Energy: 1. Energy is an abstract physical quantity 2. It can be measured only by means of its effect Vikasana - Bridge Course

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1 BASICS OF THERMODYNAMICS Vikasana - Bridge Course

2 Energy: 1. Energy is an abstract physical quantity 2. It can be measured only by means of its effect Vikasana - Bridge Course

3 HEAT Heat is a form of energy Vikasana - Bridge Course

4 Effects of Heat: 1. Expansion 2. Rise in temperature 3. Work done Vikasana - Bridge Course

5 Work done: According to the law of mechanics, energy is measured by amount of work done Vikasana - Bridge Course

6 Thermodynamics: Macroscopic science it deals with bulk system Branch of physics deals with inter conversion of heat into other form of energy (work) Vikasana - Bridge Course

7 Examples: 1. When water in a container starts t boiling, plate covering the container starts moving up and down. 2. Rub your hands one against the another for few second you will feel that your hands are wormed. Vikasana - Bridge Course

8 Mechanical work of rubbing hands is converted in to heat Vikasana - Bridge Course

9 Conclusion: It is possible to convert work in to heat or heat in to work. Vikasana - Bridge Course

10 LORD Kelvin Named the process as Thermodynamics Vikasana - Bridge Course

11 In Latin thermodynamics means Motion of Heat Vikasana - Bridge Course

12 Basic terms required to understand thermodynamics Vikasana - Bridge Course

13 1. Closed system: There is no mass transferred between the system and the surroundings. Vikasana - Bridge Course

14 02. Open system: There will be both matter and energy transfer across the boundary of the system. Vikasana - Bridge Course

15 03. Isolated system: There is neither matter nor energy transfer across the boundary of the system. Vikasana - Bridge Course

16 04. Thermodynamic system: A certain amount of matter under investigation. Vikasana - Bridge Course

17 05. Surroundings: A given thermodynamic system interacts with all other matter outside the system. The matter outside the system is called the surrounding. Vikasana - Bridge Course

18 Thermodynamic Variables OR Thermodynamic co-ordinates, ordinates, measurable quantities such as i) )p pressure ii) volume and iii) temperature are called thermodynamic variables. Vikasana - Bridge Course

19 Mechanical Equilibrium: There should be no unbalanced forces between the various parts of the systems or between the system and the surrounding Vikasana - Bridge Course

20 Thermal Equilibrium: The temperature of every part of the system must be same as that t of surroundings *A *B *C *D T A = T C = T B = T D Vikasana - Bridge Course

21 Chemical Equilibrium: Chemical composition of the system stand remain fixed and definite. Vikasana - Bridge Course

22 Thermodynamic Equilibrium: A thermodynamic system is said to be in complete equilibrium, it is in mechanical, thermal and chemical equilibrium. Vikasana - Bridge Course

23 Equation of State: t The equation relating the thermodynamic co-ordinates ordinates is called the equation of state. Ex:- PV = RT represents the equation of state for a perfect gas Vikasana - Bridge Course

24 Thermodynamic process: Taking the thermodynamic system form one thermodynamic state to another thermodynamic state. Ex:- Compression or Expansion of gas Vikasana - Bridge Course

25 Internal Energy: Every system (solid, liquid or gas) possess two types of energy. 1. Potential Energy (PE) 2. Kinetic Energy (KE) Vikasana - Bridge Course

26 * Kinetic Energy is due to motion of molecules l with in the system. * Potential Energy is due to molecular configurations of the molecules. Total energy of the system (E) = PE + KE Vikasana - Bridge Course

27 Internal energy of the Real gas depends on volume and temperature. Vikasana - Bridge Course

28 When temperature of the gas is increased, the molecules move rapidly and randomly, there by increasing the K.E Vikasana - Bridge Course

29 Increasing the KE in turn increases the internal energy of the gas Vikasana - Bridge Course

30 Internal energy can be taken as a measure of temperature. Vikasana - Bridge Course

31 In thermodynamics there are three laws: 1. Zeroth Law of thermodynamics 2. First Law of thermodynamics, and 3. Second Law of thermodynamics Vikasana - Bridge Course

32 Zeroth Law of Thermodynamics: R.H Flower formulated this law in 1931, By that time I Law and II Law had already been formulated. Hence this law is called Zeroth Law. It is more basic Vikasana - Bridge Course

33 Zeroth Law of Thermodynamics Statement:- If a two system A and B are separately in thermal equilibrium with third system C, then A and B are in thermal equilibrium with each other. Vikasana - Bridge Course

34 Explanation:- If T A = T C then A and C are in equilibrium. Similarly if T B = T c then B and C are in equilibrium. According to zeroth law A and B are in thermal equilibrium with each other if T A = T C and T B = T C, then T A = T B AT A CT C T B T B Vikasana - Bridge Course

35 Significance of zeroth Law: zeroth law gives a measurable quantity to decide whether two systems are in equilibrium or not. Vikasana - Bridge Course

36 First Law of Thermodynamics Statement:- Heat energy given to a system is equal to the sum of the increase in internal energy and the external workdone by the system. Vikasana - Bridge Course

37 Explanation: dq = du + dw du change in internal energy dw work done dq Heat energy given to a system Vikasana - Bridge Course

38 Sign convension: * When heat is given to a system dq is taken as +ve. * If the heat is drawn from the system dq is taken as ve. Vikasana - Bridge Course

39 Phase diagram: A graphical representation of variation of pressure (P) and temperature (T) at constant volume (V). Vikasana - Bridge Course

40 Indicator diagram (P-V diagram): The graphical representation of variation of Pressure with the Volume of the system is called P-V diagram or Indicator diagram Vikasana - Bridge Course

41 p-v diagram or Indicator diagram y-axis A(p 1 v 1 ) p B(p 2 v 2 ) v x-axis Vikasana - Bridge Course

42 Indicator diagram help us to determine work done by the gas or on the gas during thermodynamic process Vikasana - Bridge Course

43 Applications of first law of Thermodynamics Vikasana - Bridge Course

44 1. Isothermal process: It is a thermodynamic process that takes place at constant temperature dq = du + dw du = 0 dq = dw Ex: Ice is converted into water at 0 C Vikasana - Bridge Course

45 2. Adiabatic process: Heat can neither enters the system nor leaves the system dq = 0 du = - dw. Ex: Bursting of cycle tyre. Vikasana - Bridge Course

46 3. Isobaric process: The thermodynamic process that takes place at constant pressure none of the quantities du, dw and dq is zero. Ex: 1) Heating water in atmospheric pressure. 2) Conversion of ice into water. Vikasana - Bridge Course

47 4. Isochoric process: The thermodynamic process that t takes place at constant volume dw = 0 dq = du + p.dv dq = du Ex: When ice melts, the change in volume is negligeble. Vikasana - Bridge Course

48 Reversible process: The process that t can be retraced in the reverse direction, so that all the changes occurring in the direct process are reversed. Ex:- 1. Evaporation of water 2. Condensation of vapour 3. Ice changing into water. Vikasana - Bridge Course

49 Irreversible process: The process that cannot be retraced back in the reverse direction. Ex:- 1. Sudden expansion of gas 2. Heat produced by friction Vikasana - Bridge Course

Thermodynamic system is classified into the following three systems. (ii) Closed System It exchanges only energy (not matter) with surroundings.

Thermodynamic system is classified into the following three systems. (ii) Closed System It exchanges only energy (not matter) with surroundings. 1 P a g e The branch of physics which deals with the study of transformation of heat energy into other forms of energy and vice-versa. A thermodynamical system is said to be in thermal equilibrium when