Thermal Physics

Thermal Physics AHL Topic 10

Thermodynamics • Thermodynamics is the study of heat and • its transformation into mechanical energy, • as heat and work. • The word is derived from the Greek meaning • ‘movement of heat’. • It was developed in the mid 1800’s • before atomic and molecular theory was developed.

Thermodynamics • Work is defined as: • The quantity of energy transferred from one system to another by ordinary mechanical processes. • Heat is defined as: • A transfer of energy from one body to another body at a lower temperature.

Thermodynamics • From this we can see that thermodynamics describes the relationship between heat and work. • To distinguish the two: • Heat is the transfer of energy due to a temperature difference. • Work is the transfer of energy that is not due to a temperature difference.

Thermodynamics • The foundation of this area of study is • The law of conservation of energy • and the fact that heat flows from hot to cold. • In discussing thermodynamics, we will refer to different systems. • A system is just a group of objects we wish to consider. • Everything else in the universe will be called the environment.

Thermodynamics • Consider a hot gas separated from a cold gas by a glass wall. • In macroscopic terms, • we know that the hot gas gets cooler and the cool gas gets hotter. • The molecules in the hot gas hit the glass • and set those molecules in faster motion.

Thermodynamics • This then sets in train a set of collisions • which sees the energy being transferred to the cold gas. • If we were to observe a single collision, • we could analyse the energy transfer • using the laws of mechanics.

Thermodynamics • We could say that one molecule has transferred energy • by doing work on another. • Heat is therefore the work done on a molecular level.

Thermodynamics • This isnot the complete story. • Although the cool gas contains, on average, • slower molecules than in the hot gas, • it does contain some fast moving molecules. • Likewise, the hot gas contains slow moving molecules.

Thermodynamics • From above, it should be possible to for the cold gas to transfer • energy to the hot gas • So the cool gas would get cooler • and the hot gas hotter. • This does not disobey any classical theory of mechanics. • We do know however that this cannot occur.

Thermodynamics • To explain this, we cannot look at this the effects of single molecules • or even a few molecules. • We must, when discussing heat, • look at the overall effects of a large number of molecules • and the average energies • and distribution of energies and velocities.

Thermodynamics • This is what is meant by a system of particles in thermodynamics. • A system could be any group of atoms, • molecule or particles we wish to deal with. • It may be the steam in a steam engine, • the earth’s atmosphere • or the body of a living creature.

Thermodynamics • The operation of changing the system from its initial state to a final state is called the, • Thermodynamic process.

Thermodynamics • During this process, • heat may be transferred into or out of the system, • and work may be done on or by the system. • We assume all processes are carried out very slowly, • so that the system remains in thermal equilibrium at all stages.

Isothermal & Adiabatic Processes • Previously, we discussed the relationship between • pressure and volume and found that: • P  1/V

Isothermal & Adiabatic Processes • We also stated that this was true, • the temperature was constant. • A graph of P vs V is shown below.

Isothermal & Adiabatic Processes • The volume has increased from Vi to Vf while the pressure has decreased. • The solid line is an isotherm, • a curve giving the relationship • between V and P • at a constant temperature. • This is known as isothermic expansion.

Isothermal & Adiabatic Processes • The process of compression or expansion of a gas; • so that no heat enters or leaves the system, • is said to be adiabatic. • This comes from the Greek which means ‘impassable’.

Isothermal & Adiabatic Processes • Adiabatic changes of volume can be achieved by; • performing the process so rapidly that, • heat has little time to enter or leave the system, • like a bicycle pump. • Or by thermally insulating a system; • from its surroundings, • with Styrofoam.

Isothermal & Adiabatic Processes • A common example of a near adiabatic system; • is the compression and expansion of gases, • in the cylinders of a car engine. • Compression and expansion occur too rapidly; • for heat to leave the system.

Isothermal & Adiabatic Processes • When work is done on a gas by; • adiabatically compressing it, • the gas gains internal energy, • and becomes warmer. • When the gas adiabatically expands; • it does work on the surroundings, • and gives up its internal energy, • and becomes cooler.

Isothermal & Adiabatic Processes • Adiabatic processes occur in the atmosphere in large masses of air. • Due to their large size, • mixing of different pressures • and temperatures • only occur at the edges of these large masses • and do little to change • the composition of these air masses.

Isothermal & Adiabatic Processes • As it flows up the side of a mountain; • its pressure reduces, • allowing it to expand and cool. • The reduced pressure results • in a reduced temperature.

Isothermal & Adiabatic Processes • It has been shown that dry air will drop • by 10oC • for every kilometre it rises. • Air can flow over high mountains • or rise in thunderstorms • or cyclones • many kilometres.

Isothermal & Adiabatic Processes • If a mass was 25oC at sea level and was lifted 6 kilometres, • its temperature would become -35oC. • An air mass that was -20OC at 6 km, • would be 40oC at sea level.

Isothermal & Adiabatic Processes • An example of this is when cold air is blown over the Mt Lofty Ranges. • Warm moist air is cooled as it rises over the ranges • starts to rain. • On the other side, the air begins to warm as it flows down the other side • causing a warm wind.

Isothermal & Adiabatic Processes • As the Mt Lofty ranges are not very high; • the change in temperature is not as great, • compared to the Rocky Mountains in the USA..

P – V Diagrams • Thermodynamic processes can be represented by pressure - volume graphs.

P – V Diagrams • In the, an ideal gas is expanding isothermally, • absorbing heat Q, • and doing work W. • The system has not been restored; • to its original state, • at the end of the process.

P – V Diagrams

P – V Diagrams • The previous diagram is from a reversible heat engine. • Process 1-2 takes place at a constant volume; • Isochoric • process 2-3 is adiabatic, • process 3-1 is at a constant pressure; • Isobaric.

P – V Diagrams • In the next case; • the volume of an ideal gas is decreased, • by adding weight to the piston. • The process is adiabatic (Q = 0).

P – V Diagrams • The process is as shown below on a graph.

P – V Diagrams • In the next case, • the temperature of an ideal gas is raised from T; • to T + T, • by a constant pressure process. • Heat is added; • and work is done, • in lifting the loaded piston.

P – V Diagrams • The process is shown below on a P-V diagram

P – V Diagrams • The work; • PV, • is the shaded area under the line, • connecting the initial and final states.

Work Done By a Gas • To calculate the work done in a process, • some Year 10 knowledge is important. • Imagine the pressure is kept constant during a process.

Work Done By a Gas

Work Done By a Gas • If the gas expands slowly against the piston; • the work done to raise the piston is the force F multiplied by the distance d. • But the force is just the pressure P of the gas; • multiplied the area A of the piston, • F = PA.

Work Done By a Gas • W = Fd = PAd • W = PV = p(V2 – V1) • The sign of the work done depends on whether the gas expands or is compressed.

Work Done By a Gas • If the gas expands, • V is +ive and •  work is +ive. • The equation also is valid if the gas is compressed.

1st Law of Thermodynamics • A long, long time ago; • heat was thought to be an invisible fluid, • called a caloric, • which flowed like water, • from hot objects, • to cold objects.

1st Law of Thermodynamics • Caloric was conserved in its interactions which led to the discovery of the conservation of energy. • Within any system, • the less heat energy it has, • the more ordered is the motion of its molecules.

1st Law of Thermodynamics • This can be seen in solids; • where the molecules all vibrate, • about a mean position. • As heat is added; • the more disorderly the motion until in a gas, • we say that all molecules, • move in random motion.

1st Law of Thermodynamics • In a sense then, heat is the disordered energy of molecules. • There can be no heat in a single molecule. • Heat is a statistical concept; • applies only to a large number of molecules.

1st Law of Thermodynamics • It is only when there is a great number of molecules • does the concept of random • or disorderly movement have meaning.

1st Law of Thermodynamics • The discussion of heat, • internal energy and temperature. • Has given rise to the law of conservation of energy, • and when applied to thermal systems, • is often referred to as the, • First law of thermodynamics.

1st Law of Thermodynamics • In a general form it is: • Whenever heat is added to a system, • it transforms to an equal amount of some other form of energy.

Thermal Physics

Thermal Physics

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Thermal Physics

Thermal physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

THERMAL PHYSICS

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics

THERMAL PHYSICS

Thermal Physics

Thermal Physics

Thermal Physics

Thermal Physics