Topics
Gravitation
- Concept of Gravitation
- Force and Motion
- Centripetal Force
- Kepler’s Laws
- Law of Orbit or Kepler's First Law
- Law of Areas or Kepler's Second Law
- Law of Periods or Kepler's Third Law
- Newton's Universal Law of Gravitation
- Uniform Circular Motion (UCM)
- Earth’s Gravitational Force
- Earth’s Gravitational Acceleration
- Mass and Weight
- Gravitational Waves
- Free Fall
- Gravitational Potential Energy
- Escape Velocity
- Weightlessness in Space
Periodic Classification of Elements
- Classification of Elements
- Dobereiner’s Triads
- Newland's Law of Octaves
- Mendeleev’s Periodic Table
- Insights into Mendeleev’s Periodic Table
- Modern Periodic Law
- The Modern Periodic Table
- Structure of the Modern Periodic Table
- Modern Periodic Table and Electronic Configuration of Elements
- Groups and Electronic Configuration
- Periods and Electronic Configuration
- Periodic Trends in the Modern Periodic Table
- Atomic Size
- Metallic and Non-metallic Characters
- Gradation in Halogen Family
Chemical Reactions and Equations
- Chemical Reaction
- Chemical Equations
- Balancing Chemical Equation
- Types of Chemical Reactions > Combination Reaction
- Types of Chemical Reactions > Decomposition Reaction
- Types of Chemical Reactions > Single Displacement Reaction
- Types of Chemical Reactions > Double Displacement Reaction
- Endothermic and Exothermic Processes
- Rate of Chemical Reaction
- Factors Affecting the Rate of a Chemical Reaction
- Chemical Properties of Carbon Compounds > Oxidation
- Chemical Properties of Carbon Compounds > Reduction
- Corrosion of Metals
- Rancidity
Effects of Electric Current
- Electric Circuit
- Heating Effect of Electric Current
- Magnetic Effect of Electric Current
- Right-hand Thumb Rule
- Applications of Biot-Savart's Law > Magnetic Field at the Centre of a Circular Loop
- Applications of Ampere’s Circuital Law > Magnetic Field of a Long Straight Solenoid
- Force on a Current Carrying Conductor in a Magnetic Field
- Fleming’s Left Hand Rule
- Electric Motor
- Electromagnetic Induction
- Galvanometer
- Faraday's Laws of Electromagnetic Induction
- Fleming’s Right Hand Rule
- Alternating current (AC) and Direct Current (DC)
- Electric Generator
Heat
Refraction of Light
Lenses
- Concept of Lenses
- Images Formed by Convex Lenses
- Images Formed by Concave Lenses
- Sign Convention
- Lens Formula
- Magnification
- Power of a Lens
- Combination of Lenses
- Defects of Vision and Their Corrections > Myopia
- Defects of Vision and Their Corrections > Hypermetropia
- Defects of Vision and Their Corrections > Presbyopia
- Apparent Size of an Object
- Use of Concave Lenses
- Use of Convex Lenses
- Persistence of Vision
Metallurgy
- Physical Properties of Metals
- Physical Properties of Non-metal
- Chemical Properties of Metal
- Reactions of Metals
- Reactivity Series of Metals
- Chemical Properties of Non-metal
- Ionic Compounds
- Metallurgy
- Basic Principles of Metallurgy > Concentration of Ores
- Basic Principles of Metallurgy > Extraction of Metals
- Basic Principles of Metallurgy > Refining of Metals
- Corrosion of Metals
- Prevention of Corrosion
Carbon Compounds
- Bonds in Carbon Compounds
- Carbon: A Versatile Element
- Hydrocarbons
- Straight chains, Branched chains, and Rings of Carbon atoms
- Functional Groups in Carbon Compounds
- Homologous Series
- Nomenclature
- Chemical Properties of Carbon Compounds > Combustion
- Chemical Properties of Carbon Compounds > Oxidation
- Chemical Properties of Carbon Compounds > Addition Reaction
- Chemical Properties of Carbon Compounds > Substitution Reaction
- Ethanol
- Ethanoic Acid
- Macromolecules and Polymers
Space Missions
School of Elements
The Magic of Chemical Reactions
- Chemical Equations
- Types of Chemical Reactions > Combination Reaction
- Types of Chemical Reactions > Decomposition Reaction
- Types of Chemical Reactions > Single Displacement Reaction
- Types of Chemical Reactions > Double Displacement Reaction
- Chemical Properties of Carbon Compounds > Oxidation
- Types of Double Displacement: Neutralization Reaction
The Acid Base Chemistry
- Properties of Acids > Physical Properties
- The pH Scale
- Acids, Bases and Their Reactivity
- Acid or a Base in a Water Solution
- Preparation and Uses of Baking Soda
- Preparation and Uses of Bleaching Powder
- Preparation and Uses of Washing Soda
- Preparation and Uses of Plaster of Paris
- Chemicals from Common Salt - Soap as a Salt
The Electric Spark
All about Electromagnetism
- Magnetic force
- Bar Magnet and Solenoid Analogy
- Right-hand Thumb Rule
- Applications of Biot-Savart's Law > Magnetic Field at the Centre of a Circular Loop
- Applications of Ampere’s Circuital Law > Magnetic Field of a Long Straight Solenoid
- Force on a Current Carrying Conductor in a Magnetic Field
- Electric Motor
- Electromagnetic Induction
- A.C. Generator
- Simple D.C. Motor
- Household Electrical Circuits
Wonders of Light 1
Wonders of Light 2
Striving for better Environment 1
- Abatement of Pollution
- Sustainable Use of Resources
- Definition: Single Displacement Reaction
- Key Points: Single Displacement Reactions
Definition: Single Displacement Reaction
The reaction in which the place of the ion of a less reactive element in a compound is taken by another more reactive element by formation of its own ions, is called displacement reaction.
Maharashtra State Board: Class 10
Key Points: Single Displacement Reactions
- A more reactive metal can replace a less reactive metal from its compound in solution.
- Zinc, iron, and lead can displace copper from copper sulphate or copper chloride solutions.
- During displacement, the displaced metal appears in elemental form, while the replacing metal forms its salt.
- In the reaction Fe + CuSO₄ → FeSO₄ + Cu, the iron nail turns brownish due to deposited copper, and the blue solution fades.
- Heat may be released during displacement reactions, indicating that the reaction is exothermic.
Introduction
A single displacement reaction, also known as a single replacement reaction, occurs when a more reactive element replaces a less reactive element in a compound. The products of these reactions can be predicted using the reactivity series, which arranges elements in decreasing order of their reactivity. Elements at the top of the reactivity series are more reactive and can displace elements positioned below them.
A + BC → AC + B
Here, A (a metal) replaces B (another metal) in the compound BC, forming AC while B is released as a free element.
In this reaction, Y (a nonmetal) replaces Z (another nonmetal) in the compound XZ, forming XY, while Z is released as a free element.
For example, in the reaction between potassium (K) and magnesium chloride (MgCl₂), potassium, being more reactive, displaces magnesium from its salt, forming potassium chloride (KCl) and releasing magnesium (Mg) as a free element.
2K + MgCl₂ → 2KCl + Mg
Experiment
1. Aim: To observe a single displacement reaction, where a more reactive metal displaces a less reactive metal from its compound.
2. Requirements
- Apparatus: test tubes, beaker, dropper, magnesium strip, zinc metal.
- Chemicals: Copper(II) nitrate [Cu(NO₃)₂] solution, hydrochloric acid (HCl), zinc (Zn), and magnesium (Mg).
3. Procedure
Experiment 1: Reaction of Magnesium with Copper(II) Nitrate
- Take an aqueous solution of Cu(NO₃)₂ in a test tube.
- Place a magnesium (Mg) strip into the solution.
- Observe that copper (Cu) precipitates while magnesium nitrate [Mg(NO₃)₂] forms in solution.
Mg(s) + Cu(NO3)2(aq) → Mg(NO3)2(aq) + Cu(s)
Experiment 2: Reaction of Zinc with Hydrochloric Acid
- Take dilute hydrochloric acid (HCl) in a test tube.
- Add a small piece of zinc (Zn) to it.
- Observe the formation of bubbles of hydrogen gas (H₂) and the formation of zinc chloride (ZnCl₂) in solution.
Zn(s) + 2HCl(aq) → ZnCl₂(aq) + H₂(g)
4. Conclusion: A single displacement reaction occurs when a more reactive metal replaces a less reactive element in a compound. These reactions follow the reactivity series, where more reactive metals displace less reactive ones, producing new compounds and free elements.
