Molar Concentration of Substance C Solution

STEP 0: Pre-Calculation Summary
Formula Used
Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C)
CC = ((Q*(CA^a)*(CB^b))/(CD^d))^(1/c)
This formula uses 9 Variables
Variables Used
Concentration of C - (Measured in Mole per Cubic Meter) - Concentration of C is the molar concentration of reactant substance C at any stage during the progress of the reaction.
Reaction Quotient - The reaction quotient (Q) measures the relative amounts of products and reactants present during a reaction at a particular point in time.
Concentration of A - (Measured in Mole per Cubic Meter) - Concentration of A is the molar concentration of reactant substance A at any stage during the progress of the reaction.
Number of Moles of A - Number of Moles of A is the no. of moles of reactant A present in the equilibrium mixture.
Concentration of B - (Measured in Mole per Cubic Meter) - Concentration of B is the molar concentration of reactant substance B at any stage during the progress of the reaction.
No. of Moles of B - No. of Moles of B is the no. of moles of reactant B present in the equilibrium mixture.
Concentration of D - (Measured in Mole per Cubic Meter) - Concentration of D is the molar concentration of reactant substance D at any stage during the progress of the reaction.
No. of Moles of D - No. of Moles of D is the no. of moles of product D present in the equilibrium mixture.
No. of Moles of C - No. of Moles of C is the no. of moles of product C present in the equilibrium mixture.
STEP 1: Convert Input(s) to Base Unit
Reaction Quotient: 50 --> No Conversion Required
Concentration of A: 1.62 Mole per Liter --> 1620 Mole per Cubic Meter (Check conversion here)
Number of Moles of A: 17 --> No Conversion Required
Concentration of B: 14 Mole per Liter --> 14000 Mole per Cubic Meter (Check conversion here)
No. of Moles of B: 3 --> No Conversion Required
Concentration of D: 22 Mole per Liter --> 22000 Mole per Cubic Meter (Check conversion here)
No. of Moles of D: 7 --> No Conversion Required
No. of Moles of C: 9 --> No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
CC = ((Q*(CA^a)*(CB^b))/(CD^d))^(1/c) --> ((50*(1620^17)*(14000^3))/(22000^7))^(1/9)
Evaluating ... ...
CC = 18021.6483131758
STEP 3: Convert Result to Output's Unit
18021.6483131758 Mole per Cubic Meter -->18.0216483131758 Mole per Liter (Check conversion here)
FINAL ANSWER
18.0216483131758 18.02165 Mole per Liter <-- Concentration of C
(Calculation completed in 00.004 seconds)

Credits

Created by Akshada Kulkarni
National Institute of Information Technology (NIIT), Neemrana
Akshada Kulkarni has created this Calculator and 500+ more calculators!
Verified by Prerana Bakli
University of Hawaiʻi at Mānoa (UH Manoa), Hawaii, USA
Prerana Bakli has verified this Calculator and 1600+ more calculators!

21 Properties of Equilibrium Constant Calculators

Equilibrium Constant with respect to Partial Pressure
Go Equilibrium Constant for Partial Pressure = ((Equilibrium Partial Pressure C^No. of Moles of C)*(Equilibrium Partial Pressure D^No. of Moles of D) )/((Equilibrium Partial Pressure A^Number of Moles of A) *(Equilibrium Partial Pressure B^No. of Moles of B))
Equilibrium Partial Pressure of Substance A
Go Equilibrium Partial Pressure A = (((Equilibrium Partial Pressure C^No. of Moles of C)*(Equilibrium Partial Pressure D^No. of Moles of D))/(Equilibrium Constant for Partial Pressure*(Equilibrium Partial Pressure B^No. of Moles of B)))^(1/Number of Moles of A)
Equilibrium Partial Pressure of Substance B
Go Equilibrium Partial Pressure B = (((Equilibrium Partial Pressure C^No. of Moles of C)*(Equilibrium Partial Pressure D^No. of Moles of D))/(Equilibrium Constant for Partial Pressure*(Equilibrium Partial Pressure A^Number of Moles of A)))^(1/No. of Moles of B)
Equilibrium Partial Pressure of Substance C
Go Equilibrium Partial Pressure C = ((Equilibrium Constant for Partial Pressure*(Equilibrium Partial Pressure A^Number of Moles of A)*(Equilibrium Partial Pressure B^No. of Moles of B))/(Equilibrium Partial Pressure D^No. of Moles of D))^(1/No. of Moles of C)
Equilibrium Partial Pressure of Substance D
Go Equilibrium Partial Pressure D = ((Equilibrium Constant for Partial Pressure*(Equilibrium Partial Pressure A^Number of Moles of A)*(Equilibrium Partial Pressure B^No. of Moles of B))/(Equilibrium Partial Pressure C^No. of Moles of C))^(1/No. of Moles of D)
Equilibrium Mole Fraction of Substance A
Go Equilibrium Mole Fraction A = (((Equilibrium Mole Fraction C^No. of Moles of C) *(Equilibrium Mole Fraction D^No. of Moles of D) )/(Equilibrium Constant for Mole Fraction*(Equilibrium Mole Fraction B^No. of Moles of B)))^(1/Number of Moles of A)
Equilibrium Mole Fraction of Substance B
Go Equilibrium Mole Fraction B = (((Equilibrium Mole Fraction C^No. of Moles of C) *(Equilibrium Mole Fraction D^No. of Moles of D) )/(Equilibrium Constant for Mole Fraction*(Equilibrium Mole Fraction A^Number of Moles of A)))^(1/No. of Moles of B)
Equilibrium Constant with respect to Mole Fraction
Go Equilibrium Constant for Mole Fraction = ((Equilibrium Mole Fraction C^No. of Moles of C) *(Equilibrium Mole Fraction D^No. of Moles of D))/((Equilibrium Mole Fraction A^Number of Moles of A) *(Equilibrium Mole Fraction B^No. of Moles of B))
Equilibrium Mole Fraction of Substance C
Go Equilibrium Mole Fraction C = ((Equilibrium Constant for Mole Fraction*(Equilibrium Mole Fraction A^Number of Moles of A) *(Equilibrium Mole Fraction B^No. of Moles of B) )/(Equilibrium Mole Fraction D^No. of Moles of D))^(1/No. of Moles of C)
Equilibrium Mole Fraction of Substance D
Go Equilibrium Mole Fraction D = ((Equilibrium Constant for Mole Fraction*(Equilibrium Mole Fraction A^Number of Moles of A) *(Equilibrium Mole Fraction B^No. of Moles of B))/(Equilibrium Mole Fraction C^No. of Moles of C))^(1/No. of Moles of D)
Equilibrium Constant for Reverse Reaction
Go Reverse Equilibrium Constant = ((Equilibrium Concentration of A^Number of Moles of A)*(Equilibrium Concentration of B^No. of Moles of B))/((Equilibrium Concentration of C^No. of Moles of C)*(Equilibrium Concentration of D^No. of Moles of D))
Molar Concentration of Substance A
Go Concentration of A = (((Concentration of C^No. of Moles of C)*(Concentration of D^No. of Moles of D))/(Reaction Quotient*(Concentration of B^No. of Moles of B)))^(1/Number of Moles of A)
Molar Concentration of Substance B
Go Concentration of B = (((Concentration of C^No. of Moles of C)*(Concentration of D^No. of Moles of D))/(Reaction Quotient*(Concentration of A^Number of Moles of A)))^(1/No. of Moles of B)
Molar Concentration of Substance C
Go Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C)
Molar Concentration of Substance D
Go Concentration of D = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of C^No. of Moles of C))^(1/No. of Moles of D)
Reaction Quotient
Go Reaction Quotient = ((Concentration of C^No. of Moles of C)*(Concentration of D^No. of Moles of D))/((Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))
Equilibrium Constant for Reversed Reaction when Multiplied with Integer
Go Equilibrium Constant Multiplied = 1/(Equilibrium Constant^Number)
Equilibrium Constant for Reaction when Multiplied with Integer
Go Equilibrium Constant Multiplied = (Equilibrium Constant^Number)
Weight of Reactant given Active Mass
Go Weight of Solute = Active mass*Molecular Weight
Active Mass
Go Active mass = Weight of Solute/Molecular Weight
Equilibrium Constant for Reverse Reaction given Constant for Forward Reaction
Go Reverse Equilibrium Constant = 1/Equilibrium Constant

Molar Concentration of Substance C Formula

Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C)
CC = ((Q*(CA^a)*(CB^b))/(CD^d))^(1/c)

What is Reaction Quotient?

Reaction quotient is the ratio product of molar concentrations of products to the product of molar concentrations of reactants with each concentration term raised to a power equal to its stoichiometric coefficient at any stage during the progress of the reaction.
The main difference between K and Q is that K describes a reaction that is at equilibrium, whereas Q describes a reaction that is not at equilibrium. To determine Q , the concentrations of the reactants and products must be known. For a given general chemical equation:
aA+bB⇌cC+dD

How to Calculate Molar Concentration of Substance C?

Molar Concentration of Substance C calculator uses Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C) to calculate the Concentration of C, The Molar concentration of substance C formula is defined as the concentration of substance C at any stage during the progress of the chemical reaction. Concentration of C is denoted by CC symbol.

How to calculate Molar Concentration of Substance C using this online calculator? To use this online calculator for Molar Concentration of Substance C, enter Reaction Quotient (Q), Concentration of A (CA), Number of Moles of A (a), Concentration of B (CB), No. of Moles of B (b), Concentration of D (CD), No. of Moles of D (d) & No. of Moles of C (c) and hit the calculate button. Here is how the Molar Concentration of Substance C calculation can be explained with given input values -> 0.791585 = ((50*(1620^17)*(14000^3))/(22000^7))^(1/9).

FAQ

What is Molar Concentration of Substance C?
The Molar concentration of substance C formula is defined as the concentration of substance C at any stage during the progress of the chemical reaction and is represented as CC = ((Q*(CA^a)*(CB^b))/(CD^d))^(1/c) or Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C). The reaction quotient (Q) measures the relative amounts of products and reactants present during a reaction at a particular point in time, Concentration of A is the molar concentration of reactant substance A at any stage during the progress of the reaction, Number of Moles of A is the no. of moles of reactant A present in the equilibrium mixture, Concentration of B is the molar concentration of reactant substance B at any stage during the progress of the reaction, No. of Moles of B is the no. of moles of reactant B present in the equilibrium mixture, Concentration of D is the molar concentration of reactant substance D at any stage during the progress of the reaction, No. of Moles of D is the no. of moles of product D present in the equilibrium mixture & No. of Moles of C is the no. of moles of product C present in the equilibrium mixture.
How to calculate Molar Concentration of Substance C?
The Molar concentration of substance C formula is defined as the concentration of substance C at any stage during the progress of the chemical reaction is calculated using Concentration of C = ((Reaction Quotient*(Concentration of A^Number of Moles of A)*(Concentration of B^No. of Moles of B))/(Concentration of D^No. of Moles of D))^(1/No. of Moles of C). To calculate Molar Concentration of Substance C, you need Reaction Quotient (Q), Concentration of A (CA), Number of Moles of A (a), Concentration of B (CB), No. of Moles of B (b), Concentration of D (CD), No. of Moles of D (d) & No. of Moles of C (c). With our tool, you need to enter the respective value for Reaction Quotient, Concentration of A, Number of Moles of A, Concentration of B, No. of Moles of B, Concentration of D, No. of Moles of D & No. of Moles of C and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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