Physics Subject Area Test Thermodynamics. There are three commonly used temperature scales, Fahrenheit, Celsius and Kelvin.

Slides:



Advertisements
Similar presentations
The Laws of Thermodynamics
Advertisements

Thermodynamics AP Physics Chapter 15.
Chapter 9 Thermal Energy
Lecture 02: Work and Energy
Thermodynamics II The First Law of Thermodynamics
Chapter 15. Work, Heat, and the First Law of Thermodynamics
Thermodynamics April 27, 2015April 27, 2015April 27, 2015.
Section 1 Notes: Temperature Scales and Conversions
Thermal Physics.
1 UCT PHY1025F: Heat and Properties of Matter Physics 1025F Heat & Properties of Matter Dr. Steve Peterson THERMODYNAMICS.
The Zeroth and First Laws. Mechanical energy includes both kinetic and potential energy. Kinetic energy can be changed to potential energy and vice versa.
Lecture 2 The First Law of Thermodynamics (Ch.1)
First Law of Thermodynamics Physics 102 Professor Lee Carkner Lecture 6 “of each the work shall become manifest, for the day shall declare it, because.
Lecture 2 The First Law of Thermodynamics (Ch.1)
First law of thermodynamics
Heat Chapter 9 &10. Kinetic-molecular Theory Matter is made up of many tiny particles that are always in motion In a hot body the particles move faster.
Physics 121, April 24. Heat and the First Law of Thermodynamics.
The Laws of Thermodynamics
Heat, Temperature, Heat Transfer, Thermal Expansion & Thermodynamics.
1 Thermal Physics 13 - Temperature & Kinetic Energy 15 - Laws of Thermodynamics.
MHS Physics Department AP Unit II C 2 Laws of Thermodynamics Ref: Chapter 12.
Heat. Heat and Temperature Kinetic Molecular Theory – Is the theory that matter is made up of atoms (smallest piece of matter) and that these atoms are.
Thermodynamics AP Physics 2.
Thermal Energy and Matter Chapter 16. Heat Heat is the transfer of thermal energy from one object to another due to a temperature difference – Flows from.
The Laws of Thermodynamics
Physics 12 Giancoli Chapter 15
Thermodynamics.
Thermodynamics AP Physics B. Thermal Equlibrium The state in which 2 bodies in physical contact with each other have identical temperatures. No heat flows.
17.4 State Variables State variables describe the state of a system
THERMODYNAMICS Branch of science which deals with the processes involving heat and temperature inter conversion of heat and other forms of energy.
1 Introduction Physics 313 Professor Lee Carkner Lecture 1.
The Laws of Thermodynamics
Thermal Physics Thermal Physics is the study of temperature and heat and how they effect matter. Heat leads to change in internal energy which shows as.
Heat, Temperature, Heat Transfer, Thermal Expansion & Thermodynamics.
Thermodynamics Chapter 12.
Chapter 12 The Laws of Thermodynamics. Homework, Chapter 11 1,3,5,8,13,15,21,23,31,34.
Thermal contact Two systems are in thermal (diathermic) contact, if they can exchange energy without performing macroscopic work. This form of energy.
Chapter-18 Temperature, Heat and the First Law of Thermodynamics.
Chapter 10 Thermal Energy. Chapter Objectives Define Temperature Converting between the 3 temperature scales Identify Linear Expansion Utilize the Coefficient.
IB Physics Topic 10 – Thermodynamic Processes Mr. Jean.
Thermodynamics AP Physics Chapter 15. Thermodynamics 13.3 Zeroth Law of Thermodynamics.
Deduce an expression for the work involved in a volume change of a gas at constant pressure State the first law of thermodynamics. 1 Students.
The Laws of Thermodynamics
Heat and the 2 nd Law of Thermodynamics.  Although we learned in the first law that the total amount of energy, including heat, is conserved in an isolated.
حرارة وديناميكا حرارية
Chapter 13: Thermodynamics
Temperature and Kinetic Theory
Thermal Expansion D L = a Lo D T D L = change in_______
Chapter 12: Thermal Energy What’s hot and what’s not…
Heat & The First Law of Thermodynamics
Thermodynamics Internal energy of a system can be increased either by adding energy to the system or by doing work on the system Remember internal energy.
1 Work and Heat Readings: Chapter Internal Energy -Initial kinetic energy is lost due to friction. -This is not completely true, the initial kinetic.
Chapter 5 Thermal Energy
The First Law of Thermodynamics The Law of Conservation of Energy.
HEAT. Thermal energy –The kinetic and potential energy of the random microscopic motion of molecules, atoms, ions, electrons & other particles Heat –The.
Thermodynamics Thermodynamics is a branch of physics concerned with heat and temperature and their relation to energy and work.
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley. Chapter 15. Work, Heat, and the First Law of Thermodynamics.
Work andHeat Mechanical Energy E mech = K + U If there are only conservative forces ( ex. Gravity force, spring force) in the system ΔE mech = ΔK + ΔU.
Thermodynamics. Temperature and thermal equilibrium Temperature is the measure of the internal energy of an object. Internal energy: the energy of a substance.
Raymond A. Serway Chris Vuille Chapter Twelve The Laws of Thermodynamics.
Chemical Thermodynamics Lecture 1. Chemical Thermodynamics Prepared by PhD Halina Falfushynska.
AP Physics B Ch. 12: Laws of Thermodynamics. Internal energy (U) Sum of the kinetic energy of all particles in a system. For an ideal gas: U = N K ave.
Thermodynamics AP B. ‘its hot enough to fry an egg on the sidewalk’
Heat, Temperature, Heat Transfer, Thermal Expansion & Thermodynamics.
Physics 141Mechanics Lecture 24 Heat and Temperature Yongli Gao So far we have concentrated on mechanical energy, including potential and kinetic energy.
In this chapter you will:  Learn how temperature relates to the potential and kinetic energies of atoms and molecules.  Distinguish heat from work. 
Chapter 16 Temperature and Heat.  Definition of heat: Heat is the energy transferred between objects because of a temperature difference.  Objects are.
Chapter 12 The Laws of Thermodynamics. First Law of Thermodynamics The First Law of Thermodynamics tells us that the internal energy of a system can be.
Government Engineering College, Dahod Mechanical Engineering Department SUB- Engg. thermodynamics ( ) Topic: First law of thermodynamics Prepared.
Chapter 10 Energy.
Presentation transcript:

Physics Subject Area Test Thermodynamics

There are three commonly used temperature scales, Fahrenheit, Celsius and Kelvin.

Converting Between the Kelvin and Celsius Scales Converting Between the Fahrenheit and Celsius Scales

Thermal expansion Expanding solids maintain original shape Expanding liquids conform to the container Linear expansion ΔL = αLΔTL = length α = coefficient of liner expansion ΔT = temperature change

Example: The highest tower in the world is the steel radio mast of Warsaw Radio in Poland, which has a height if 646m. How much does its height increase between a cold winter day when the temperature is -35⁰C and a hot summer day when the temperature is +35 ⁰C ? ΔL = αLΔT = 12x10 -6 / ⁰C x 646 x 70 ⁰C = 0.54m

Volume expansion ΔV= βVΔTL = length β = coefficient of liner expansion ΔT = temperature change coldhot Β = 3 α

Heat flow: the heat current; the amount of heat that passes by some given place on the rod per unit time

* convection Heat is stored in a moving fluid and is carried from one place to another by the motion of this fluid * radiation The heat is carried from one place to another by electromagnetic waves * conduction the process of handing on energy from one thing to the next

P 1 V 1 =P 2 V 2 P= pressure V = volume

V 1 /V 2 =T 1 /T 2 V = volume T = temperature

P 1 /T 1 =P 2 /T 2 P = pressure T = temperature

Ideal Gas Law PV = n R T P= pressure V = volume T = temperature n = moles R = Gas constant = L-atm/mol K

PV = nRT n/V = P/RT Molarity = n/V Density D = m/V Molecular Wt M = m/n D=Mn/V = PM/RT M= DRT/P

Energy can be neither created nor destroyed but only transformed

THE GENERAL ENERGY EQUATION Energy In = Energy Out or U 2 - U 1 = Q -W where U 1 : internal energy of the system at the beginning U 2 : internal energy of the system at the end Q : net heat flow into the system W : net work done by the system Q = ΔU + ΔW

A closed tank has a volume of 40.0 m 2 and is filled with air at 25 ⁰C and 100 kPa. We want to maintain the temperature in the tank at 25 ⁰C as water is pumped into it. How much heat will have to be removed from the air in the tank to fill it half full? = (100kPa) (40.0 m 2 )( ) = kJ

Isobaric –the pressure of and on the working fluid is constant –represented by horizontal lines on a graph Isothermal –temperature is constant –Temperature doesn’t change, internal energy remains constant, & the heat absorbed by the gas = the work done by the gas –The PV curve is a hyperbola Adiabatic –there is no transfer of heat to or from the system during the process –Work done = decrease in internal energy & the temperature falls as the gas expands –-the PV curve is steeper than that of and isothermal expansion

Quasi-static (quasi-equilibrium) processes – sufficiently slow processes, any intermediate state can be considered as an equilibrium state (the macroparamers are well- defined for all intermediate states). Examples of quasi- equilibrium processes: isochoric: V = const isobaric: P = const isothermal: T = const adiabatic: Q = 0 For quasi-equilibrium processes, P, V, T are well-defined – the “path” between two states is a continuous lines in the P, V, T space. P V T 1 2 Advantage: the state of a system that participates in a quasi-equilibrium process can be described with the same (small) number of macro parameters as for a system in equilibrium (e.g., for an ideal gas in quasi- equilibrium processes, this could be T and P). By contrast, for non- equilibrium processes (e.g. turbulent flow of gas), we need a huge number of macro parameters.

The sign: if the volume is decreased, W is positive (by compressing gas, we increase its internal energy); if the volume is increased, W is negative (the gas decreases its internal energy by doing some work on the environment). The work done by an external force on a gas enclosed within a cylinder fitted with a piston: W = (PA) dx = P (Adx) = - PdV xx P W = - PdV - applies to any shape of system boundary The work is not necessarily associated with the volume changes – e.g., in the Joule’s experiments on determining the “mechanical equivalent of heat”, the system (water) was heated by stirring. dU = Q – PdV A – the piston area force

* Specific Heat the heat absorbed during the change of state Q = nC v ΔTQ = amount of heat required n = number of moles C v = specific heat at a constant volume ΔT = Change in temperature

How to calculate changes in thermal energy Specific heat is the amount of heat required to raise the temperature of 1 kg of a material by one degree (C or K). C water = 4184 J / kg C Q = m x  T x C p Q = change in thermal energy m = mass of substance  T = change in temperature (T f – T i ) C p = specific heat of substance

Second Law of Thermodynamics Entropy = the transformation of energy to a more disordered state - can be thought of as a measure of the randomness of a system - related to the various modes of motion in molecules The second law of thermodynamics: entropy of an isolated system not in equilibrium tends to increase over time No machine is 100% efficient Heat cannot spontaneously pass from a colder to a hotter object

The relationship between kinetic energy and intermolecular forces determines whether a collection of molecules will be a solid, liquid or a gas * Pressure results from collisions * The # of collisions and the KE contribute to pressure * Temperature increase KE