Total Concentration of Solute in Organic Phase Calculator

✖The Distribution Ratio is the concentration of a component in two different phases of solvent.ⓘ Distribution Ratio [D]			+10% -10%
✖The Concentration in Aqueous Phase is the total concentration of solute dissolved in the solvent present in the aqueous phase.ⓘ Concentration in Aqueous Phase [C_aq]			+10% -10%

✖Concentration in Organic Solvent is the total concentration of solute dissolved in the solvent present in the organic phase.ⓘ Total Concentration of Solute in Organic Phase [C_orgP]

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Formula

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Total Concentration of Solute in Organic Phase

Formula

`"C"_{"orgP"} = ("D"*"C"_{"aq"})`

Example

`"24mol/L"=("0.6"*"40mol/L")`

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Total Concentration of Solute in Organic Phase Solution

STEP 0: Pre-Calculation Summary

Formula Used

Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase)
C_orgP = (D*C_aq)
This formula uses 3 Variables

Variables Used

Concentration in Organic Solvent - (Measured in Mole per Cubic Meter) - Concentration in Organic Solvent is the total concentration of solute dissolved in the solvent present in the organic phase.
Distribution Ratio - The Distribution Ratio is the concentration of a component in two different phases of solvent.
Concentration in Aqueous Phase - (Measured in Mole per Cubic Meter) - The Concentration in Aqueous Phase is the total concentration of solute dissolved in the solvent present in the aqueous phase.

STEP 1: Convert Input(s) to Base Unit

Distribution Ratio: 0.6 --> No Conversion Required
Concentration in Aqueous Phase: 40 Mole per Liter --> 40000 Mole per Cubic Meter (Check conversion here)

STEP 2: Evaluate Formula

Substituting Input Values in Formula

C_orgP = (D*C_aq) --> (0.6*40000)

Evaluating ... ...

C_orgP = 24000

STEP 3: Convert Result to Output's Unit

24000 Mole per Cubic Meter -->24 Mole per Liter (Check conversion here)

FINAL ANSWER

24 Mole per Liter <-- Concentration in Organic Solvent

(Calculation completed in 00.004 seconds)

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Created by Prashant Singh

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

Prashant Singh has created this Calculator and 700+ more calculators!

Verified by Akshada Kulkarni

National Institute of Information Technology (NIIT), Neemrana

Akshada Kulkarni has verified this Calculator and 900+ more calculators!

< 6 Phase Calculators

Molar Concentration of Third Component in Second Phase

Go Concentration of Solute in Phase2 = (Concentration of Solute in Solvent 1/Distribution Coefficient of Solution)

Molar Concentration of Third Component in First Phase

Go Concentration of Solute in Phase1 = (Distribution Coefficient of Solution*Solute Concentration in Solvent2)

Mobile Phase Travel Time through Column

Go Unretained Solute Travel Time through Column = (Retention Time-Adjusted Retention Time)

Total Concentration of Solute in Organic Phase

Go Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase)

Total Concentration of Solute in Aqueous Phase

Go Concentration in Aqueous Solvent = (Concentration in Organic Phase/Distribution Ratio)

Mobile Phase Travel Time given Capacity Factor

Go Unretained Solute Travel Time given CP = (Retention Time)/(Capacity Factor+1)

< 13 Relative and Adjusted Retention and Phase Calculators

Molar Concentration of Third Component in Second Phase

Go Concentration of Solute in Phase2 = (Concentration of Solute in Solvent 1/Distribution Coefficient of Solution)

Molar Concentration of Third Component in First Phase

Go Concentration of Solute in Phase1 = (Distribution Coefficient of Solution*Solute Concentration in Solvent2)

Relative Retention given Adjusted Retention Times

Go Actual Relative Retention = (Adjusted Retention Time of Solute 2/Adjusted Retention Time of Solute 1)

Relative Retention given Partition Coefficient of Two Components

Go Actual Relative Retention = (Partition Coefficient of Solute 2/Partition Coefficient of Solute 1)

Adjusted Retention of Second Component given Relative Retention

Go Adjusted Retention Time of Comp 2 = (Relative Retention*Adjusted Retention Time of Solute 1)

Adjusted Retention of First Component given Relative Retention

Go Adjusted Retention Time of Comp 1 = (Adjusted Retention Time of Solute 2/Relative Retention)

Partition Coefficient of Solute 1 given Relative Retention

Go Partition Coefficient of Comp 1 = (Partition Coefficient of Solute 2/Relative Retention)

Partition Coefficient of Solute 2 given Relative Retention

Go Partition Coefficient of Comp 2 = (Relative Retention*Partition Coefficient of Solute 1)

Mobile Phase Travel Time through Column

Go Unretained Solute Travel Time through Column = (Retention Time-Adjusted Retention Time)

Total Concentration of Solute in Aqueous Phase

Go Concentration in Aqueous Solvent = (Concentration in Organic Phase/Distribution Ratio)

Total Concentration of Solute in Organic Phase

Go Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase)

Relative Retention given Capacity Factor of Two Components

Go Actual Relative Retention = (Capacity Factor of Solute 2/Capacity Factor of Solute 1)

Mobile Phase Travel Time given Capacity Factor

Go Unretained Solute Travel Time given CP = (Retention Time)/(Capacity Factor+1)

Total Concentration of Solute in Organic Phase Formula

Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase)
C_orgP = (D*C_aq)

What is Nernst distribution law?

The law that determines the relative distribution of a component that is soluble in two liquids, these liquids being immiscible or miscible to a limited extent. This law is one of the laws applying to ideal dilute solutions. It was discovered by W. Nernst in 1890. The Nernst distribution law states that, at equilibrium, the ratio of the concentrations of a third component in two liquid phases is constant. The Nernst distribution law permits us to determine the most favorable conditions for the extraction of substances from solutions.

How to Calculate Total Concentration of Solute in Organic Phase?

Total Concentration of Solute in Organic Phase calculator uses Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase) to calculate the Concentration in Organic Solvent, The Total concentration of solute in organic phase formula is defined as the product of the distribution ratio and the total concentration of solute in the aqueous phase solvent. Concentration in Organic Solvent is denoted by C_orgP symbol.

How to calculate Total Concentration of Solute in Organic Phase using this online calculator? To use this online calculator for Total Concentration of Solute in Organic Phase, enter Distribution Ratio (D) & Concentration in Aqueous Phase (C_aq) and hit the calculate button. Here is how the Total Concentration of Solute in Organic Phase calculation can be explained with given input values -> 0.024 = (0.6*40000).

FAQ

What is Total Concentration of Solute in Organic Phase?

The Total concentration of solute in organic phase formula is defined as the product of the distribution ratio and the total concentration of solute in the aqueous phase solvent and is represented as C_orgP = (D*C_aq) or Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase). The Distribution Ratio is the concentration of a component in two different phases of solvent & The Concentration in Aqueous Phase is the total concentration of solute dissolved in the solvent present in the aqueous phase.

How to calculate Total Concentration of Solute in Organic Phase?

The Total concentration of solute in organic phase formula is defined as the product of the distribution ratio and the total concentration of solute in the aqueous phase solvent is calculated using Concentration in Organic Solvent = (Distribution Ratio*Concentration in Aqueous Phase). To calculate Total Concentration of Solute in Organic Phase, you need Distribution Ratio (D) & Concentration in Aqueous Phase (C_aq). With our tool, you need to enter the respective value for Distribution Ratio & Concentration in Aqueous Phase 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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