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Rate of Energy Transfer using Distances and Donor Lifetime Formula

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Rate of Energy Transfer is simply the rate of energy transfer from a donor to an acceptor. Check FAQs

K T = (\frac{1}{ζ D}) \cdot {(\frac{R 0}{r})}^{6}

K_T - Rate of Energy Transfer?ζ_D - Donor Lifetime?R₀ - Forster Critical Distance?r - Donor to Acceptor Distance?

Rate of Energy Transfer using Distances and Donor Lifetime Example

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Here is how the Rate of Energy Transfer using Distances and Donor Lifetime equation looks like with Values.

Here is how the Rate of Energy Transfer using Distances and Donor Lifetime equation looks like with Units.

Here is how the Rate of Energy Transfer using Distances and Donor Lifetime equation looks like.

26.2144 = (\frac{1}{0.01}) \cdot {(\frac{40}{50})}^{6}

26.2144 = (\frac{1}{0.01}) \cdot {(\frac{40A}{50A})}^{6}

26.2144 = (\frac{1}{0.01}) \cdot {(\frac{40}{50})}^{6}

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Rate of Energy Transfer using Distances and Donor Lifetime Solution

Follow our step by step solution on how to calculate Rate of Energy Transfer using Distances and Donor Lifetime?

FIRST Step Consider the formula

K T = (\frac{1}{ζ D}) \cdot {(\frac{R 0}{r})}^{6}

Next Step Substitute values of Variables

∴

K T = (\frac{1}{0.01}) \cdot {(\frac{40A}{50A})}^{6}

Next Step Convert Units

∴

K T = (\frac{1}{0.01}) \cdot {(\frac{4E-9m}{5E-9m})}^{6}

Next Step Prepare to Evaluate

∴

K T = (\frac{1}{0.01}) \cdot {(\frac{4E-9}{5E-9})}^{6}

LAST Step Evaluate

∴

K T = 26.2144

Rate of Energy Transfer using Distances and Donor Lifetime Formula Elements

Variables

Rate of Energy Transfer

Rate of Energy Transfer is simply the rate of energy transfer from a donor to an acceptor.

Symbol: K_T

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Rate of Energy Transfer

Donor Lifetime

The Donor Lifetime is the donor's fluorescence lifetime in the absence of the acceptor.

Symbol: ζ_D

Measurement: NAUnit: Unitless

Note: Value should be greater than 0.

Formulas to find Donor Lifetime

Forster Critical Distance

The Forster Critical Distance is the distance at which the energy transfer efficiency is 50%.

Symbol: R₀

Measurement: LengthUnit: A

Note: Value should be greater than 0.

Formulas to find Forster Critical Distance

Donor to Acceptor Distance

Donor to Acceptor Distance is the distance between the donor and the acceptor molecules.

Symbol: r

Measurement: LengthUnit: A

Note: Value should be greater than 0.

Formulas to find Donor to Acceptor Distance

Other formulas in Förster resonance energy transfer category

Go Efficiency of Energy Transfer using Distances

E = \frac{1}{1 + {(\frac{r}{R 0})}^{6}}

Go Forster Critical Distance

R 0 = 0.0211 \cdot {({(η)}^{- 4} \cdot (Φ d) \cdot (κ 2) \cdot (J))}^{\frac{1}{6}}

Go Efficiency of Energy Transfer using Rate of Energy Transfer

E = \frac{K T}{K T + K nr + K r}

Go Efficiency of Energy Transfer using Rate of Energy Transfer and Donor Lifetime

E = \frac{K T}{\frac{1}{ζ DA}}

How to Evaluate Rate of Energy Transfer using Distances and Donor Lifetime?

Rate of Energy Transfer using Distances and Donor Lifetime evaluator uses Rate of Energy Transfer = (1/Donor Lifetime)*(Forster Critical Distance/Donor to Acceptor Distance)^6 to evaluate the Rate of Energy Transfer, The Rate of Energy Transfer using Distances and Donor Lifetime formula is defined as multiplication of inverse of donor lifetime without FRET and to the 6th power of the ratio of forster critical distance to donor acceptor distance. Rate of Energy Transfer is denoted by K_T symbol.

How to evaluate Rate of Energy Transfer using Distances and Donor Lifetime using this online evaluator? To use this online evaluator for Rate of Energy Transfer using Distances and Donor Lifetime, enter Donor Lifetime (ζ_D), Forster Critical Distance (R₀) & Donor to Acceptor Distance (r) and hit the calculate button.

FAQs on Rate of Energy Transfer using Distances and Donor Lifetime

What is the formula to find Rate of Energy Transfer using Distances and Donor Lifetime?

The formula of Rate of Energy Transfer using Distances and Donor Lifetime is expressed as Rate of Energy Transfer = (1/Donor Lifetime)*(Forster Critical Distance/Donor to Acceptor Distance)^6. Here is an example- 2621.44 = (1/0.01)*(4E-09/5E-09)^6.

How to calculate Rate of Energy Transfer using Distances and Donor Lifetime?

With Donor Lifetime (ζ_D), Forster Critical Distance (R₀) & Donor to Acceptor Distance (r) we can find Rate of Energy Transfer using Distances and Donor Lifetime using the formula - Rate of Energy Transfer = (1/Donor Lifetime)*(Forster Critical Distance/Donor to Acceptor Distance)^6.

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Rate of Energy Transfer using Distances and Donor Lifetime Formula

Rate of Energy Transfer using Distances and Donor Lifetime Example

Rate of Energy Transfer using Distances and Donor Lifetime Solution

Rate of Energy Transfer using Distances and Donor Lifetime Formula Elements

Other formulas in Förster resonance energy transfer category

How to Evaluate Rate of Energy Transfer using Distances and Donor Lifetime?

FAQs on Rate of Energy Transfer using Distances and Donor Lifetime

Variable Name