Singlet Radiative Phosphorescence Lifetime Solution

STEP 0: Pre-Calculation Summary
Formula Used
Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence
ζ4o = 1/Rp
This formula uses 2 Variables
Variables Used
Singlet Radiative Phosphorescence Lifetime - (Measured in Second) - Singlet Radiative Phosphorescence Lifetime of a population is the time measured for the number of excited molecules to decay exponentially to N/e of the original population.
Rate of Phosphorescence - (Measured in Mole per Cubic Meter Second) - Rate of Phosphorescence is the rate at which induced emission occurs.
STEP 1: Convert Input(s) to Base Unit
Rate of Phosphorescence: 15750 Mole per Liter Second --> 15750000 Mole per Cubic Meter Second (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
ζ4o = 1/Rp --> 1/15750000
Evaluating ... ...
ζ4o = 6.34920634920635E-08
STEP 3: Convert Result to Output's Unit
6.34920634920635E-08 Second --> No Conversion Required
FINAL ANSWER
6.34920634920635E-08 6.3E-8 Second <-- Singlet Radiative Phosphorescence Lifetime
(Calculation completed in 00.004 seconds)

Credits

Created by Torsha_Paul
University of Calcutta (CU), Kolkata
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25 Emission Spectroscopy Calculators

Intensity of Fluorescence given Degree of Exciplex Formation
Go Fluorosence Intensity given Degree of Exciplex = Rate Constant of Fluoroscence*Equilibrium Constant for Coordinate Complexes*(1-Degree of Exciplex Formation)/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)
Degree of Exciplex Formation
Go Degree of Exciplex Formation = (Equilibrium Constant for Coordinate Complexes*Quencher Concentration given Degree of Exciplex)/(1+(Equilibrium Constant for Coordinate Complexes*Quencher Concentration given Degree of Exciplex))
Fluoroscence Quantum Yield given Phosphorescence Quantum Yield
Go Fluorosecence Quantum Yield given Ph = Phosphosecence Quantum Yield*((Rate Constant of Fluoroscence*Singlet State Concentration)/(Phosphorescence Rate Constant*Concentration of Triplet State))
Fluorosence Intensity at Low Concentration of Solute
Go Fluorosence Intensity at Low Concentration = Fluorosecence Quantum Yield*Initial Intensity*2.303*Spectroscopical Molar Extinction Coefficient*Concentration at Time t*Length
Fluorescence Quantum Yield
Go Quantum Yield of Fluorescence = Rate of Radiative Reaction/(Rate of Radiative Reaction+Rate of Internal Conversion+Rate Constant of Intersystem Crossing+Quenching Constant)
Initial Intensity given Degree of Exciplex Formation
Go Initial Intensity given Degree of Exciplex = Rate Constant of Fluoroscence*Equilibrium Constant for Coordinate Complexes/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)
Intensity Ratio
Go Intensity Ratio = 1+(Quencher Concentration given Degree of Exciplex*(Quenching Constant/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)))
Quantum Yield of Fluorescence
Go Quantum Yield of Fluorescence = Rate Constant of Fluoroscence/(Rate Constant of Fluoroscence+Rate of Internal Conversion+Rate Constant of Intersystem Crossing)
Singlet Life Time of Radiative Process
Go Singlet Life time of Radiative Process = ((Initial Intensity/Fluorosence Intensity)-1)/(Quenching Constant*Quencher Concentration given Degree of Exciplex)
Fluoroscence Intensity without Quenching
Go Intensity Without Quenching = (Rate Constant of Fluoroscence*Absorption Intensity)/(Rate Constant of Non Radiative Reaction+Rate Constant of Fluoroscence)
Final Intensity using Stern Volmer Equation
Go Final Intensity = Initial Intensity/ (1+(Singlet Life time given Degree of Exciplex*Quenching Constant*Quencher Concentration given Degree of Exciplex))
Fluoroscence Intensity
Go Fluorosence Intensity = (Rate Constant of Fluoroscence*Absorption Intensity)/(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)
Collisional Energy Transfer
Go Rate of Collisional Energy Transfer = Quenching Constant*Quencher Concentration given Degree of Exciplex*Singlet State Concentration
Rate of Deactivation
Go Rate of Deactivation = (Rate Constant of Non Radiative Reaction+Rate Constant of Fluoroscence)*Singlet State Concentration
Quenching Concentration given Degree of Exciplex Formation
Go Quencher Concentration given Degree of Exciplex = ((1/(1-Degree of Exciplex Formation))-1)*(1/Equilibrium Constant for Coordinate Complexes)
Quenching Concentration
Go Quencher Concentration = ((Initial Intensity/Fluorosence Intensity)-1)/Stern Volmner Constant
Singlet Life given Degree of Exciplex Formation
Go Singlet Life time given Degree of Exciplex = 1/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)
Rate of Phosphorescence
Go Phosphorescence Rate = Phosphorescence Rate Constant*Concentration of Triplet State
ISC Rate Constant
Go Rate Constant of ISC = Rate of Intersystem Crossing*Singlet State Concentration
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
Equilibrium Constant for Exciplex Formation
Go Equilibrium Constant for Coordinate Complexes = 1/(1-Degree of Exciplex Formation)-1
Singlet Radiative Phosphorescence Lifetime
Go Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence

13 Quantum Yield and Singlet Llifetime Calculators

Phosphorescence Quantum Yield given Triplet Triplet Annhilation Constant
Go Phosphosecence Quantum Yield given TTA Constant = (Phosphorescence Rate Constant*ISC Quantum Yield)/(Phosphorescence Rate Constant+Rate Constant of Intersystem Crossing+Rate Constant of Triplet Triplet Anhilation)
Phosphorescence Quantum Yield given Intersystem Quantum Yield
Go Phosphorescence Quantum Yield given ISC = (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 Phosphorescence Quantum Yield given φf = 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 given Ph = Phosphosecence Quantum Yield*((Rate Constant of Fluoroscence*Singlet State Concentration)/(Phosphorescence Rate Constant*Concentration of Triplet State))
Fluorescence Quantum Yield
Go Quantum Yield of Fluorescence = Rate of Radiative Reaction/(Rate of Radiative Reaction+Rate of Internal Conversion+Rate Constant of Intersystem Crossing+Quenching Constant)
Quantum Yield of Fluorescence
Go Quantum Yield of Fluorescence = Rate Constant of Fluoroscence/(Rate Constant of Fluoroscence+Rate of Internal Conversion+Rate Constant of Intersystem Crossing)
Singlet Life Time of Radiative Process
Go Singlet Life time of Radiative Process = ((Initial Intensity/Fluorosence Intensity)-1)/(Quenching Constant*Quencher Concentration given Degree of Exciplex)
Singlet Life Time
Go Singlet Life time = 1/(Rate Constant of Intersystem Crossing+Rate of Radiative Reaction+Rate of Internal Conversion+Quenching Constant)
Phosphorescence Quantum Yield
Go Quantum Yield of Phosphorescence = Rate of Radiative Reaction/(Rate of Radiative Reaction+Rate Constant of Non Radiative Reaction)
Triplet State Quantum yield
Go Quantum Yield of Triplet State = (Rate Constant of Intersystem Crossing*Singlet State Concentration)/Absorption Intensity
Singlet Life given Degree of Exciplex Formation
Go Singlet Life time given Degree of Exciplex = 1/(Rate Constant of Fluoroscence+Rate Constant of Non Radiative Reaction)
Singlet Radiative Fluorescence Lifetime
Go Singlet Radiative Fluorescence Lifetime = 1/Rate Constant of Fluoroscence
Singlet Radiative Phosphorescence Lifetime
Go Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence

Singlet Radiative Phosphorescence Lifetime Formula

Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence
ζ4o = 1/Rp

What is Phosphorescence?

The emission of radiation in a similar manner to fluorescence but on a longer timescale, so that emission continues after excitation ceases.

How to Calculate Singlet Radiative Phosphorescence Lifetime?

Singlet Radiative Phosphorescence Lifetime calculator uses Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence to calculate the Singlet Radiative Phosphorescence Lifetime, The Singlet Radiative Phosphorescence Lifetime is the inverse of rate of Phosphorescence or radiative emission. It measures the decay time. Singlet Radiative Phosphorescence Lifetime is denoted by ζ4o symbol.

How to calculate Singlet Radiative Phosphorescence Lifetime using this online calculator? To use this online calculator for Singlet Radiative Phosphorescence Lifetime, enter Rate of Phosphorescence (Rp) and hit the calculate button. Here is how the Singlet Radiative Phosphorescence Lifetime calculation can be explained with given input values -> 6.3E-8 = 1/15750000.

FAQ

What is Singlet Radiative Phosphorescence Lifetime?
The Singlet Radiative Phosphorescence Lifetime is the inverse of rate of Phosphorescence or radiative emission. It measures the decay time and is represented as ζ4o = 1/Rp or Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence. Rate of Phosphorescence is the rate at which induced emission occurs.
How to calculate Singlet Radiative Phosphorescence Lifetime?
The Singlet Radiative Phosphorescence Lifetime is the inverse of rate of Phosphorescence or radiative emission. It measures the decay time is calculated using Singlet Radiative Phosphorescence Lifetime = 1/Rate of Phosphorescence. To calculate Singlet Radiative Phosphorescence Lifetime, you need Rate of Phosphorescence (Rp). With our tool, you need to enter the respective value for Rate of Phosphorescence 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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