The rate and extent to which chemical reactions occur

Yüklə 54,15 Kb.

səhifə	7/16
tarix	22.07.2023
ölçüsü	54,15 Kb.
	#119831

1 2 3 4 5 6 7 8 9 10 ... 16

Tempertaure

Plasma physics
Theoretical foundation

Temperature conversions

	from Celsius	to Celsius
Fahrenheit	[°F] = [°C] × ⁹⁄₅ + 32	[°C] = ([°F] − 32) × ⁵⁄₉
Kelvin	[K] = [°C] + 273.15	[°C] = [K] − 273.15
Rankine	[°R] = ([°C] + 273.15) × ⁹⁄₅	[°C] = ([°R] − 491.67) × ⁵⁄₉
Delisle	[°De] = (100 − [°C]) × ³⁄₂	[°C] = 100 − [°De] × ²⁄₃
Newton	[°N] = [°C] × ³³⁄₁₀₀	[°C] = [°N] × ¹⁰⁰⁄₃₃
Réaumur	[°Ré] = [°C] × ⁴⁄₅	[°C] = [°Ré] × ⁵⁄₄
Rømer	[°Rø] = [°C] × ²¹⁄₄₀ + 7.5	[°C] = ([°Rø] − 7.5) × ⁴⁰⁄₂₁

Plasma physics

The field of plasma physics deals with phenomena of electromagnetic nature that involve very high temperatures. It is customary to express temperature as energy in units of electronvolts (eV) or kiloelectronvolts (keV). The energy, which has a different dimension from temperature, is then calculated as the product of the Boltzmann constant and temperature, {\displaystyle E=k_{\text{B}}T} Then, 1 eV corresponds to 11605 K. In the study of QCD matter one routinely encounters temperatures of the order of a few hundred MeV, equivalent to about 10¹² K.

Theoretical foundation

Historically, there are several scientific approaches to the explanation of temperature: the classical thermodynamic description based on macroscopic empirical variables that can be measured in a laboratory; the kinetic theory of gases which relates the macroscopic description to the probability distribution of the energy of motion of gas particles; and a microscopic explanation based on statistical physics and quantum mechanics. In addition, rigorous and purely mathematical treatments have provided an axiomatic approach to classical thermodynamics and temperature. Statistical physics provides a deeper understanding by describing the atomic behavior of matter and derives macroscopic properties from statistical averages of microscopic states, including both classical and quantum states. In the fundamental physical description, using natural units, the temperature may be measured directly in units of energy. However, in the practical systems of measurement for science, technology, and commerce, such as the modern metric system of units, the macroscopic and the microscopic descriptions are interrelated by the Boltzmann constant, a proportionality factor that scales temperature to the microscopic mean kinetic energy.
The microscopic description in statistical mechanics is based on a model that analyzes a system into its fundamental particles of matter or into a set of classical or quantum-mechanical oscillators and considers the system as a statistical ensemble of microstates. As a collection of classical material particles, the temperature is a measure of the mean energy of motion, called kinetic energy, of the particles, whether in solids, liquids, gases, or plasmas. The kinetic energy, a concept of classical mechanics, is half the mass of a particle times its speed squared. In this mechanical interpretation of thermal motion, the kinetic energies of material particles may reside in the velocity of the particles of their translational or vibrational motion or in the inertia of their rotational modes. In monatomic perfect gases and, approximately, in most gas, the temperature is a measure of the mean particle kinetic energy. It also determines the probability distribution function of energy. In condensed matter, and particularly in solids, this purely mechanical description is often less useful and the oscillator model provides a better description to account for quantum mechanical phenomena. Temperature determines the statistical occupation of the microstates of the ensemble. The microscopic definition of temperature is only meaningful in the thermodynamic limit, meaning for large ensembles of states or particles, to fulfill the requirements of the statistical model.
Kinetic energy is also considered as a component of thermal energy. The thermal energy may be partitioned into independent components attributed to the degrees of freedom of the particles or to the modes of oscillators in a thermodynamic system. In general, the number of these degrees of freedom that are available for the equipartitioning of energy depends on the temperature, i.e. the energy region of the interactions under consideration. For solids, the thermal energy is associated primarily with the vibrations of its atoms or molecules about their equilibrium position. In an ideal monatomic gas, the kinetic energy is found exclusively in the purely translational motions of the particles. In other systems, vibrational and rotational motions also contribute degrees of freedom.

Yüklə 54,15 Kb.

Dostları ilə paylaş:

1 2 3 4 5 6 7 8 9 10 ... 16