Fluorosence Intensity at Low Concentration of Solute Calculator

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✖Fluorosecence Quantum Yield is a measure of the efficiency of photon emission as defined by the ratio of the number of photons emitted to the number of photons absorbed.ⓘ Fluorosecence Quantum Yield [φ_f]			+10% -10%
✖Initial Intensity flux of radiant energy is the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy.ⓘ Initial Intensity [Io]			+10% -10%
✖Spectroscopical Molar Extinction Coefficient a measure of how strongly a chemical species or substance absorbs light at a particular wavelength.ⓘ Spectroscopical Molar Extinction Coefficient [ξ]			+10% -10%
✖The Concentration at Time t is the amount of species formed or reacted in that particular time.ⓘ Concentration at Time t [C_t]			+10% -10%
✖Length is the measurement or extent of something from end to end.ⓘ Length [L]			+10% -10%

✖Fluorosence Intensity formula is defined as the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy.ⓘ Fluorosence Intensity at Low Concentration of Solute [I_F]

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Fluorosence Intensity at Low Concentration of Solute

Formula

`"I"_{"F"} = "φ"_{"f"}*"Io"*2.303*"ξ"*"C"_{"t"}*"L"`

Example

`"3.3E^11W/m²"="3"*"200W/m²"*2.303*"100000m²/mol"*"0.8mol/L"*"3m"`

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Fluorosence Intensity at Low Concentration of Solute Solution

STEP 0: Pre-Calculation Summary

Formula Used

Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length
I_F = φ_f*Io*2.303*ξ*C_t*L
This formula uses 6 Variables

Variables Used

Fluorosence Intensity - (Measured in Watt per Square Meter) - Fluorosence Intensity formula is defined as the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy.
Fluorosecence Quantum Yield - Fluorosecence Quantum Yield is a measure of the efficiency of photon emission as defined by the ratio of the number of photons emitted to the number of photons absorbed.
Initial Intensity - (Measured in Watt per Square Meter) - Initial Intensity flux of radiant energy is the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy.
Spectroscopical Molar Extinction Coefficient - (Measured in Square Meter per Mole) - Spectroscopical Molar Extinction Coefficient a measure of how strongly a chemical species or substance absorbs light at a particular wavelength.
Concentration at Time t - (Measured in Mole per Cubic Meter) - The Concentration at Time t is the amount of species formed or reacted in that particular time.
Length - (Measured in Meter) - Length is the measurement or extent of something from end to end.

STEP 1: Convert Input(s) to Base Unit

Fluorosecence Quantum Yield: 3 --> No Conversion Required
Initial Intensity: 200 Watt per Square Meter --> 200 Watt per Square Meter No Conversion Required
Spectroscopical Molar Extinction Coefficient: 100000 Square Meter per Mole --> 100000 Square Meter per Mole No Conversion Required
Concentration at Time t: 0.8 Mole per Liter --> 800 Mole per Cubic Meter (Check conversion here)
Length: 3 Meter --> 3 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

I_F = φ_f*Io*2.303*ξ*C_t*L --> 3*200*2.303*100000*800*3

Evaluating ... ...

I_F = 331632000000

STEP 3: Convert Result to Output's Unit

331632000000 Watt per Square Meter --> No Conversion Required

FINAL ANSWER

331632000000 Watt per Square Meter <-- Fluorosence Intensity

(Calculation completed in 00.000 seconds)

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< 24 Physical spectroscopy Calculators

Singlet State Concentration

Go Singlet State Concentration = Absorption Intensity/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction+Rate Constant of Intersystem Crossing+Rate Constant of Internal Conversion)

Phosphorescence Quantum Yield given Intersystem Quantum Yield

Go Phosphosecence Quantum Yield = (Phosphorescence Rate Constant/Absorption Intensity)*(((Absorption Intensity*Triplet State Quantum Yield)/Rate Constant of Triplet Triplet Anhilation)^(1/2))

Phosphorescence Quantum Yield given Fluoroscence Quantum Yield

Go Phosphosecence Quantum Yield = Fluorosecence Quantum Yield*((Phosphorescence Rate Constant*Concentration of Triplet State)/(Rate Constant of Fluoroscence*Singlet State Concentration))

Fluoroscence Quantum Yield given Phosphorescence Quantum Yield

Go Fluorosecence Quantum Yield = Phosphosecence Quantum Yield*((Rate Constant of Fluoroscence*Singlet State Concentration)/(Phosphorescence Rate Constant*Concentration of Triplet State))

Fluorescence Quantum Yield

Go Fluorosecence Quantum Yield = Rate of Radiative Reaction/(Rate of Radiative Reaction+Rate of Internal Conversion+Rate Constant of Intersystem Crossing+Quenching Constant)

Fluorosence Intensity at Low Concentration of Solute

Go Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length

Quantum Yield of Fluorescence

Go Fluorosecence Quantum Yield = Rate Constant of Fluoroscence/(Rate Constant of Fluoroscence+Rate of Internal Conversion+Rate Constant of Intersystem Crossing)

Fluoroscence Intensity without Quenching

Go Intensity Without Quenching = (Rate Constant of Fluoroscence*Absorption Intensity)/(Rate Constant of Non Radiative Reaction+Rate Constant of Fluoroscence)

Intensity Ratio

Go Intensity Ratio = 1+(Quencher Concentration*(Quenching Constant/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)))

Singlet Life Time

Go Singlet Life time = 1/(Rate Constant of Intersystem Crossing+Rate of Radiative Reaction+Rate of Internal Conversion+Quenching Constant)

Final Intensity using Stern Volmer Equation

Go Final Intensity = Initial Intensity/ (1+(Singlet Life time*Quenching Constant*Quencher Concentration))

Phosphorescence Quantum Yield

Go Phosphosecence Quantum Yield = Rate of Radiative Reaction/(Rate of Radiative Reaction+Rate Constant of Non Radiative Reaction)

Rate of Deactivation

Go Rate of Deactivation = (Rate Constant of Non Radiative Reaction+Rate Constant of Fluoroscence)*Singlet State Concentration

Triplet State Quantum yield

Go Triplet State Quantum Yield = (Rate Constant of Intersystem Crossing*Singlet State Concentration)/Absorption Intensity

Collisional Energy Transfer

Go Rate of Collisional Energy Transfer = Quenching Constant*Quencher Concentration*Singlet State Concentration

ISC Rate Constant

Go Rate Constant of Intersystem Crossing = Rate of Intersystem Crossing*Singlet State Concentration

Rate of ISC

Go Rate of Intersystem Crossing = Rate Constant of Intersystem Crossing*Singlet State Concentration

Phosphorescence Rate Constant

Go Phosphorescence Rate Constant = Rate of Phosphorescence/Concentration of Triplet State

Rate of Phosphorescence

Go Rate of Phosphorescence = Phosphorescence Rate Constant*Concentration of Triplet State

Fluorescence Rate Constant

Go Rate Constant of Fluoroscence = Rate of Fluoroscence/Singlet State Concentration

Rate of Activation

Go Rate of Activation = Equilibrium Constant*(1-Degree of Dissociation of Emission)

Difference in Acidity between Ground and Excited State

Go Difference in pka = pKa of Excited State-pKa of Ground State

Singlet Radiative Fluorescence Lifetime

Go Singlet Life time = 1/Rate Constant of Fluoroscence

Singlet Radiative Phosphorescence Lifetime

Go Singlet Life time = 1/Rate of Phosphorescence

Fluorosence Intensity at Low Concentration of Solute Formula

Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length
I_F = φ_f*Io*2.303*ξ*C_t*L

What is the molar extinction coefficient in Beer's law?

Molar extinction coefficient is a measure of how strongly a substance absorbs light at a particular wavelength, and is usually represented by the unit M-1 cm-1 or L mol-1 cm-1.

What is the Franck Condon factor?

According to the Franck–Condon principle, the intensity of a vibrational peak in an electronically allowed transition is proportional to the absolute square of the overlap integral of the vibrational wave functions of the initial and final states. This overlap integral is known as the Franck–Condon factor.

How to Calculate Fluorosence Intensity at Low Concentration of Solute?

Fluorosence Intensity at Low Concentration of Solute calculator uses Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length to calculate the Fluorosence Intensity, The Fluorosence Intensity at Low Concentration of Solute formula is defined as the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy. Fluorosence Intensity is denoted by I_F symbol.

How to calculate Fluorosence Intensity at Low Concentration of Solute using this online calculator? To use this online calculator for Fluorosence Intensity at Low Concentration of Solute, enter Fluorosecence Quantum Yield (φ_f), Initial Intensity (Io), Spectroscopical Molar Extinction Coefficient (ξ), Concentration at Time t (C_t) & Length (L) and hit the calculate button. Here is how the Fluorosence Intensity at Low Concentration of Solute calculation can be explained with given input values -> 3.3E+11 = 3*200*2.303*100000*800*3.

FAQ

What is Fluorosence Intensity at Low Concentration of Solute?

The Fluorosence Intensity at Low Concentration of Solute formula is defined as the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy and is represented as I_F = φ_f*Io*2.303*ξ*C_t*L or Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length. Fluorosecence Quantum Yield is a measure of the efficiency of photon emission as defined by the ratio of the number of photons emitted to the number of photons absorbed, Initial Intensity flux of radiant energy is the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy, Spectroscopical Molar Extinction Coefficient a measure of how strongly a chemical species or substance absorbs light at a particular wavelength, The Concentration at Time t is the amount of species formed or reacted in that particular time & Length is the measurement or extent of something from end to end.

How to calculate Fluorosence Intensity at Low Concentration of Solute?

The Fluorosence Intensity at Low Concentration of Solute formula is defined as the power transferred per unit area, where the area is measured on the plane perpendicular to the direction of propagation of the energy is calculated using Fluorosence Intensity = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length. To calculate Fluorosence Intensity at Low Concentration of Solute, you need Fluorosecence Quantum Yield (φ_f), Initial Intensity (Io), Spectroscopical Molar Extinction Coefficient (ξ), Concentration at Time t (C_t) & Length (L). With our tool, you need to enter the respective value for Fluorosecence Quantum Yield, Initial Intensity, Spectroscopical Molar Extinction Coefficient, Concentration at Time t & Length 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 Fluorosence Intensity?

In this formula, Fluorosence Intensity uses Fluorosecence Quantum Yield, Initial Intensity, Spectroscopical Molar Extinction Coefficient, Concentration at Time t & Length. We can use 1 other way(s) to calculate the same, which is/are as follows -

Fluorosence Intensity = (Rate Constant of Fluoroscence*Absorption Intensity)/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)

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