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High-accuracy ab initio water line intensities Lorenzo Lodi University College London Department of Physics & Astronomy.

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Presentation on theme: "High-accuracy ab initio water line intensities Lorenzo Lodi University College London Department of Physics & Astronomy."— Presentation transcript:

1 High-accuracy ab initio water line intensities Lorenzo Lodi University College London Department of Physics & Astronomy

2 Talk summary Variational methods for vibration-rotation spectra Electronic structure treatment Results for water line intensities

3 What we are aiming at? Line intensities are extremely important. They are also difficult to measure accurately. Aim: accuracy of 1% (for majority lines). We used the very best level of theory to achieve this goal. Line intensities likely to be in error can be identified.

4 General scheme of solution Solve the electronic problem, obtaining Potential Energy Surface E(R) and Dipole Moment Surface  (R). Use E(R) for the motion of the nuclei. From  (R) and nuclear-motion wavefunctions calculate line intensities. Born-Oppenheimer approximation.

5 Solving for the nuclear motion An efficient technique to do this is the Discrete Variable Representation method. The resulting 3-dimentional Schrödinger equation can be solved numerically. Molecule-fixed, J-dependent effective hamiltonians can be derived. Accuracy of line positions and intensities is limited by quality of PES and DMS.

6 Transition intensities Transition intensity for the transition n → m is given by  (R) is the Dipole Moment Surface (DMS) function and is given by We compute the DMS for many selected geometries and then interpolate between these values.

7 Multi-reference methods Standard methods such as DFT, MP2 etc are not suitable. Multi-reference methods are needed. We used IC-MRCI+Q[8,10], 6Z basis set. Relativistic effects accounted for.

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10 Equilibrium water dipole From L. Lodi and J. Tennyson, J. Phys. B: At. Mol. Opt. Phys. 43, 133001 (2010)

11 Fitting the points Intensities are very sensitive to oscillations in the DMS.

12 Lisak, Harvey and Hodges D. Lisak, D. K. Harvey and J.T. Hodges, Phys. Rev. A 79, 052507 (2009) 15 line intensities between 7170-7183 cm -1 Declared error of 0.4%.

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14 Lisak, Harvey and Hodges 15 very accurate lines One line where theory is consistently stronger by 30% For the other 14 lines: average 1.01(1)

15 Ponsardin & Browell P.L. Ponsardin and E. V. Browell, J. Mol. Spectr. 185, 58-70 (1997) 40 line intensities around 12,200 cm -1. Declared error of 2%.

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20 Summary comparison with HITRAN2008 Total lines analysed: 26,957 Stable lines: 19,056 Unstable lines: 7,901 Average of ratios for stable lines: 1.00(4)

21 Final words New high-accurate intensity linelist Error of 1% in most cases “Resonant” lines with large errors can be identified

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