11th MHT-CET

Physics

1.Motion in a Plane
Scalars and vectors

Comprehensive explanation of scalars and vectors, including definitions and differences. 

Detailed discussion on scalars and vectors with examples, tailored for MHT CET preparation. 

Introduction to position and displacement vectors, with practical examples. 

Explanation of position vectors and displacement vectors, including graphical representations. 

In-depth tutorial on vector operations: equality, addition, and subtraction, with illustrative examples. 

Detailed explanation of vector addition and subtraction, including graphical methods. 

 

 

Comprehensive guide on relative velocity concepts, with problem-solving techniques. 

Detailed explanation of relative velocity in different contexts, with examples. 

Detailed analysis of projectile motion, including equations of motion and trajectory analysis. 

Comprehensive tutorial on projectile motion, covering key concepts and problem-solving strategies. 

In-depth discussion on uniform circular motion, including centripetal force and acceleration. 

Detailed explanation of uniform circular motion concepts, with practical examples. 

Newton’s first, second, and third laws

In-depth discussion on each of Newton’s laws, including mathematical formulations and examples. 

Analysis of Newton’s laws with emphasis on their significance in classical mechanics. 

Tutorial on constructing free body diagrams, highlighting common mistakes and best practices. 

Step-by-step guide to drawing free body diagrams for various physical systems. 

Explanation of linear momentum concepts, including conservation principles and problem-solving techniques. 

Detailed discussion on linear momentum and its applications in collisions and other interactions. 

Comprehensive analysis of the conservation of momentum principle, with examples from real-life scenarios. 

Discussion on the applications of momentum conservation in isolated systems and during collisions. 

Overview of frictional forces, differentiating between static, kinetic, and rolling friction, with practical examples. 

Detailed explanation of the causes of friction, factors affecting it, and methods to reduce or increase friction in various applications. 

Newton’s law of gravitation

Comprehensive explanation of Newton’s Law of Gravitation, including its applications and significance in physics. 

Detailed analysis of Newton’s Law of Universal Gravitation with examples and problem-solving techniques. 

In-depth discussion on the gravitational constant (G), its determination, and role in gravitational equations. 

Explanation of the Cavendish experiment and how it led to the calculation of the gravitational constant. 

Overview of gravitational potential energy, its derivation, and significance in orbital mechanics. 

Detailed explanation of gravitational potential energy with practical examples and problem-solving sessions. 

Comprehensive analysis of escape velocity, including its derivation and applications in space science. 

Explanation of the concept of escape velocity with numerical examples and its relevance in launching satellites. 

Detailed discussion on the orbital velocity of satellites, including derivation of formulas and practical applications. 

Explanation of how orbital velocity is calculated and its importance in satellite motion and space missions. 

Heat, temperature, and internal energy

Comprehensive explanation of heat, temperature, and internal energy, including their interrelations and significance in thermodynamics. 

Detailed discussion on the differences between heat and temperature, and an introduction to internal energy with practical examples. 

In-depth analysis of the three modes of heat transfer—conduction, convection, and radiation—with real-life applications and demonstrations. 

Tutorial on heat transfer mechanisms, focusing on the principles of conduction, convection, and radiation, and their roles in everyday phenomena. 

Explanation of specific heat capacity, its importance in thermal physics, and methods to calculate it for different substances. 

Detailed discussion on measuring specific heat capacities experimentally, including the continuous flow method and related calculations. 

Analysis of the effects of temperature changes on the expansion of solids, liquids, and gases, with examples from engineering and daily life. 

Comprehensive overview of thermal expansion in different states of matter, including coefficients of expansion and practical implications. 

Wave motion, longitudinal and transverse waves

An animated lecture explaining wave motion, focusing on the differences between transverse and longitudinal waves with practical examples. 

A detailed discussion on longitudinal and transverse waves, tailored for foundational understanding in physics. 

An in-depth analysis of the speed of sound, including factors affecting it and its measurement in different mediums. 

A comprehensive tutorial on the speed of sound, covering theoretical concepts and practical applications. 

An exploration of how sound waves reflect, refract, and interfere, with demonstrations and real-life examples. 

A study of the behavior of sound waves during reflection, refraction, and interference, emphasizing their significance in acoustics. 

A detailed explanation of the Doppler Effect, illustrating how the frequency of sound changes with the relative motion of source and observer. 

An analysis of the Doppler Effect with mathematical derivations and examples from everyday life. 

Reflection and refraction of light

In-depth discussion on reflection from spherical mirrors, covering fundamental concepts. 

Comprehensive analysis of reflection and refraction principles with practical examples. 

Explanation of components of spherical lenses, including their properties and uses. 

Lecture focusing on refraction at spherical surfaces and lenses, essential for understanding optics. 

Detailed tutorial on spherical mirrors, including mirror formula and magnification concepts. 

Comprehensive lecture on optics, focusing on spherical mirrors and related formulas. 

Understanding spherical mirrors and their role in light dispersion phenomena. 

Image formation by spherical lenses and its relation to light dispersion. 

Electric charge, properties, and Coulomb’s law

In-depth explanation of electric charge, its properties, and Coulomb’s law with practical examples. 

Detailed analysis of Coulomb’s law and its applications in electrostatics. 

Comprehensive discussion on electric fields and electric potential, including their interrelation. 

Detailed lecture on electric fields, potential, and their significance in electrostatics. 

Explanation of capacitance, capacitors, and their role in electrical circuits. 

Detailed discussion on capacitors, capacitance, and their applications in electronics. 

Basic concepts of semiconductors

Comprehensive lecture on semiconductor electronics, covering fundamental concepts and materials. 

Detailed explanation of semiconductors, focusing on intrinsic and extrinsic types. 

In-depth discussion on p-n junction diodes, including formation and characteristics. 

Detailed analysis of p-n junctions with emphasis on their role in semiconductor devices. 

Explanation of applications of p-n junction diodes in electronics, such as rectifiers and voltage regulators. 

Detailed discussion on the practical uses of p-n junctions in various electronic devices. 

Basics of vectors

Comprehensive introduction to vectors, including definitions, representations, and fundamental properties. 

Detailed explanation of vector quantities, focusing on their significance in physics and engineering. 

In-depth discussion on vector addition and subtraction using graphical and analytical methods. 

Comprehensive analysis of vector multiplication, including dot and cross products, with practical examples. 

Explanation of error analysis in measurements, covering systematic and random errors, and methods to minimize them. 

Detailed discussion on types of errors in experimental physics and statistical techniques for error analysis.