- Introduction of Thermodynamics
- Thermodynamic System
- Thermodynamic Views
- Thermodynamic Properties
- Thermodynamic Equilibrium
- Pure Substance
- Basic Terms (State, Path, Process and Cycle)
- Quasistatic Process
- Path Function and Point Function
- Temperature
- Zeroth Law of Thermodynamics
- Pressure and Terms Related to Pressure
- Reversible and Irreversible Process
- Work, Heat and Energy

- Work Transfer
- Displacement work
- Workdone for various Quasistatic Process
- Free Expansion
- Heat Transfer
- Types of Heat
- Problem Based on Closed Cycle
- Application of 1st Law of Thermodynamics to Non Flow System or Closed system
- What Is Reversible of Constant Volume Process
- What Is the Reversible of Constant Pressure Process
- What Is the Reversible of Constant Temperature Process
- What Is the Reversible of Adiabatic Process
- What Is Polytropic Process in Thermodynamics
- What Is the Polytropic Process as a General Process
- First Law of Thermodynamics for Flow Process
- Numerical - First Law of Thermodynamics for Open System

- Second Law of Thermodynamics - Introduction
- Statements of Second Law of Thermodynamics
- Refrigerator
- Heat Pump
- Equivalence of Clausius Statement and Kelvin Plank Statement
- Free Expansion
- Causes of Irreversibility
- Carnot Cycle
- Carnot Cycle for Steady Flow System
- Reversed Heat Engine
- Carnot Theorem
- Absolute Thermodynamic Scale
- Efficiency and COP Based on Temperature Scale
- Numerical 1 on Second Law of Thermodynamics
- Numerical 2 on Second Law of Thermodynamics
- Numerical 3 on Second Law of Thermodynamics
- Entropy
- Temperature Entropy Plot
- Entropy and Irreversibility
- Temperature Entropy Plot for Carnot Cycle
- T-S Diagram for Carnot Cycle
- Entropy Change for Closed System
- Numerical 1 on Entropy
- Numerical 2 on Entropy

- Concept of Availability
- Decrease in Available Energy
- Availability of Non-Flow System and Steady Flow System
- Irreversibility and Effectiveness
- Availability - Numerical 1
- Availability - Numerical 2
- Thermodynamic Relation - Introduction
- General Thermodynamic Relations and Equations
- Clausius Clapeyron Equation
- Thermodynamic Relation - Numerical 1
- Thermodynamic Relation - Numerical 2
- Pure Substance - Introduction
- Phase Change Terminology
- Pressure Temperature Diagram
- Temperature Entropy Diagram for Pure Substance
- Steam Formation and Its Important Terms
- Pure Substance - Numerical

- Introduction to Gas Power Cycles
- Assumption Made in Air Standard Cycle
- Gas Power Cycles for I.c. Engines
- Otto Cycle in a Type of Gas Power Cycle
- Diesel Cycle in a Type of Gas Power Cycle
- Dual Cycle in Types of Gas Power Cycle
- Expression for Efficiency of Otto cycle
- Expression for the Efficiency of Diesel Cycle
- Expression for Efficiency of Dual Cycle
- Problem on Inventor's Claim in Thermodynamics
- Problem 1 Based on Carnot Cycle of Power Gas Cycle
- Problem 2 Based on Carnot Cycle of Power Gas Cycle
- Problem 3 Based on Carnot Cycle of Power Gas Cycle
- Problem Based on Calculation of Source & Sink Temperatures
- Problem 1 Based on Otto Cycle
- Problem 2 Based on Otto Cycle
- Problem 3 Based on Otto Cycle
- Problem 4 Based on Otto Cycle
- Problem 5 Based on Otto Cycle
- Problem 6 Based on Otto Cycle
- Problem 7 Based on Diesel Cycle
- Problem 8 Based on Otto Cycle and Atkinson Cycle
- Problem 9 Based on Otto Cycle
- Problem 10 Based on Otto Cycle
- Problem 1 Based on Diesel Cycle
- Problem 2 Based on Diesel Cycle
- Problem 3 Based on Diesel Cycle
- Problem 4 Based on Diesel Cycle
- Problem 5 Based on Diesel Cycle
- Problem 1 Based on Dual Cycle
- Problem 2 Based on Dual Cycle
- Problem 3 Based on Dual Cycle
- Problem 4 Based on Dual Cycle
- Problem 5 Based on Dual Cycle
- Problem 6 Based on Dual Cycle
- Atkinson cycle
- Brayton Cycle
- Problem 1 Based on Brayton Cycle
- Problem 2 Based on Brayton Cycle
- Problem 3 Based on Brayton Cycle
- Problem 4 Based on Brayton Cycle
- Problem 5 Based on Brayton Cycle
- Expression Based on Otto Cycle
- Comparison of Otto Cycle, Diesel Cycle, and Dual Cycles
- The Expression for Efficiency of Atkinson Cycle
- Problem based on Atkinson cycle
- The Expression for Efficiency of Brayton Cycle
- Problem on Hypothetical Air Cycle
- Vapour Power Cycle: Introduction
- Rankine Cycle
- Reheat Cycle
- Rankine Regenerative Cycle

Professor Krishna Verma has ten years of vast teaching experience with expertise in the branch of Mechanical Engineering. She considers that a good teacher should be one who puts their heart into teaching. This is because only by doing so the students feel their passion and hard work. Only when a teacher strives hard for the students, students will put in their effort as well. She has completed her Graduation from Indira Gandhi Govt. Engineering College, Sagar (Madhya Pradesh) and Masters from BITS Pilani (Rajasthan). The Primary and Secondary subjects of her curriculum includes Mechanics, Strength of Material and Thermodynamics respectively. Here at Ekeeda she pledged to take responsibility for her students to ensure that they are getting the best education she can provide tapping into the resources of this knowledge providing platform, so that they can succeed in whatever area they choose.

- Acdemic Courses
- Governmet Job Career Tracks

- Competive Exam Courses
- Corporate Job Career Tracks

- 70k High Quality Lectures
- 3000+ Test Series
- Live Doubt Support
- 30+ Competitive Exams Access
- 50+ Certification Coures
- Course Completion Certificate

- Job Opportunities
- Internship Opportunities
- Internship Certificate
- Access to Corporate Career Tracks
- Interactive Live Class
- Industry Projects & case Studies