₂^- + 2H₂O + 3e^-

2. Reduction: NO₂^- + 5H₂O + 6e^- → NH₃ + 7OH^-

3. Balance Electrons: Multiply Oxidation by 2.

Final: 2Al + NO₂^- + OH^- + H₂O → 2AlO₂^- + NH₃

Basic

14. Chromite and Hypochlorite

Cr(OH)₃ + ClO^- → CrO₄^2- + Cl^-

Detailed Solution

1. Oxidation: Cr(OH)₃ + 5OH^- → CrO₄^2- + 4H₂O + 3e^-

2. Reduction: ClO^- + H₂O + 2e^- → Cl^- + 2OH^-

3. Balance Electrons: Multiply Oxidation by 2 and Reduction by 3.

Final: 2Cr(OH)₃ + 3ClO^- + 4OH^- → 2CrO₄^2- + 3Cl^- + 5H₂O

Basic

15. Permanganate and Cyanide

MnO₄^- + CN^- → MnO₂ + CNO^-

Detailed Solution

1. Oxidation: CN^- + 2OH^- → CNO^- + H₂O + 2e^-

2. Reduction: MnO₄^- + 2H₂O + 3e^- → MnO₂ + 4OH^-

3. Balance Electrons: Multiply Oxidation by 3 and Reduction by 2.

Final: 2MnO₄^- + 3CN^- + H₂O → 2MnO₂ + 3CNO^- + 2OH^-

Basic

16. Hydrazine and Chlorate

N₂H₄ + ClO₃^- → NO + Cl^-

Detailed Solution

1. Oxidation: N₂H₄ + 4OH^- → 2NO + 4H₂O + 8e^-

2. Reduction: ClO₃^- + 3H₂O + 6e^- → Cl^- + 6OH^-

3. Balance Electrons: Multiply Oxidation by 3 and Reduction by 4.

Final: 3N₂H₄ + 4ClO₃^- → 6NO + 4Cl^- + 6H₂O

Basic

17. Zinc and Nitrate (Zincate formation)

Zn + NO₃^- → Zn(OH)₄^2- + NH₃

Detailed Solution

1. Oxidation: Zn + 4OH^- → Zn(OH)₄^2- + 2e^-

2. Reduction: NO₃^- + 6H₂O + 8e^- → NH₃ + 9OH^-

3. Balance Electrons: Multiply Oxidation by 4.

Final: 4Zn + NO₃^- + 7OH^- + 6H₂O → 4Zn(OH)₄^2- + NH₃

Basic

18. Bismuth Hydroxide and Stannite

Bi(OH)₃ + SnO₂^2- → SnO₃^2- + Bi

Detailed Solution

1. Oxidation: SnO₂^2- + 2OH^- → SnO₃^2- + H₂O + 2e^-

2. Reduction: Bi(OH)₃ + 3e^- → Bi + 3OH^-

3. Balance Electrons: Multiply Oxidation by 3 and Reduction by 2.

Final: 2Bi(OH)₃ + 3SnO₂^2- → 3SnO₃^2- + 2Bi + 3H₂O

Basic

19. Ferrate production

Fe(OH)₃ + ClO^- → FeO₄^2- + Cl^-

Detailed Solution

1. Oxidation: Fe(OH)₃ + 5OH^- → FeO₄^2- + 4H₂O + 3e^-

2. Reduction: ClO^- + H₂O + 2e^- → Cl^- + 2OH^-

3. Balance Electrons: Multiply Oxidation by 2 and Reduction by 3.

Final: 2Fe(OH)₃ + 3ClO^- + 4OH^- → 2FeO₄^2- + 3Cl^- + 5H₂O

Basic

20. Cobalt(II) and Peroxide

Co(OH)₂ + H₂O₂ → Co(OH)₃

Detailed Solution

1. Oxidation: Co(OH)₂ + OH^- → Co(OH)₃ + e^-

2. Reduction: H₂O₂ + 2e^- → 2OH^-

3. Balance Electrons: Multiply Oxidation by 2.

Final: 2Co(OH)₂ + H₂O₂ → 2Co(OH)₃

Coordination Compounds Flashcards - Chemca.in

Quiz Revision Notes Downloads Class Notes Video Lectures

Structure of Atom Flashcards - Chemca.in

Quiz Revision Notes Downloads Class Notes Video Lectures