Grade 11
  1. Basic concepts of chemistry  1.1. Importance of Chemistry  1.2. Nature and scope of chemistry  1.3. laws of chemical combination  1.3.1. Law of conservation of mass  1.3.2. Law of definite proportions  1.3.3. Law of multiple proportions  1.3.4. Law of gaseous volume  1.3.5. Avogadro's Law  1.4. Dalton's atomic theory  1.5. Mole concept and molar mass  1.6. Percent composition  1.7. Empirical and molecular formula  1.8. Stoichiometry and Stoichiometric Calculations  1.9. Limiting reagent concept
  2. Structure of the atom  2.1. Discovery of the electron, proton, and neutron  2.2. Atomic Model  2.2.1. Thomson's model  2.2.2. Rutherford's model  2.2.3. Bohr's model  2.3. Quantum mechanical model of the atom  2.4. Dual nature of matter and radiation  2.5. Heisenberg's uncertainty principle  2.6. Quantum numbers  2.7. Atomic orbitals and their shapes  2.8. Electronic configuration of elements  2.9. Aufbau principle  2.10. Pauli's exclusion principle  2.11. Hund's maximum multiplicity rule  2.12. de Broglie's hypothesis  2.13. Photoelectric effect
  3. Classification of elements and periodicity in properties  3.1. Historical development of the periodic table  3.2. Modern Periodic Law and Periodic Table  3.3. Periodic trends in properties  3.3.1. Atomic and Ionic Radius  3.3.2. Ionization enthalpy  3.3.3. Electron gain enthalpy  3.3.4. Electronegativity  3.3.5. Valency  3.3.6. Metallic and Non-Metallic Properties  3.3.7. Oxidation states  3.4. Unusual Properties of the First Elements
  4. Chemical Bonding and Molecular Structure  4.1. Kossel–Lewis approach to chemical bonding  4.2. Ionic or electrovalent bond  4.3. Covalent bond and its features  4.4. Bond parameters  4.5. VSEPR Theory  4.6. Valence bond theory  4.7. Hybridization and its types  4.8. Molecular orbital theory  4.8.1. Bond order and stability  4.9. Hydrogen bonding
  5. States of matter  5.1. Intermolecular forces  5.2. Gas Laws  5.2.1. Boyle's law  5.2.2. Charles's Law  5.2.3. Avogadro's Law  5.2.4. Dalton's law of partial pressure  5.2.5. Graham's law of spread  5.3. Ideal Gas Equation and Applications  5.4. Real gases and deviations from ideal behaviour  5.5. Kinetic molecular theory of gases  5.6. Liquefaction of gases  5.7. Properties of Liquids  5.8. Surface tension and viscosity
  6. Thermodynamics  6.1. System and environment  6.2. Types of systems in thermodynamics  6.3. Types of procedures  6.4. First law of thermodynamics  6.5. Internal energy and enthalpy  6.6. Heat capacity and specific heat  6.7. Hess's law of constant heat summation  6.8. Bond dissociation enthalpy  6.9. Enthalpy of formation and combustion  6.10. Enthalpy of solution and neutralization  6.11. Spontaneity and the second law of thermodynamics  6.12. Gibbs free energy and its applications
  7. Balance  7.1. The concept of balance  7.2. Equilibrium constant and its applications  7.3. Le Chatelier's principle  7.4. Ionic equilibrium in solutions  7.5. Acid and Base Theory  7.5.1. Arrhenius concept  7.5.2. Bronsted-Lowry concept  7.5.3. Lewis concept  7.6. pH Scale and pOH  7.7. Common ion effect  7.8. Hydrolysis of salts  7.9. Buffer solutions and their mechanism of action  7.10. Solubility equilibrium of sparingly soluble salts
  8. Redox reactions  8.1. Oxidation and reduction concepts  8.2. Oxidation number and its applications  8.3. Redox reactions in terms of electron transfer  8.4. Balancing redox reactions (oxidation number and ion-electron methods)  8.5. Types of redox reactions  8.6. Electrochemical Cells and Redox Reactions
  9. Hydrogen  9.1. Position of Hydrogen in the Periodic Table  9.2. Isotopes of hydrogen  9.3. Preparation of Hydrogen  9.4. Properties of Hydrogen  9.5. Hydrides and their classification  9.6. Water and heavy water  9.7. Hydrogen peroxide and its properties  9.8. Uses of Hydrogen and Its Compounds
  10. S-block elements (alkali and alkaline earth metals)  10.1. Group 1 Elements - Properties and Trends  10.2. Group 2 Elements - Properties and Trends  10.3. Unusual properties of lithium and beryllium  10.4. Important compounds of sodium and their uses  10.5. Important Compounds of Magnesium and Calcium
  11. Some p-block elements  11.1. General Introduction to p-Block Elements  11.2. Group 13 Elements  11.2.1. Boron and its compounds  11.3. Group 14 Elements  11.3.1. Carbon and its allotropes  11.3.2. Important Compounds of Carbon and Silicon
  12. Organic Chemistry - Some Basic Principles and Techniques  12.1. Classification and Nomenclature of Organic Compounds  12.2. Structural representation of organic compounds  12.3. Classification of organic reactions  12.4. Electronic Effects in Organic Chemistry  12.4.1. Inductive effect  12.4.2. Resonance effect  12.4.3. Hyperconjugation  12.5. Reaction mechanism and intermediate species  12.6. Purification and qualitative analysis of organic compounds
  13. Hydrocarbons  13.1. Hydrocarbons  13.1.1. Preparation and Properties of Alkenes  13.2. alkene  13.2.1. Preparation and Properties of Alkenes  13.2.2. Electrophilic addition reactions  13.3. Alkynes  13.3.1. Preparation and Properties of Alkynes  13.4. Aromatic hydrocarbons  13.4.1. Structure and properties of benzene  13.4.2. Electrophilic substitution reactions of benzene
  14. Environmental Chemistry  14.1. Environmental Pollution  14.2. Atmospheric pollution and the greenhouse effect  14.3. Water pollution and treatment methods  14.4. Soil pollution and its effects  14.5. Industrial waste and its treatment  14.6. Strategies for pollution control

Grade 11Structure of the atom


Quantum mechanical model of the atom


The quantum mechanical model of the atom is a fundamental theory in physics that provides a comprehensive solution to understanding the behavior of electrons within atoms. It is based on quantum theory, which emerged in the early 20th century with the breakthroughs of scientists such as Max Planck, Albert Einstein, Niels Bohr, Werner Heisenberg, and Erwin Schrödinger.

Unlike previous models such as the Bohr model, which depicted electrons orbiting around the nucleus in fixed paths, the quantum mechanical model depicts electrons as existing in probabilistic clouds called orbitals. These orbitals specify the possible locations of the electron in the atom, but do not indicate the exact path.

Historical context

The journey to quantum mechanical models began with the inadequacy of classical physics in explaining atomic phenomena. Early atomic models such as J.J. Thomson's "plum pudding" model and Rutherford's atomic model set the stage for further exploration, but could not explain atomic spectra or the stability of atoms.

Max Planck and the quantum hypothesis

The introduction of the quantum hypothesis by Max Planck provided the first clues toward understanding atomic behavior. Planck proposed that energy is quantized, meaning that it comes in discrete units, which he called "quanta." This was a radical change from the classical view of viewing energy as a continuous quantity.

Niels Bohr and the Bohr model

Niels Bohr, working on Planck's ideas, developed the Bohr model, which depicted electrons orbiting the nucleus in neat, fixed orbits with quantized energy. Although this model explained the hydrogen spectrum well, it failed for more complex atoms.

Development of quantum mechanics

Quantum mechanics emerged as a revolutionary framework that provided a fundamental explanation for the behavior of matter and radiation at the atomic scale.

Heisenberg's uncertainty principle

Werner Heisenberg introduced the uncertainty principle, which is the basis of quantum mechanics. It states that it is impossible to know both the exact position and momentum of an electron simultaneously. Mathematically, it is expressed as:

Δx * Δp ≥ ħ / 2

where Δx is the uncertainty in position, Δp is the uncertainty in momentum, and ħ is the reduced Planck constant.

Schrödinger wave equation

The quantum mechanical model is centered around the Schrödinger equation, formulated by Erwin Schrödinger. This equation provides a way to calculate the electron's wave function (ψ), which describes the probability distribution of the electron's position in an atom.

Ĥψ = Eψ

Here, Ĥ is the Hamiltonian operator, which represents the total energy of the system, ψ is the wave function, and E is the energy eigenvalue.

Understanding orbitals and electron clouds

The solution of the Schrödinger equation for an atom gives a set of quantum numbers and orbitals that define the distribution and energy of the electrons.

Quantum numbers

Quantum numbers are a set of numerical values that determine the unique state of an electron in an atom. There are four quantum numbers:

  • Principal quantum number (n): Determines the shape and energy of the orbital, it can be any positive integer.
  • Angular momentum quantum number (l): Determines the size of the orbital, ranges from 0 to n-1.
  • Magnetic quantum number (ml): Determines the orientation of the orbital in space, ranging from -l to +l.
  • Spin quantum number (ms): Determines the spin of the electron, which can be +1/2 or -1/2.

Types of orbitals

Orbitals can have different shapes and are characterized by the angular momentum quantum number (l):

  • s-orbitals (spherical): These orbitals are spherical in shape. An s-orbital for n=1 would look like this:
    • * * * * * * * * * * * * * * * *
  • p-orbitals (dumbbell shape): These orbitals have a dumbbell-like shape and come in sets of three for p level.
    • * * * * * * * * * * * * * * * * * * * *
  • d-orbitals (cloverleaf and complex): These have a more complex shape and typically contribute to bonding in transition metals.
  • f-orbitals (even more complex): found in heavier elements and have complex shapes.

Visualization of electron configuration

The electron configuration of an atom shows the distribution of electrons among orbitals. It is determined by applying the Aufbau principle, Pauli exclusion principle and Hund's rule.

Aufbau principle

Electrons move to the lowest energy orbitals first, followed by higher energy orbitals. The energy order is estimated as follows:

1s < 2s < 2p < 3s < 3p < 4s < 3d < 4p < 5s < 4d < 5p < 6s < 4f < 5d < 6p

Pauli exclusion principle

No two electrons in an atom can have the same set of four quantum numbers. This means that each orbital can hold a maximum of two electrons with opposite spins.

Hund's law

When electrons are in orbitals of equal energy, one electron enters each orbital until all orbitals have one electron with parallel spin, after which pairing occurs.

Practical example: electron configuration of carbon

Let us find the electron configuration of carbon (C), which has atomic number 6, that is, it has 6 electrons.

The order of filling is: 1s² 2s² 2p² - 1s orbital gets filled with two electrons: 1s² - 2s orbital gets filled with two electrons: 2s² - The 2p orbital gets two remaining electrons: 2p²

Importance and applications

The quantum mechanical model revolutionized chemistry and physics by providing a framework for understanding chemical bonds, atomic interactions, and the properties of matter at the atomic level. Its applications span a variety of fields, including medicine, technology, and quantum computing.

Using this model, chemists can predict and explain the behavior of atoms during chemical reactions, how molecules combine together to form compounds, and infer the physical properties of elements based on their electronic configuration.

Contribution of Heisenberg and Schrödinger

Heisenberg and Schrödinger contributed greatly to quantum theory with the development of matrix mechanics and wave mechanics, respectively. The two frameworks were later proven to be mathematically equivalent.

Applications in modern chemistry

Quantum mechanical models allow us to understand complex chemical reactions, predict the behaviour of new materials, and innovate in the development of medicines and materials with specific properties.

Conclusion

The quantum mechanical model of the atom is a significant advance in scientific understanding. It broke away from the idea of deterministic paths for electrons and introduced the concept of probabilistic electron distributions that accurately describe nuclear interactions. This model laid the foundation for quantum chemistry and modern physics, allowing both theoretical insights and practical applications in many scientific fields.


Grade 11 → 2.3


U
username
0%
completed in Grade 11

← Prev (2.2.3)
Bohr's model
Next (2.4) →
Dual nature of matter and radiation

Comments 



Quantum mechanical model of the atom

https://www.chemistryelite.com/g11/2.3?ceal=en