Chapter 4

... • Temperature is a measure of heat content of atoms and molecules. • The higher the temperature the more heat the atoms and/or molecules of the substance contain. • The higher the heat and temperature the higher the average kinetic energy of the atoms and molecules of the substance (element or compo ...

Combustion Chemistry

Chapter 12 - HCC Learning Web

... volume for a monatomic ideal gas ...

2. Classical Gases

... directions). And each particle contributes 12 DkB T towards the average energy. This is a general rule of thumb, which holds for all classical systems: the average energy of each free degree of freedom in a system at temperature T is 12 kB T . This is called the equipartition of energy. As stated, i ...

Basic Properties of the Atmosphere

Energy, Work and Heat - abuad lms

... Open System permit the flow of both mass and energy across its boundaries, example is the turbine, the flow of water through a pipe. An open system is also called a control volume and its boundary is called control surface. Isolated system is a system that neither energy nor mass flows out of the bo ...

What are the 3 primary phases of matter?

... In a balloon, the particles of gas strike the walls more often because they move faster so the pressure increases making the balloon larger ...

Chapter 15: Thermal Properties of Matter

Part IV

Work, Energy and Momentum Notes

Example 1.1: Energy of an Extended Spring

... Example 2.1: Average speed of a molecule in a gas The probability of a molecule of mass m in a non-interacting gas at temperature T (K) having a magnitude of velocity (speed) between v and v + dv is given by the Maxwell-Boltzmann distribution P (v)dv = N v 2 exp −mv 2 /2kT dv, ...

heat

Carnot Cycle - University of Wyoming

... • A disorderly arrangement is much more probable than an orderly one if the laws of nature are allowed to act without interference – This comes from a statistical mechanics development ...

Mr Alasdair Ross at Southpointe Academy: Math and Chemistry Pages

Chapter 3. Energy and the First Law

... Sungkyunkwan University Chemical Engineering ...

t 0 - PhysicsEducation.net

... The specific heat of water is greater than that of copper. A piece of copper metal is put into an insulated calorimeter which is nearly filled with water. The mass of the copper is the same as the mass of the water, but the initial temperature of the copper is lower than the initial temperature of t ...

Set 3

... If the work done on a system is reverseable, we call it configuration work. This is because in almost all cases, reverseable processes do something to change the macroscopic configuration of the system. This in general can be undone. Consider the compression of an ideal gas by a piston. Of the syste ...

Lattice Vibrations

... The Breakdown of the Static Lattice Model • The free electron model was refined • The classical static lattice can only be by introducing a crystalline external valid for T=0K potential • It is even wrong for T=0K: ∆x∆p ≥ h̄ ⇒ Zero point motion • This allows much progress, but is not the full story ...

Chapter 12

chapter12_PC

Section 3. Matter Course Notes

grand canonical partition function

chem 155 trial questions

... 34. An isolated system is best described by which one of the following statements? a. Neither matter nor heat can pass into or out of the system b. The system has a boundary which allows heat to be transferred but does not allow material to pass into or out of the system c. The system has a diatherm ...

Chapter 16 Power Point Notes

... temperature is increased? a. The number of particles increases as temperature increases. b. Each particle expands as its temperature increases, so the total volume increases. c. As temperature increases, more electrons leave atoms and move separately. d. As gas particles move faster, they overcome s ...

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Equipartition theorem

In classical statistical mechanics, the equipartition theorem is a general formula that relates the temperature of a system with its average energies. The equipartition theorem is also known as the law of equipartition, equipartition of energy, or simply equipartition. The original idea of equipartition was that, in thermal equilibrium, energy is shared equally among all of its various forms; for example, the average kinetic energy per degree of freedom in the translational motion of a molecule should equal that of its rotational motions.The equipartition theorem makes quantitative predictions. Like the virial theorem, it gives the total average kinetic and potential energies for a system at a given temperature, from which the system's heat capacity can be computed. However, equipartition also gives the average values of individual components of the energy, such as the kinetic energy of a particular particle or the potential energy of a single spring. For example, it predicts that every atom in a monatomic ideal gas has an average kinetic energy of (3/2)kBT in thermal equilibrium, where kB is the Boltzmann constant and T is the (thermodynamic) temperature. More generally, it can be applied to any classical system in thermal equilibrium, no matter how complicated. The equipartition theorem can be used to derive the ideal gas law, and the Dulong–Petit law for the specific heat capacities of solids. It can also be used to predict the properties of stars, even white dwarfs and neutron stars, since it holds even when relativistic effects are considered.Although the equipartition theorem makes very accurate predictions in certain conditions, it becomes inaccurate when quantum effects are significant, such as at low temperatures. When the thermal energy kBT is smaller than the quantum energy spacing in a particular degree of freedom, the average energy and heat capacity of this degree of freedom are less than the values predicted by equipartition. Such a degree of freedom is said to be ""frozen out"" when the thermal energy is much smaller than this spacing. For example, the heat capacity of a solid decreases at low temperatures as various types of motion become frozen out, rather than remaining constant as predicted by equipartition. Such decreases in heat capacity were among the first signs to physicists of the 19th century that classical physics was incorrect and that a new, more subtle, scientific model was required. Along with other evidence, equipartition's failure to model black-body radiation—also known as the ultraviolet catastrophe—led Max Planck to suggest that energy in the oscillators in an object, which emit light, were quantized, a revolutionary hypothesis that spurred the development of quantum mechanics and quantum field theory.

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Equipartition theorem