Natural Transition Orbitals (NTOs) Gaussian

The canonical molecular orbital depiction of an electronic transition is often a messy business in terms of a ‘chemical‘ interpretation of ‘which electrons‘ go from ‘which occupied orbitals‘ to ‘which virtual orbitals‘.

Natural Transition Orbitals provide a more intuitive picture of the orbitals, whether mixed or not, involved in any hole-particle excitation. This transformation is particularly useful when working with the excited states of molecules with extensively delocalized chromophores or multiple chromophoric sites. The elegance of the NTO method relies on its simplicity: separate unitary transformations are performed on the occupied and on the virtual set of orbitals in order to get a localized picture of the transition density matrix.

[1] R. L. Martin, J. Chem. Phys., 2003, DOI:10.1063/1.1558471.

In Gaussian09:
After running a TD-DFT calculation with the keyword TD(Nstates=n) (where n = number of states to be requested) we need to take that result and launch a new calculation for the NTOs but lets take it one step at a time. As an example here’s phenylalanine which was already optimized to a minimum at the B3LYP/6-31G(d,p) level of theory. If we take that geometry and launch a new calculation with the TD(Nstates=40) in the route section we obtain the UV-Vis spectra and the output looks like this (only the first three states are shown):

Excitation energies and oscillator strengths:

Excited State 1: Singlet-A 5.3875 eV 230.13 nm f=0.0015 <S**2>=0.000
42 -> 46 0.17123
42 -> 47 0.12277
43 -> 46 -0.40383
44 -> 45 0.50838
44 -> 47 0.11008
This state for optimization and/or second-order correction.
Total Energy, E(TD-HF/TD-KS) = -554.614073682
Copying the excited state density for this state as the 1-particle RhoCI density.

Excited State 2: Singlet-A 5.5137 eV 224.86 nm f=0.0138 <S**2>=0.000
41 -> 45 -0.20800
41 -> 47 0.24015
42 -> 45 0.32656
42 -> 46 0.10906
42 -> 47 -0.24401
43 -> 45 0.20598
43 -> 47 -0.14839
44 -> 45 -0.15344
44 -> 47 0.34182

Excited State 3: Singlet-A 5.9254 eV 209.24 nm f=0.0042 <S**2>=0.000
41 -> 45 0.11844
41 -> 47 -0.12539
42 -> 45 -0.10401
42 -> 47 0.16068
43 -> 45 -0.27532
43 -> 46 -0.11640
43 -> 47 0.16780
44 -> 45 -0.18555
44 -> 46 -0.29184
44 -> 47 0.43124

The oscillator strength is listed on each Excited State as “f” and it is a measure of the probability of that excitation to occur. If we look at the third one for this phenylalanine we see f=0.0042, a very low probability, but aside from that the following list shows what orbital transitions compose that excitation and with what energy, so the first line indicates a transition from orbital 41 (HOMO-3) to orbital 45 (LUMO); there are 10 such transitions composing that excitation, visualizing them all with canonical orbitals is not an intuitive picture, so lets try the NTO approach, we’re going to take excitation #10 for phenylalanine as an example just because it has a higher oscillation strength:

%chk=Excited State 10: Singlet-A 7.1048 eV 174.51 nm f=0.3651 <S**2>=0.000
41 -> 45 0.35347
41 -> 47 0.34685
42 -> 45 0.10215
42 -> 46 0.17248
42 -> 47 0.13523
43 -> 45 -0.26596
43 -> 47 -0.22995
44 -> 46 0.23277

Each set of NTOs for each transition must be calculated separately. First, copy you filename.chk file from the TD-DFT result to a new one and name it after the Nth state of interest as shown below (state 10 in this case). NOTE: In the route section, replace N with the number of the excitation of interest according to the results in filename.log. Run separately for each transition your interested in:

#chk=state10.chk

#p B3LYP/6-31G(d,p) Geom=AllCheck Guess=(Read,Only) Density=(Check,Transition=N) Pop=(Minimal,NTO,SaveNTO)

0 1
--blank line--

By requesting SaveNTO, the canonical orbitals in the state10.chk file are replaced with the NTOs for the 10th excitation, this makes it easier to plot since most visualizers just plot whatever set of orbitals they read in the chk file but if they find the canonical MOs then one would need to do some re-processing of them. This is much more straightforward.

Now we format our chk files into fchk with the formchk utility:

formchk -3 filename.chk filename.fchk
formchk -3 state10.chk state10.fchk

If we open filename.fchk (the file where the original TD-DFT calculation is located) with GaussView we can plot all orbitals involved in excited state number ten, those would be seven orbitals from 41 (HOMO-3) to 47 (LUMO+2) as shown in figure 1.

Figure 1. Canonical orbitals involved in the 10th excited state according to the TD-DFT calculation

If we now open state10.fchk we see that the numbers at the side of the orbitals are not their energy but their occupation number particular to this state of interest, so we only need to plot those with highest occupations, in our example those are orbitals 44 and 45 (HOMO and LUMO) which have occupations = 0.81186; you may include 43 and 46 (HOMO-1 and LUMO+1, respectively) for a much more complete description (occupations = 0.18223) but we’re still dealing with 4 orbitals instead of 7.

Figure 2. Natural Transition Orbitals for Phenylalanine. Orbital 44 (particle) and Orbital 45 (hole) exhibit the largest occupations for Excited State No. 10

The NTO transition 44 -> 45 is far easier to conceptualize than all the 10 combinations given in the canonical basis from the direct TD-DFT calculation. TD-DFT provides us with the correct transitions, NTOs just paint us a picture more readily available to the chemist mindset.

NOTE: for G09 revC and above, the %OldChk option is available, I haven’t personally tried it but using it to specify where the excitations are located and then write the NTOs of interest into a new chk file in the following way, thus eliminating the need of copying the original chk file for each state:

%OldChk=filename.chk
%chk=stateN.chk

NTOs are based on the Natural Hybrid orbitals vision by Löwdin and others, and it is said to be so straightforward that it has been re-discovered from time to time. Be that as it may, the NTO visualization provides a much clearer vision of the excitations occurring during a TD calculation.

Thanks for reading, stay home and stay safe during these harsh days everyone. Please share, rate and comment this and other posts.

About joaquinbarroso

Theoretical chemist in his early forties, in love with life and deeply in love with his woman and children. I love science, baseball, literature, movies (perhaps even in that order). I'm passionate about food and lately wines have become a major hobby. In a nutshell I'm filled with regrets but also with hope, and that is called "living".

Posted on April 6, 2020, in Computational Chemistry, DFT, Fluorescence, Gaussian, Models, NBO, NBO, Spectroscopy, TD-DFT, Tricks, Visualization, White papers and tagged , , , , , , , , , , , , . Bookmark the permalink. 14 Comments.

  1. Brahim HACHLAF

    Hello, I’m Brahim, beginner researcher in thoeritecal chemistry, I work with gaussian for three years ago, but I need someone to help and give a good way (orientation)? I have many new molecules no published, could you please help me for that?

  2. Thank you. Your topic is clear. I confirm you that the %Oldchk command is going on as well. Please, could you show us how to perform, in Gaussview, a differential density map for the 10th excitation of your NTO example ? That is to say to show the redistribution of the electron density upon excitation (decrease and increase). Have a nice work.

    • Hello,

      Thanks for confirming the functionality of %oldchk.
      GaussView 5 and beyond is able to perform operations on cubes from the Surfaces window -> Cube Actions tab -> Add/Subtract/ two cubes.
      So you first need to save the corresponding cubes from the NTO-containing fchk file with the cubegen utility. Once you generate them, load them and subtract them. I will try to write a step-by-step post on it.

      Have a nice day

  3. Edgardo Garcia

    Hi Joaquin,

    Thanks so much for your posts.
    I’m using Orca 4.2.1 to do TD-DFT with TDA aproximation at the B97-3c composite model and it does calculation of NTO by default, it also has a clean organized output and it is free :-). My question : how that stands for open-shell neutral systems ? Can we still draw meaningful chemical view for transitions related to the NTO pictures corresponding to the excitation with the highest transition probability in open-shell neutral systems ?

    • Hola Edgardo,

      Thanks for bringing ORCA to our attention, I should break some old habits and work other pieces of software I just need more time.
      Yes, you can work it with open shell systems but you have to consider alpha and beta spin densities separately, beware of the occupation numbers.

      I hope this helps!

      • Hola Joaquin,

        Thanks for your answer.
        True, breaking habits is never easy. This pandemic made me spend more time at the computer, found out that G09-ORCA oscillator strength is much higher than I anticipated. Operation is actually similar to G09 with keywords text input, really nice output files, helpful active forum, many options to generate cube files, visualizers include GaussView and free ones such as iQmol, Gabedit, Avogadro, Chimera etc
        I’m just starting to work with ORCA, mainly because it has several brand new DFT methods better suited to exited states and transitions in organo-metallic complex. That brought me into NTOs and your cool blog.
        One thing I noticed with the usual canonical molecular orbital isodensity pictures, is that their shapes can be highly dependent on the basis set used, I mean different pictures and localization for the same molecule. When that is the case their usefulness in providing any ‘chemical meaning’ is highly questionable.
        So far I only tried with a handful of compounds, found NTO much better in providing a more meaningful (localized) picture for particle-hole transitions.
        In your experience, are the NTO pictures consistent for a given molecule, less dependent than canonical MOs on the basis sets and DFT methods ?

  4. Pablo González Herrero

    Hi Joaquin,
    Thanks for your very useful posts. I want to ask you about the cases when, after an NTO calculation, several hole-particle pairs are obtained, and some of them have important occupations, let’s say 0.6 and 0.3. Is it possible to have an even better visualization by just performing a weighed sum of the resultant hole cubes and then, separately, the particle cubes? I have tried this and got a consistent result, but I am not sure if it is correct.

    • Hola Pablo
      It sounds right, I mean in the end there is nothing that prevents you from adding several NTO cubes into one and in the end each molecular orbital is the linear combination of other orbitals. I may be forgetting something here but I think there isn’t any fundamental prohibition to perform this linear combination (I’m assuming your weighing coefficients are the relative occupations). The only thing that would be fundamentally wrong would be to sum hole and particle NTOs

      Gracias por leernos!

  5. Hello professor Barroso,
    Thank you for this instructional post! I really appreciate it!
    I had a quick question, I performed a a TD-DFT with nbo, and it was nice to see the localized picture of the orbitals.
    Afterwards I performed a NTO analysis on excited state #3, my questions are as follows:

    1) Does the numbering of orbitals in NTO the same as NBO.For instance is orbital number 254 in NBO (for all excited state) the same as the orbital labeled 254 after the NTO for the third excited state?

    2) Also, in the NTO, I see my two highest occupation orbitals (occ and virtual) are one where the picture is very deolocalized over the entire molecule and the virtual orbital is centered on the metal, can I interpret this as an increase in electron density at the metal in the given transition?

    • Dear Kekeedme

      I’m glad you found it useful.
      The short answer for both your questions is yes 🙂 once NBO labels an orbital it sticks to that numbering scheme throughout any other analysis provided you’re using the same input/checkpoint file, so as long as you don’t start your calculation from scratch (and make a mistake then) you should be fine considering the same numbering scheme.
      NTOs are usually localized but sometimes they don’t look very much so, unfortunately. In the case you’re describing it looks like you have a charge transfer case.

      Thank you for reading.

  6. Connor Callaway

    Thanks for this great write-up, Joaquin. It’s very clear and helpful for understanding the principles (and practicals) of NTO analysis. 🙂

  7. Hello Doctor, your blog has very useful information for those of us who are starting with this.

    Is it possible that you have or can provide me some example on how to calculate Singlet-Triplet Split energy (S1 to T1) in gaussian? I mean, about the sequence to follow, or some example of the inputs.
    Thanks in advance

  8. Hello professor Barroso,

    I came here from a former question about calculating the orbitals of excited states (https://www.researchgate.net/post/How-can-I-calculate-the-natural-transition-orbitals-analysis-NTO-and-visualize-it). I followed the input “#p B3LYP/6-31G(d,p) Geom=AllCheck Guess=(Read,Only) Density=(Check,Transition=N)”, as well as “% oldchk” and “% chk”. However, it still can’t solve the “This type of calculation cannot be archived” problem.

    When I did not add “% oldchk”, the .log file wrote “This type of calculation cannot be archived”.
    When I added the “% oldchk”, the .log file indicated that it just copyed the information in old chk file to the new one.

  1. Pingback: Density Keyword in Excited State Calculations with Gaussian | Dr. Joaquin Barroso's Blog

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