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Potential Docking Sites and Positions of Hydrogen in High-Pressure Silicates N.L. Ross, G.V. Gibbs Virginia Tech K.M. Rosso Pacific Northwest Laboratory.

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Presentation on theme: "Potential Docking Sites and Positions of Hydrogen in High-Pressure Silicates N.L. Ross, G.V. Gibbs Virginia Tech K.M. Rosso Pacific Northwest Laboratory."— Presentation transcript:

1 Potential Docking Sites and Positions of Hydrogen in High-Pressure Silicates N.L. Ross, G.V. Gibbs Virginia Tech K.M. Rosso Pacific Northwest Laboratory

2 Water in Minerals Trace amounts of water can have profound effects on physical properties of minerals. Nominally anhydrous mantle minerals can incorporate significant amounts of water (OH - ) in their structure. How is hydrogen incorporated into structures of mantle phases? Why do wadsleyite and ringwoodite dissolve wt% H 2 O in structures whereas no detectable OH - found in MgSiO 3 perovskite (Bolfan-Casanova et al. (2000)?

3 Propose a Strategy to... Predict docking sites for hydrogen on minerals Crystallographic orientation of O-H Apply to high-pressure silicates

4 Strategy Calculate topological bond critical point properties of electron density distribution, including... Laplacian, -  2  (r), and component curvatures of  (r), 1, 2, and 3 -  2  (r) =  2  (r)/  x 2 +  2  (r)/  y 2 +  2  (r)/  z 2 Mapping of -  2  (r) identifies (3,-3) critical points that correspond to local concentration of  and potenital proton docking positions Bader (1990)

5 Different Views of H 2 O H 1s 1 O 1s 2 2s 2 2p 4 Electron density (  ) and Laplacian (-  2  ) of H 2 O: Bader (1990) (3,-3) Critical Points Lone Pairs

6 Mapping of Valence Shell Charge Concentration ( -  2  (r)>0) for H 2 O Gibbs et al. (2001)

7 Hydrogen in Coesite (Gibbs et al. 2002, PCM) H avoids O1, bonds to O2,O3,O4 and O5 Very good agreement w/ Koch-Müller et al. (2001) IR study (see GV Gibbs, Session 5, Tues am)

8 Computational Details Electron density distributions for all phases calculated with CRYSTAL98 (Pisani, 1996;Saunders et al., 1998; Pisani et al., 2000) All-electron basis sets used: The topological analysis of the electron density and of its Laplacian scalar fields were analyzed using TOPOND.

9 Wadsleyite,  -Mg 2 SiO 4 & Ringwoodite,  -Mg 2 SiO 4 Abundant minerals in transition zone Can incorporate ~3 wt% H 2 O in structure (Smyth, 1987,1994; Gaspark, 1993;Inoue et al. 1995,1998;Kohlstedt et al., 1996;Kudoh et al., 1996,2000) IR spectra from Bolfan-Casanova et al. (2000)

10 H in wadselyite: Smyth (1987,1994)O1 Downs (1989)O2 Kudoh et al. (1996)O1..O1,O1…O3, O1..O4 Kohn et al. (2002)ordered on 4 sites, most O1 (<0.4wt% H 2 O); disordered,14-17 sites (0.8-1.5 wt% H 2 O)

11 H in ringwoodite Kudoh et al. (2000): O-O pairs around MgO 6 vacancies

12 (3,-3) Critical Points in Wadsleyite,  -Mg 2 SiO 4 O3O4 O1 O2

13 Potential Docking Sites and Positions of H in Wadsleyite (001 )

14 Wadsleyite Clusters around O1 and O2 O1-h1 [001] O2-h2 ~ [100]

15 Potential H Positions associated with Mg Vacancies (100) slice of wadselyite

16 (3,-3) Critical Points in Ringwoodite,  -Mg 2 SiO 4 O Compare with O3 and O4 in  -Mg 2 SiO 4 O3O4

17 Potential Docking Sites and Positions of H in Ringwoodite,  -Mg 2 SiO 4 (100)(110)

18 Potential H Positions associated with Mg Vacancies in Ringwoodite

19 Hydrogen in Stishovite O-H  [001] IR spectrum from Pawley et al. 1993

20 Potential Docking Sites and Positions of H in Stishovite O-H  [001] (see GV Gibbs Session 5 – Tues am)

21 MgSiO 3 ilmenite and perovskite No OH - detected in MgSiO 3 perovskite [Meade et al. (1994) observed 2 pleochroic OH peaks] Bolfan-Casanova et al. (2000, EPSL)

22 (3,-3) Critical Points in MgSiO 3 Ilmenite  CP’s along edges and face of MgO 6 octahedra: “Avoid” SiO 6 octahedra:

23 Two potential H sites in MgSiO 3 Ilmenite O-H  [001] w/in face of MgO 6 H w/in MgO 6 layers ~ along edges

24 (3,-3) Critical Points in MgSiO 3 Perovskite No CP’s on O1 and only 1 CP on O2! O2O1

25 Potential Docking Sites and Positions of H in MgSiO 3 Perovskite  Mg vacancy and O-H  [110] [Similar to location of H in San Benito Perovskite proposed by Beran et al. (1996) Can. Min. ]

26 CaSiO 3 Perovskite No (3,-3) Critical Points May be due to Si-O-Si=180 o To incorporate H, need Ca vacancy O-H not restricted to [100] c as MgSiO 3 pv

27 Summary

28 Conclusions Strategy based on mapping of -  2  and location of (3,-3) critical points provides a powerful technique for location of potential H sites in minerals. Future work includes introduction of trivalent cations, vacancies, etc. with H and see where H “docks”. Also let structure relax around proton sites.

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