Temperature given Gibbs free entropy Calculator

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✖The internal energy of a thermodynamic system is the energy contained within it. It is the energy necessary to create or prepare the system in any given internal state.ⓘ Internal Energy [U]			+10% -10%
✖Pressure is the force applied perpendicular to the surface of an object per unit area over which that force is distributed.ⓘ Pressure [P]			+10% -10%
✖Volume is the amount of space that a substance or object occupies or that is enclosed within a container.ⓘ Volume [V_T]			+10% -10%
✖Entropy is the measure of a system’s thermal energy per unit temperature that is unavailable for doing useful work.ⓘ Entropy [S]			+10% -10%
✖The Gibbs free entropy is an entropic thermodynamic potential analogous to the free energy.ⓘ Gibbs Free Entropy [Ξ]			+10% -10%

✖The temperature of liquid is the degree or intensity of heat present in a liquid.ⓘ Temperature given Gibbs free entropy [T]

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Formula

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Temperature given Gibbs free entropy

Formula

`"T" = (("U"+("P"*"V"_{"T"}))/("S"-"Ξ"))`

Example

`"29.55172K"=(("121J"+("800Pa"*"63L"))/("16.8 J/K"-"11J/K"))`

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Temperature given Gibbs free entropy Solution

STEP 0: Pre-Calculation Summary

Formula Used

Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy))
T = ((U+(P*V_T))/(S-Ξ))
This formula uses 6 Variables

Variables Used

Temperature of Liquid - (Measured in Kelvin) - The temperature of liquid is the degree or intensity of heat present in a liquid.
Internal Energy - (Measured in Joule) - The internal energy of a thermodynamic system is the energy contained within it. It is the energy necessary to create or prepare the system in any given internal state.
Pressure - (Measured in Pascal) - Pressure is the force applied perpendicular to the surface of an object per unit area over which that force is distributed.
Volume - (Measured in Cubic Meter) - Volume is the amount of space that a substance or object occupies or that is enclosed within a container.
Entropy - (Measured in Joule per Kelvin) - Entropy is the measure of a system’s thermal energy per unit temperature that is unavailable for doing useful work.
Gibbs Free Entropy - (Measured in Joule per Kelvin) - The Gibbs free entropy is an entropic thermodynamic potential analogous to the free energy.

STEP 1: Convert Input(s) to Base Unit

Internal Energy: 121 Joule --> 121 Joule No Conversion Required
Pressure: 800 Pascal --> 800 Pascal No Conversion Required
Volume: 63 Liter --> 0.063 Cubic Meter (Check conversion here)
Entropy: 16.8 Joule per Kelvin --> 16.8 Joule per Kelvin No Conversion Required
Gibbs Free Entropy: 11 Joule per Kelvin --> 11 Joule per Kelvin No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

T = ((U+(P*V_T))/(S-Ξ)) --> ((121+(800*0.063))/(16.8-11))

Evaluating ... ...

T = 29.551724137931

STEP 3: Convert Result to Output's Unit

29.551724137931 Kelvin --> No Conversion Required

FINAL ANSWER

29.551724137931 ≈ 29.55172 Kelvin <-- Temperature of Liquid

(Calculation completed in 00.020 seconds)

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K J Somaiya College of science (K J Somaiya), Mumbai

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< 14 Temperature of Concentration Cell Calculators

Temperature of concentration cell with transference given valencies

Go Temperature of Liquid = ((EMF of Cell*Number of Positive and Negative Ions*Valencies of Positive and Negative Ions*[Faraday])/(Transport Number of Anion*Total number of Ions*[R]))/ln(Cathodic Ionic Activity/Anodic Ionic Activity)

Temperature of Concentration Cell with Transference given Transport Number of Anion

Go Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*Transport Number of Anion*[R]))/(ln(Cathodic Electrolyte Molality*Cathodic Activity Coefficient)/(Anodic Electrolyte Molality*Anodic Activity Coefficient))

Temperature of Concentration Cell without Transference given Molalities

Go Temperature of Liquid = (EMF of Cell*([Faraday]/2*[R]))/(ln((Cathodic Electrolyte Molality*Cathodic Activity Coefficient)/(Anodic Electrolyte Molality*Anodic Activity Coefficient)))

Temperature of concentration cell without transference given concentration and fugacity

Go Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*[R]))/ln((Cathodic Concentration*Cathodic Fugacity)/(Anodic Concentration*Anodic Fugacity))

Temperature of Concentration Cell with Transference given Activities

Go Temperature of Liquid = ((EMF of Cell*[Faraday])/(Transport Number of Anion*[R]))/ln(Cathodic Ionic Activity/Anodic Ionic Activity)

Temperature of concentration cell without transference for dilute solution given concentration

Go Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*[R]))/(ln(Cathodic Concentration/Anodic Concentration))

Temperature of Concentration Cell without Transference given Activities

Go Temperature of Liquid = (EMF of Cell*([Faraday]/[R]))/(ln(Cathodic Ionic Activity/Anodic Ionic Activity))

Temperature given Tafel Slope

Go Temperature of Liquid = (Tafel Slope*Charge transfer coefficient*Elementary Charge)/(ln(10)*[BoltZ])

Temperature given Gibbs free entropy

Go Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy))

Temperature given Gibbs and Helmholtz free entropy

Go Temperature of Liquid = (Pressure*Volume)/(Helmholtz Free Entropy-Gibbs Free Entropy)

Temperature given internal energy and Helmholtz free entropy

Go Temperature of Liquid = Internal Energy/(Entropy-Helmholtz Free Entropy)

Temperature given Thermal Voltage and Electric Elementary Charge

Go Temperature of Liquid = (Thermal Voltage*Elementary Charge)/([BoltZ])

Temperature given Helmholtz free energy and Helmholtz free entropy

Go Temperature of Liquid = -(Helmholtz Free Energy of System/Helmholtz Free Entropy)

Temperature given Gibbs free energy and Gibbs free entropy

Go Temperature of Liquid = -(Gibbs Free Energy/Gibbs Free Entropy)

Temperature given Gibbs free entropy Formula

Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy))
T = ((U+(P*V_T))/(S-Ξ))

What is Debye–Hückel limiting law?

The chemists Peter Debye and Erich Hückel noticed that solutions that contain ionic solutes do not behave ideally even at very low concentrations. So, while the concentration of the solutes is fundamental to the calculation of the dynamics of a solution, they theorized that an extra factor that they termed gamma is necessary to the calculation of the activity coefficients of the solution. Hence they developed the Debye–Hückel equation and Debye–Hückel limiting law. The activity is only proportional to the concentration and is altered by a factor known as the activity coefficient . This factor takes into account the interaction energy of ions in solution.

How to Calculate Temperature given Gibbs free entropy?

Temperature given Gibbs free entropy calculator uses Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy)) to calculate the Temperature of Liquid, The Temperature given Gibbs free entropy formula is defined as the relation of temperature with internal energy and change in entropy at particular temperature, pressure, and volume. Temperature of Liquid is denoted by T symbol.

How to calculate Temperature given Gibbs free entropy using this online calculator? To use this online calculator for Temperature given Gibbs free entropy, enter Internal Energy (U), Pressure (P), Volume (V_T), Entropy (S) & Gibbs Free Entropy (Ξ) and hit the calculate button. Here is how the Temperature given Gibbs free entropy calculation can be explained with given input values -> 29.55172 = ((121+(800*0.063))/(16.8-11)).

FAQ

What is Temperature given Gibbs free entropy?

The Temperature given Gibbs free entropy formula is defined as the relation of temperature with internal energy and change in entropy at particular temperature, pressure, and volume and is represented as T = ((U+(P*V_T))/(S-Ξ)) or Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy)). The internal energy of a thermodynamic system is the energy contained within it. It is the energy necessary to create or prepare the system in any given internal state, Pressure is the force applied perpendicular to the surface of an object per unit area over which that force is distributed, Volume is the amount of space that a substance or object occupies or that is enclosed within a container, Entropy is the measure of a system’s thermal energy per unit temperature that is unavailable for doing useful work & The Gibbs free entropy is an entropic thermodynamic potential analogous to the free energy.

How to calculate Temperature given Gibbs free entropy?

The Temperature given Gibbs free entropy formula is defined as the relation of temperature with internal energy and change in entropy at particular temperature, pressure, and volume is calculated using Temperature of Liquid = ((Internal Energy+(Pressure*Volume))/(Entropy-Gibbs Free Entropy)). To calculate Temperature given Gibbs free entropy, you need Internal Energy (U), Pressure (P), Volume (V_T), Entropy (S) & Gibbs Free Entropy (Ξ). With our tool, you need to enter the respective value for Internal Energy, Pressure, Volume, Entropy & Gibbs Free Entropy and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

How many ways are there to calculate Temperature of Liquid?

In this formula, Temperature of Liquid uses Internal Energy, Pressure, Volume, Entropy & Gibbs Free Entropy. We can use 13 other way(s) to calculate the same, which is/are as follows -

Temperature of Liquid = Internal Energy/(Entropy-Helmholtz Free Entropy)
Temperature of Liquid = -(Helmholtz Free Energy of System/Helmholtz Free Entropy)
Temperature of Liquid = (Pressure*Volume)/(Helmholtz Free Entropy-Gibbs Free Entropy)
Temperature of Liquid = -(Gibbs Free Energy/Gibbs Free Entropy)
Temperature of Liquid = (Tafel Slope*Charge transfer coefficient*Elementary Charge)/(ln(10)*[BoltZ])
Temperature of Liquid = (Thermal Voltage*Elementary Charge)/([BoltZ])
Temperature of Liquid = (EMF of Cell*([Faraday]/[R]))/(ln(Cathodic Ionic Activity/Anodic Ionic Activity))
Temperature of Liquid = (EMF of Cell*([Faraday]/2*[R]))/(ln((Cathodic Electrolyte Molality*Cathodic Activity Coefficient)/(Anodic Electrolyte Molality*Anodic Activity Coefficient)))
Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*[R]))/ln((Cathodic Concentration*Cathodic Fugacity)/(Anodic Concentration*Anodic Fugacity))
Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*[R]))/(ln(Cathodic Concentration/Anodic Concentration))
Temperature of Liquid = ((EMF of Cell*[Faraday])/(2*Transport Number of Anion*[R]))/(ln(Cathodic Electrolyte Molality*Cathodic Activity Coefficient)/(Anodic Electrolyte Molality*Anodic Activity Coefficient))
Temperature of Liquid = ((EMF of Cell*[Faraday])/(Transport Number of Anion*[R]))/ln(Cathodic Ionic Activity/Anodic Ionic Activity)
Temperature of Liquid = ((EMF of Cell*Number of Positive and Negative Ions*Valencies of Positive and Negative Ions*[Faraday])/(Transport Number of Anion*Total number of Ions*[R]))/ln(Cathodic Ionic Activity/Anodic Ionic Activity)

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