Time taken when Initial Concentration of Reactant B greater than 0 Solution

STEP 0: Pre-Calculation Summary
Formula Used
Time = 1/Forward Reaction Rate Constant*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))*((Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium)/(Initial Concentration of Reactant A+Initial Concentration of Reactant B))
t = 1/kf*ln(xeq/(xeq-x))*((B0+xeq)/(A0+B0))
This formula uses 1 Functions, 6 Variables
Functions Used
ln - The natural logarithm, also known as the logarithm to the base e, is the inverse function of the natural exponential function., ln(Number)
Variables Used
Time - (Measured in Second) - Time is used to defined as the period of time that is required for the reactant to given a certain amount of product in a chemical reaction.
Forward Reaction Rate Constant - (Measured in 1 Per Second) - Forward Reaction Rate Constant is used to define the relationship between the molar concentration of the reactants and the rate of the chemical reaction in forward direction.
Concentration of Reactant at Equilibrium - (Measured in Mole per Cubic Meter) - Concentration of Reactant at Equilibrium is defined as the amount of reactant present when the reaction is at equilibrium condition.
Concentration of Product at Time t - (Measured in Mole per Cubic Meter) - Concentration of Product at Time t is defined as the amount of reactant that has been converted into product in a time interval of t.
Initial Concentration of Reactant B - (Measured in Mole per Cubic Meter) - Initial Concentration of Reactant B is defined as the initial concentration of the reactant B at time t=0.
Initial Concentration of Reactant A - (Measured in Mole per Cubic Meter) - Initial Concentration of Reactant A is defined as the concentration of the reactant A at time t=0.
STEP 1: Convert Input(s) to Base Unit
Forward Reaction Rate Constant: 9.74E-05 1 Per Second --> 9.74E-05 1 Per Second No Conversion Required
Concentration of Reactant at Equilibrium: 70 Mole per Liter --> 70000 Mole per Cubic Meter (Check conversion ​here)
Concentration of Product at Time t: 27.5 Mole per Liter --> 27500 Mole per Cubic Meter (Check conversion ​here)
Initial Concentration of Reactant B: 80 Mole per Liter --> 80000 Mole per Cubic Meter (Check conversion ​here)
Initial Concentration of Reactant A: 100 Mole per Liter --> 100000 Mole per Cubic Meter (Check conversion ​here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
t = 1/kf*ln(xeq/(xeq-x))*((B0+xeq)/(A0+B0)) --> 1/9.74E-05*ln(70000/(70000-27500))*((80000+70000)/(100000+80000))
Evaluating ... ...
t = 4269.26049040886
STEP 3: Convert Result to Output's Unit
4269.26049040886 Second --> No Conversion Required
FINAL ANSWER
4269.26049040886 4269.26 Second <-- Time
(Calculation completed in 00.004 seconds)

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First Order Opposed by First Order Reactions Calculators

Backward Reaction Rate Constant of First Order Opposed by First Order Reaction
​ LaTeX ​ Go Backward Reaction Rate Constant = (ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))/Time taken for Backward Reaction)-Forward Reaction Rate Constant
Forward Reaction Rate Constant of First Order Opposed by First Order Reaction
​ LaTeX ​ Go Forward Reaction Rate Constant = (ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))/Time)-Backward Reaction Rate Constant
Time taken for 1st Order Opposed by 1st Order Reaction
​ LaTeX ​ Go Time = ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))/(Forward Reaction Rate Constant+Backward Reaction Rate Constant)
Product Concentration of 1st Order Opposed by 1st Order Reaction at given Time t
​ LaTeX ​ Go Concentration of Product at Time t = Concentration of Reactant at Equilibrium*(1-exp(-(Forward Reaction Rate Constant+Backward Reaction Rate Constant)*Time))

Important Formulas on Reversible Reaction Calculators

Reactant Concentration at given Time t
​ LaTeX ​ Go Concentration of A at Time t = Initial Concentration of Reactant A*(Forward Reaction Rate Constant/(Forward Reaction Rate Constant+Backward Reaction Rate Constant))*((Backward Reaction Rate Constant/Forward Reaction Rate Constant)+exp(-(Forward Reaction Rate Constant+Backward Reaction Rate Constant)*Time))
Product Conc for 1st Order Opposed by 1st Order Rxn given Initial Conc of B greater than 0
​ LaTeX ​ Go Concentration of Product at Time t = Concentration of Reactant at Equilibrium*(1-exp(-Forward Reaction Rate Constant*((Initial Concentration of Reactant A+Initial Concentration of Reactant B)/(Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium))*Time))
Product Conc of First Order Opposed by First Order Reaction given Initial Conc of Reactant
​ LaTeX ​ Go Concentration of Product at Time t = Concentration of Reactant at Equilibrium*(1-exp(-Forward Reaction Rate Constant*Time*(Initial Concentration of Reactant A/Concentration of Reactant at Equilibrium)))
Product Concentration of 1st Order Opposed by 1st Order Reaction at given Time t
​ LaTeX ​ Go Concentration of Product at Time t = Concentration of Reactant at Equilibrium*(1-exp(-(Forward Reaction Rate Constant+Backward Reaction Rate Constant)*Time))

Time taken when Initial Concentration of Reactant B greater than 0 Formula

​LaTeX ​Go
Time = 1/Forward Reaction Rate Constant*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))*((Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium)/(Initial Concentration of Reactant A+Initial Concentration of Reactant B))
t = 1/kf*ln(xeq/(xeq-x))*((B0+xeq)/(A0+B0))

What is an Opposing Reaction?

Opposing reactions or reversible reactions are those in which both forward and backward reaction takes place simultaneously. To start with, the rate of forward reaction is very large and it decreases as reactant concentration decreases with time. Similarly, initially the rate of backward reaction is slow and it increases as product concentration increases with time.
The state at which the rate of forward reaction equals the rate of backward reaction is called the equilibrium state. Thus, equilibrium is a dynamic equilibrium where all the participants of a reaction are being formed as fast as they are being destroyed and hence no further change in the various concentrations is observed.

What are the classifications of Opposing Reactions?

A reversible reaction may be classified on the basis of orders of elementary forward and backward reactions. We describe below a few reversible reactions classified accordingly:
1. First Order Opposed by First Order Reaction
2. First Order Opposed by Second Order Reaction
3. Second Order Opposed by First Order Reaction
4. Second Order Opposed by Second Order Reaction.

How to Calculate Time taken when Initial Concentration of Reactant B greater than 0?

Time taken when Initial Concentration of Reactant B greater than 0 calculator uses Time = 1/Forward Reaction Rate Constant*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))*((Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium)/(Initial Concentration of Reactant A+Initial Concentration of Reactant B)) to calculate the Time, The Time taken when Initial Concentration of Reactant B greater than 0 formula is defined as the time interval required to convert a particular concentration substance (A) to a certain concentration of another substance (B) in a First Order Opposed by First Order Reaction. Time is denoted by t symbol.

How to calculate Time taken when Initial Concentration of Reactant B greater than 0 using this online calculator? To use this online calculator for Time taken when Initial Concentration of Reactant B greater than 0, enter Forward Reaction Rate Constant (kf), Concentration of Reactant at Equilibrium (xeq), Concentration of Product at Time t (x), Initial Concentration of Reactant B (B0) & Initial Concentration of Reactant A (A0) and hit the calculate button. Here is how the Time taken when Initial Concentration of Reactant B greater than 0 calculation can be explained with given input values -> 2878.784 = 1/9.74E-05*ln(70000/(70000-27500))*((80000+70000)/(100000+80000)).

FAQ

What is Time taken when Initial Concentration of Reactant B greater than 0?
The Time taken when Initial Concentration of Reactant B greater than 0 formula is defined as the time interval required to convert a particular concentration substance (A) to a certain concentration of another substance (B) in a First Order Opposed by First Order Reaction and is represented as t = 1/kf*ln(xeq/(xeq-x))*((B0+xeq)/(A0+B0)) or Time = 1/Forward Reaction Rate Constant*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))*((Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium)/(Initial Concentration of Reactant A+Initial Concentration of Reactant B)). Forward Reaction Rate Constant is used to define the relationship between the molar concentration of the reactants and the rate of the chemical reaction in forward direction, Concentration of Reactant at Equilibrium is defined as the amount of reactant present when the reaction is at equilibrium condition, Concentration of Product at Time t is defined as the amount of reactant that has been converted into product in a time interval of t, Initial Concentration of Reactant B is defined as the initial concentration of the reactant B at time t=0 & Initial Concentration of Reactant A is defined as the concentration of the reactant A at time t=0.
How to calculate Time taken when Initial Concentration of Reactant B greater than 0?
The Time taken when Initial Concentration of Reactant B greater than 0 formula is defined as the time interval required to convert a particular concentration substance (A) to a certain concentration of another substance (B) in a First Order Opposed by First Order Reaction is calculated using Time = 1/Forward Reaction Rate Constant*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))*((Initial Concentration of Reactant B+Concentration of Reactant at Equilibrium)/(Initial Concentration of Reactant A+Initial Concentration of Reactant B)). To calculate Time taken when Initial Concentration of Reactant B greater than 0, you need Forward Reaction Rate Constant (kf), Concentration of Reactant at Equilibrium (xeq), Concentration of Product at Time t (x), Initial Concentration of Reactant B (B0) & Initial Concentration of Reactant A (A0). With our tool, you need to enter the respective value for Forward Reaction Rate Constant, Concentration of Reactant at Equilibrium, Concentration of Product at Time t, Initial Concentration of Reactant B & Initial Concentration of Reactant A 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 Time?
In this formula, Time uses Forward Reaction Rate Constant, Concentration of Reactant at Equilibrium, Concentration of Product at Time t, Initial Concentration of Reactant B & Initial Concentration of Reactant A. We can use 3 other way(s) to calculate the same, which is/are as follows -
  • Time = ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))/(Forward Reaction Rate Constant+Backward Reaction Rate Constant)
  • Time = (1/Forward Reaction Rate Constant)*(Concentration of Reactant at Equilibrium/Initial Concentration of Reactant A)*ln(Concentration of Reactant at Equilibrium/(Concentration of Reactant at Equilibrium-Concentration of Product at Time t))
  • Time = (1/(Forward Reaction Rate Constant+Backward Reaction Rate Constant))*ln(Initial Concentration of Reactant A*Forward Reaction Rate Constant/(Forward Reaction Rate Constant*(Initial Concentration of Reactant A-Concentration of B)-Backward Reaction Rate Constant*Concentration of B))
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