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Controlled Neutralization of Anions in Cryogenic Matrices by Photodetachment Ryan M. Ludwig, David T. Moore Chemistry Department, Lehigh University Bethlehem,

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Presentation on theme: "Controlled Neutralization of Anions in Cryogenic Matrices by Photodetachment Ryan M. Ludwig, David T. Moore Chemistry Department, Lehigh University Bethlehem,"— Presentation transcript:

1 Controlled Neutralization of Anions in Cryogenic Matrices by Photodetachment Ryan M. Ludwig, David T. Moore Chemistry Department, Lehigh University Bethlehem, PA 18015

2 Introduction Using matrix isolation for study of ions Need charge balance Controlled deposition of counter-ions 2 hour dep -10eV Cu - 60eV Ar + 2% CO in Ar 27 mmol/hour 10K Anionic Copper Carbonyl 2

3 10K Deposition 1 2 3 1 2 3 Upon deposition both anionic and neutrals formed How are neutrals formed? No direct line of site from source Ion recombination Photodetachment n=1 n=2 n=3 3

4 10K Deposition 1 2 3 1 2 3 (CO) 2 - n=1 n=2 n=3 Careful control of ambient light Only anionic peaks observed! Irradiation Population transfer from anionic to neutral Photo-electrons flow through CB of solid argon ~1eV above vacuum level New peak at 1774 cm -1 4

5 Mixed Isotope 12 CO: 13 CO 50:50 mix Typical 1:1 for monocarbonyl 1:2:1 for dicarbonyl Same for new peak Broad shape for 5:3:3:5 for tricarbonyl with D 3h symmetry 30K 5

6 Irradiation during Deposition Only neutral copper species upon deposition Spectra qualitatively the same as deposition followed by photodetachment Neutralization event likely occurs after complex formation 6

7 0.125cm -1 Resolution Irradiation during deposition Taken after 20K annealing Peaks are intrinsically broad Consistent with inhomogeneous broadening 7

8 “Thermal” Neutralization? 15K annealing  very small neutral peaks for dicarbonyl and tricarbonyl (due to free Cu - centers) Higher annealing  loss of matrix Low intensity light  mono- and di-carbonyl neutralize first Full intensity light  complete neutralization 8

9 Photodetachment Dicarbonyl species first to photodetach Followed by monocarbonyl Tricarbonyl last to photodetach Trend follows gas phase values SpeciesEnergy (eV) Cu - 1.23 Cu(CO) 2 - 0.95 Cu(CO) 3 - 1.02 Stanzel, J.; Aziz, E. F.; Neeb, M.; Eberhardt, W. Collect. Czech. Chem. Commun. 2007, 72, 1-14. 9

10 Conclusions Formation and stabilization of anionic metal compounds is possible with counter-ion deposition Photodetachment leads to neutralization of anionic species Acknowledgements $$ NSF CHE-0955637 Lehigh University 10

11 0.5% CO Stoichiometry shifted to lower coordination Annealing No neutral peaks Broad feature anneals in Broad feature anneals out Irradiation Dicarbonyl grows in Sharp features arise from tricarbonyl 11

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