Bond Breakage Time Calculator

✖Length Scale FTS is a measure of distance for exponential repulsion.ⓘ Length Scale FTS [L]			+10% -10%
✖Speed FTS is the rate at which someone or something moves or operates or is able to move or operate.ⓘ Speed FTS [v]			+10% -10%
✖Energy FTS is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of heat and light.ⓘ Energy FTS [E]			+10% -10%
✖The Bond Breakage Time Pulse Width is a measure of the elapsed time between the leading and trailing edges of a single pulse of energy.ⓘ Bond Breakage Time Pulse Width [δ]			+10% -10%

✖Bond Breakage Time is the time required to break the bond in atomic scale wave packet in femtoseconds.ⓘ Bond Breakage Time [ζ_BB]

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Formula

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Bond Breakage Time

Formula

`"ζ"_{"BB"} = ("L"/"v")*ln((4*"E")/"δ")`

Example

`"0.89588fs"=("10m"/"20m/s")*ln((4*"3.6J")/"2.4fs")`

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Bond Breakage Time Solution

STEP 0: Pre-Calculation Summary

Formula Used

Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width)
ζ_BB = (L/v)*ln((4*E)/δ)
This formula uses 1 Functions, 5 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

Bond Breakage Time - (Measured in Femtosecond) - Bond Breakage Time is the time required to break the bond in atomic scale wave packet in femtoseconds.
Length Scale FTS - (Measured in Meter) - Length Scale FTS is a measure of distance for exponential repulsion.
Speed FTS - (Measured in Meter per Second) - Speed FTS is the rate at which someone or something moves or operates or is able to move or operate.
Energy FTS - (Measured in Joule) - Energy FTS is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of heat and light.
Bond Breakage Time Pulse Width - (Measured in Femtosecond) - The Bond Breakage Time Pulse Width is a measure of the elapsed time between the leading and trailing edges of a single pulse of energy.

STEP 1: Convert Input(s) to Base Unit

Length Scale FTS: 10 Meter --> 10 Meter No Conversion Required
Speed FTS: 20 Meter per Second --> 20 Meter per Second No Conversion Required
Energy FTS: 3.6 Joule --> 3.6 Joule No Conversion Required
Bond Breakage Time Pulse Width: 2.4 Femtosecond --> 2.4 Femtosecond No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

ζ_BB = (L/v)*ln((4*E)/δ) --> (10/20)*ln((4*3.6)/2.4)

Evaluating ... ...

ζ_BB = 0.895879734614027

STEP 3: Convert Result to Output's Unit

8.95879734614028E-16 Second -->0.895879734614028 Femtosecond (Check conversion here)

FINAL ANSWER

0.895879734614028 ≈ 0.89588 Femtosecond <-- Bond Breakage Time

(Calculation completed in 00.020 seconds)

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Created by Sangita Kalita

National Institute of Technology, Manipur (NIT Manipur), Imphal, Manipur

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< 20 Femtochemistry Calculators

Observed Lifetime Given Quenching Time

Go Observed Lifetime = ((Self Quenching Time*Quenching Time)+(Radiative Lifetime*Quenching Time)+(Self Quenching Time*Radiative Lifetime))/(Radiative Lifetime*Self Quenching Time*Quenching Time)

Observed Lifetime Given Reduced Mass

Go Observed Lifetime = sqrt((Reduced Mass of Fragments*[BoltZ]*Temperature for Quenching)/(8*pi))/(Pressure for Quenching*Cross Section Area for Quenching)

Field Strength for Barrier Suppression Ionization

Go Field Strength for Barrier Suppression Ionization = (([Permitivity-vacuum]^2)*([hP]^2)*(Ionization Potential Barrier Suppression^2))/(([Charge-e]^3)*[Mass-e]*[Bohr-r]*Final Charge)

Spectral Chirp

Go Spectral Chirp = (4*Temporal Chirp*(Pulse Duration^4))/((16*(ln(2)^2))+((Temporal Chirp^2)*(Pulse Duration^4)))

Mean Free Tunneling Time for Electron

Go Mean Free Tunneling Time = (sqrt(Ionization Potential Barrier Suppression/(2*[Mass-e])))/Field Strength for Barrier Suppression Ionization

Velocity for Delayed Coherence in Photodissociation

Go Velocity for Delayed Coherence = sqrt((2*(Binding Potential-Potential Energy of Repulsing Term))/Reduced Mass for Delayed Coherence)

Potential for Exponential Repulsion

Go Potential For Exponential Repulsion = Energy FTS*(sech((Speed FTS*Time FTS)/(2*Length Scale FTS)))^2

Bond Breakage Time

Go Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width)

Analysis of Anisotropy

Go Analysis of Anisotropy = ((cos(Angle Between Transition Dipole Moments)^2)+3)/(10*cos(Angle Between Transition Dipole Moments))

Anisotropy Decay Behavior

Go Anisotropy Decay = (Parallel Transient-Perpendicular Transient)/(Parallel Transient+(2*Perpendicular Transient))

Relationship between Pulse Intensity and Electric Field Strength

Go Electric Field Strength for Ultrafast Radiation = sqrt((2*Intensity of Laser)/([Permitivity-vacuum]*[c]))

Gaussian-Like Pulse

Go Gaussian Like Pulse = sin((pi*Time FTS)/(2*Half Width of Pulse))^2

Mean Electron Velocity

Go Mean Electron Velocity = sqrt((2*Ionization Potential Barrier Suppression)/[Mass-e])

Pump Pulse Difference

Go Pump Pulse Difference = (3*(pi^2)*Dipole Dipole Interaction for Exciton)/((Exciton Delocalization Length+1)^2)

Classical Analysis of Fluorescence Anisotropy

Go Classical Analysis of Fluorescence Anisotropy = (3*(cos(Angle Between Transition Dipole Moments)^2)-1)/5

Transit Time from Center of Sphere

Go Transit Time = (Radius of Sphere for Transit^2)/((pi^2)*Diffusion Coefficient for Transit)

Carrier Wavelength

Go Carrier Wavelength = (2*pi*[c])/Carrier Light Frequency

Recoil Energy for Bond Breaking

Go Energy FTS = (1/2)*Reduced Mass of Fragments*(Speed FTS^2)

Frequency Modulation

Go Frequency Modulation = (1/2)*Temporal Chirp*(Time FTS^2)

Mean Free Tunneling Time Given Velocity

Go Mean Free Tunneling Time = 1/Mean Electron Velocity

Bond Breakage Time Formula

Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width)
ζ_BB = (L/v)*ln((4*E)/δ)

What is femtochemistry?

Femtochemistry is the area of physical chemistry that studies chemical reactions on extremely short timescales (approximately 10 seconds or one femtosecond, hence the name) in order to study the very act of atoms within molecules (reactants) rearranging themselves to form new molecules (products).

How to Calculate Bond Breakage Time?

Bond Breakage Time calculator uses Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width) to calculate the Bond Breakage Time, The Bond Breakage Time formula is defined as time taken to break a bond during absorption of fragments by considering FTS observables. It is observed with a drop in potential. Bond Breakage Time is denoted by ζ_BB symbol.

How to calculate Bond Breakage Time using this online calculator? To use this online calculator for Bond Breakage Time, enter Length Scale FTS (L), Speed FTS (v), Energy FTS (E) & Bond Breakage Time Pulse Width (δ) and hit the calculate button. Here is how the Bond Breakage Time calculation can be explained with given input values -> 9E+14 = (10/20)*ln((4*3.6)/2.4E-15).

FAQ

What is Bond Breakage Time?

The Bond Breakage Time formula is defined as time taken to break a bond during absorption of fragments by considering FTS observables. It is observed with a drop in potential and is represented as ζ_BB = (L/v)*ln((4*E)/δ) or Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width). Length Scale FTS is a measure of distance for exponential repulsion, Speed FTS is the rate at which someone or something moves or operates or is able to move or operate, Energy FTS is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of heat and light & The Bond Breakage Time Pulse Width is a measure of the elapsed time between the leading and trailing edges of a single pulse of energy.

How to calculate Bond Breakage Time?

The Bond Breakage Time formula is defined as time taken to break a bond during absorption of fragments by considering FTS observables. It is observed with a drop in potential is calculated using Bond Breakage Time = (Length Scale FTS/Speed FTS)*ln((4*Energy FTS)/Bond Breakage Time Pulse Width). To calculate Bond Breakage Time, you need Length Scale FTS (L), Speed FTS (v), Energy FTS (E) & Bond Breakage Time Pulse Width (δ). With our tool, you need to enter the respective value for Length Scale FTS, Speed FTS, Energy FTS & Bond Breakage Time Pulse Width 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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