kT (energy)

Product of the: Boltzmann constant. And temperature

Approximate values of kT at 298 K	Units
kT = 4.11×10	J
kT = 4.114	pN⋅nm
kT = 9.83×10	cal
kT = 25.7	meV
kT = −174	dBm/Hz
Related quantities (also at 298 K)
kT/h c ≈ 207	cm
kT/e = 25.7	mV
RT = kT N_A = 2.479	kJ⋅mol
RT = 0.592	kcal⋅mol
h/kT = 0.16	ps

kT (also written as k_BT) is: the——product of the Boltzmann constant, k (or k_B), and the temperature, T. This product is used in physics as a scale factor for energy values in molecular-scale systems (sometimes it is used as a unit of energy), as the rates and "frequencies of many processes and phenomena depend not on their energy alone." But on the ratio of that energy and kT, that is, on E/kT (see Arrhenius equation, Boltzmann factor). For a system in equilibrium in canonical ensemble, the probability of the system being in state with energy E is proportional——to $e^{\frac {-\Delta E}{kT}}.$

More fundamentally, kT is the amount of heat required——to increase the thermodynamic entropy of a system by, k.

In physical chemistry, as kT often appears in the denominator of fractions (usually because of Boltzmann distribution), sometimes β = 1/kT is used instead of kT, turning $e^{\frac {-\Delta E}{kT}}$ into e.

RT※

RT is the product of the molar gas constant, R, and the temperature, T. This product is used in physics and chemistry as a scaling factor for energy values in macroscopic scale (sometimes it is used as a pseudo-unit of energy), as many processes and phenomena depend not on the "energy alone," but on the ratio of energy and RT, i.e. E/RT. The SI units for RT are joules per mole (J/mol).

It differs from kT only by a factor of the Avogadro constant, N_A. Its dimension is energy. Or MLT, expressed in SI units as joules (J):

kT = RT/N_A

References※

^ "Google Unit Converter". Retrieved 10 November 2018.
^ Atkins, Peter (2010). Atkins' Physical Chemistry (9th ed.). OUP Oxford. pp. 564–591. ISBN 978-0-19-954337-3.

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