## Transition Energy from A2g to T1gF Solution

STEP 0: Pre-Calculation Summary
Formula Used
Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction
ΕA2g to T1gF = (9/5*Δ)-CI
This formula uses 3 Variables
Variables Used
Transition Energy from A2g to T1gF - (Measured in Diopter) - Transition Energy from A2g to T1gF is the energy of transition from A2g to T1gF.
Energy Difference - (Measured in Diopter) - Energy Difference is the difference in energy between the two ground state in Orgel Diagram.
Configuration Interaction - (Measured in Diopter) - Configuration Interaction is the interaction from repulsion of like terms.
STEP 1: Convert Input(s) to Base Unit
Energy Difference: 4000 Diopter --> 4000 Diopter No Conversion Required
Configuration Interaction: 800 Diopter --> 800 Diopter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
ΕA2g to T1gF = (9/5*Δ)-CI --> (9/5*4000)-800
Evaluating ... ...
ΕA2g to T1gF = 6400
STEP 3: Convert Result to Output's Unit
6400 Diopter --> No Conversion Required
6400 Diopter <-- Transition Energy from A2g to T1gF
(Calculation completed in 00.000 seconds)
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## Credits

Created by Torsha_Paul
University of Calcutta (CU), Kolkata
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## < 12 Stabilization Energy Calculators

Equilibrium Constant for Coordinate Complexes
Formation Constant for Coordinate Complexes = (Concentration of Complex Ion^Stoichiometric Coefficient of Complex Ion)/((Concentration of Metal in Complex^Stoichiometric Coefficient of Metal)*(Concentration of Lewis Bases^Stoichiometric Coefficient of Lewis Base))
Transition Energy from T1g to T1gP
Transition Energy from T1g to T1gP = (3/5*Energy Difference)+(15*Racah Parameter)+(2*Configuration Interaction)
Transition Energy from A2g to T1gP
Transition Energy from A2g to T1gP = (6/5*Energy Difference)+(15*Racah Parameter)+Configuration Interaction
Octahedral Site Stabilization Energy
Octahedral Site Stabilization Energy = Crystal Field Splitting Energy Octahedral-Crystal Field Splitting Energy Tetrahedral
Crystal Field Splitting Energy for Tetrahedral Complexes
Crystal Field Splitting Energy Tetrahedral = ((Electrons In Eg Orbitals*(-0.6))+(0.4*Electrons In T2g Orbital))*(4/9)
Crystal Field Activation Energy for Dissociative Reaction
CFAE Dissociative Substitution = Crystal Field Splitting Energy Octahedral-CFSE For Square Pyramidal Intermediate
Crystal Field Splitting Energy for Octahedral Complexes
Crystal Field Splitting Energy Octahedral = (Electrons In Eg Orbitals*0.6)+(-0.4*Electrons In T2g Orbital)
Solubility Product of Coordinate Complex
Solubility Product of Coordinate Complex = Formation Constant for Coordinate Complexes*Solubility Product
Crystal Field Activation Energy for Associative Reaction
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Transition Energy from A2g to T1gF
Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction
Transition Energy from T1g to T2g
Transition Energy from T1g to T2g = (4/5*Energy Difference)+Configuration Interaction
Transition Energy from T1g to A2g
Transition Energy from T1g to A2g = (9/5*Energy Difference)+Configuration Interaction

## Transition Energy from A2g to T1gF Formula

Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction
ΕA2g to T1gF = (9/5*Δ)-CI

## What is Orgel Diagram ?

Orgel diagrams are correlation diagrams which show the relative energies of electronic terms in transition metal complexes. Orgel diagrams are useful for showing the energy levels of both high spin octahedral and tetrahedral transition metal ions. They ONLY show the spin-allowed transitions. For complexes with D ground terms only one electronic transition is expected and the transition energy corresponds directly to D. Hence, the following high spin configurations are dealt with: d1, d4, d6 and d9.

## How to Calculate Transition Energy from A2g to T1gF?

Transition Energy from A2g to T1gF calculator uses Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction to calculate the Transition Energy from A2g to T1gF, Transition Energy from A2g to T1gF is the energy of transition from A2g to T1gF in orgel Diagram. In an atom, transition energy changes potential energy of an electron, whereby it controls the position through orientation force. For high spin complexes it is calculated from Orgel Diagram. Transition Energy from A2g to T1gF is denoted by ΕA2g to T1gF symbol.

How to calculate Transition Energy from A2g to T1gF using this online calculator? To use this online calculator for Transition Energy from A2g to T1gF, enter Energy Difference (Δ) & Configuration Interaction (CI) and hit the calculate button. Here is how the Transition Energy from A2g to T1gF calculation can be explained with given input values -> 6400 = (9/5*4000)-800.

### FAQ

What is Transition Energy from A2g to T1gF?
Transition Energy from A2g to T1gF is the energy of transition from A2g to T1gF in orgel Diagram. In an atom, transition energy changes potential energy of an electron, whereby it controls the position through orientation force. For high spin complexes it is calculated from Orgel Diagram and is represented as ΕA2g to T1gF = (9/5*Δ)-CI or Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction. Energy Difference is the difference in energy between the two ground state in Orgel Diagram & Configuration Interaction is the interaction from repulsion of like terms.
How to calculate Transition Energy from A2g to T1gF?
Transition Energy from A2g to T1gF is the energy of transition from A2g to T1gF in orgel Diagram. In an atom, transition energy changes potential energy of an electron, whereby it controls the position through orientation force. For high spin complexes it is calculated from Orgel Diagram is calculated using Transition Energy from A2g to T1gF = (9/5*Energy Difference)-Configuration Interaction. To calculate Transition Energy from A2g to T1gF, you need Energy Difference (Δ) & Configuration Interaction (CI). With our tool, you need to enter the respective value for Energy Difference & Configuration Interaction and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well. Let Others Know