Atomic Structure and Bonding at Oxide Surfaces Publications

  1. On the Relationship Between Surface Reconstructions and Step Edges on BaTiO3 (001)
    E. Morales, D. A. Bonnell  Surface Science  Volume: 609 Pages: 62-66 DOI: 10.1016/j.susc.2012.11.006    (2013)
  2. Atomic and Electronic Structure of the BaTiO3(001) (R5x R5)R26:6  Surface Reconstruction
    J. M. P. Martirez, E. H. Morales, W. A. Saidi, D. A. Bonnell, A. M. Rappe  Phys. Rev. Lett 109 (2012) 256802.
  3. High-Resolution Characterization of Defects in Oxide Thin Films
    M. P. Nikiforov, M. J. Brukman, D. A. Bonnell Applied Physics Letters 93 (2008) 182101
  4. Effect of Ferroelectric Polarization on the Adsorption and Reaction of Ethanol on BaTiO3
    M. H. Zhao, D. A. Bonnell, J. M. Vohs Surface Science 602 (2008) 2849-2855
  5. Direct In Situ Determination of the Polarization Dependence of Physisorption on Ferroelectric Surfaces
    D. B. Li, M. H. Zhao, J. Garra, et al. Nature Materials 7 (2008) 473-477
  6. Scanning Probe Microscopy of Oxide Surfaces: Atomic Structure and Properties
    D. A. Bonnell, J. Garra Reports on Progress in Physics 71 (2008) 044501
  7. Atomic Structure and Charge-Density Waves of Blue Bronze K0.3MoO3 (20(1)Over-Bar) By Variable-Temperature Scanning Tunneling Microscopy
    M. P. Nikiforov, A.F. Isakovic, D. A. Bonnell Phys Rev B 76 (2007) 033104
  8. Local Behavior of Complex Materials: Scanning Probes and Nano Structure
    Dawn A. Bonnell and Rui Shao Current Opinions in SolidState and Materials Science 7 (2003) 161-171
  9. Materials in Nanotechnology: New structures, new properties, new complexity
    Dawn A. Bonnell, J. Vac. Sci. and Technol. 21(2003) S194
  10. Optical Properties and Electronic Structure of Oxidized and Reduced Single Crystal SrTiO3.
    A. Frye, R. French, D. Bonnell Z. Metallkd 94 (2003) 226-232.
  11. Nanometer Scale Property Variation in CrOCN Thin Films.
    J.R. Smith, D.A. Bonnell J. American Ceramic Society 85 (2002) 2873-81.
  12. Scanning Probe Microscopy: Theory, Techniques, and Application.
    ed. D. A. Bonnell John Wiley & Sons New York (2000).
  13. Scanning Tunneling Microscopy: Theory, Techniques, and Application.
    ed. D. A. Bonnell VCH Publications New York (1993).
  14. Structure and Properties of Interfaces in Ceramics.
    (Symposium held November 28-December 2, 1994, Boston, Massachusetts.) [In: Mater. Res. Soc. Symp. Proc., 1995; 357]. Bonnell, Dawn; Ruehle, Manfred; Chowdhry, Uma; Editors.; USA. (1995), 468 pp. Publisher: (Mater. Res. Soc., Pittsburgh, Pa.)
  15. Determination of the TiO2(110) (2x3) Surface Structure via a Parametric Approach to STM Image Analysis.
    Jack Smith, D.A. Bonnell, Physical Review. (2000), 62(7), 4720-4725.
  16. Atomic Structure of Transition Metal Oxide Surfaces from Scanning Tunneling Microscopy.
    D. A. Bonnell Progress in Surface Science 57 (1998) 187-252.
  17. Local Structure and Properties of Oxide Surface: Scanning Probe Analyses.
    D. A. Bonnell J. Am. Ceramic Soc. 81 (1998) 3049-70.
  18. A New Reconstruction on TiO2 (110)
    M. Wagner, D. A. Bonnell, M. Rüfhle, Applied Physics A 66 (1998) 1165-70.
  19. Nonstoichiometry on TiO2 (110) and Cu-TiO2 Interfaces.
    M. Wagner, O. Kienzle, D. Bonnell, M. Rüfhle J. Vac. Sci. and Technol. A 16 (1998) 1078-84.
  20. Temperature Stability of Cu Thin Films on TiO2 (110).
    Carroll, M. Wagner, D. Bonnell, M. Rüfhle J. Mat. Res. 12 (1997) 975-983.
  21. Metal Oxide Interactions on Cu Segregated and Deposited TiO2 (001) Surfaces.
    P. Thibado, D. Bonnell J. Am. Ceramic Soc. 80 (1997) 1267.
  22. Effect of Variations in Stoichiometry on the Surface Structure of SrTiO3 (001).
    Y. Liang, D. Bonnell J. Am. Cer. Soc. 78 (1995) 2633-40.
  23. The Structure of Cu Clusters on SrTiO3 (001).
    Y. Liang, D. Bonnell Proceedings of the Materials Research Society Meeting. 357 (1995) 1-13.
  24. The Effect of Annealing on the Stoichiometry of SrTiO3 (001).
    Y. Liang, B. Rothman, D. Bonnell J. Vac. Sci. Tech. A 12 (1994) 2276-2280.
  25. Investigation of the Growth and Structure of Al Overlayers on TiO2 (001) by STM.
    D. Carroll, Y. Liang, D. Bonnell J. Vac. Sci. 12 (1994) 2298-2301.
  26. Experimental and Simulation of Tunneling Spectra of Polar ZnO Surfaces.
    P. Thibado, G. Rohrer, D. Bonnell Surface Science 318 (1994) 379-394.
  27. On the Use of Electron Tunneling to Probe Structure and Bonding at Oxide-Metal Interfaces.
    D. Bonnell, D. Carroll, Y. Liang Interface Science. 2, (1995) 365-377.
  28. Structure and Chemistry of the Annealed SrTiO3 (001).
    Y. Liang, D. Bonnell Surf. Sci. 310 (1994) 128-134.
  29. Surface Structure of Reduced SrTiO3 (001) Surfaces.
    Y. Liang, D. A. Bonnell Proceedings of the Materials Research Society Meeting (1993).
  30. STM Studies of Ultra Thin Overlayers of Cu on SrTiO3 (001).
    Y. Liang, D. Bonnell Proceedings of the Materials Research Society Meeting (1994).
  31. On the Use of Ion Scattering to Examine the Role of Hydrogen Reduction of TiO2.
    W. Wallace, Q. Zhong, R. Composto, D. Bonnell J. Mat. Res. 8 (1993) 1629-1634.
  32. Local Structure of Defects on Hydrogen and Vacuum Reduced TiO2.
    Q. Zhong, J. Vohs, D. A. Bonnell J. Am. Ceram. Soc. 76 (1993) 1137-1142.
  33. Local Structure of Defects on the Surfaces of Nonstoichiometric Oxides by STM and STS.
    D. Bonnell, Q. Zhong, Y. Liang Microbeam Analysis Journal 2 (1993) 91-96.
  34. Atomic Structures of Reduced SrTiO3 (001).
    Y. Liang, D. A. Bonnell Surf. Sci. 285 (1993) L510-516.
  35. Effect of reduction on the topographic and electronic structure of titania (110) surfaces.
    G. S. Rohrer, V. Henrich, D. A. Bonnell Surf. Sci. 274 (1992) 35-43.
  36. Structure of the Reduced TiO2(110) Surface Determined by STM.
    G. S. Rohrer, V. Henrich, D. A. Bonnell Science 250 (1991) 1230-1241.
  37. Structure of the ZnO(0001) Surface Determined by STM.
    G. S. Rohrer, D. A. Bonnell Surface Science, 247 (1991) L195-L200.
  38. Metal Oxide Interactions on Cu Segregated and Deposited TiO2 (001) Surfaces.
    P. Thibado, D. Bonnell J. Am. Ceramic Soc. 80 (1997) 1267.
  39. Cross Sectional Scanning Tunneling Spectroscopy of Cleaved Si based in MOS Junctions.
    P. Thibado, T. Mercer, S. Fu, J. Dinardo, T. Egami, D. Bonnell J. Vac. Sci. and Tech. B 14(1996) 1607.
  40. Experimental and Simulation of Tunneling Spectra of Polar ZnO Surfaces.
    P. Thibado, G. Rohrer, D. Bonnell Surface Science 318 (1994) 379-394.
  41. Electronic structure of defects on reduced TiO2 (rutile) surfaces.
    Zhong, Qian; Vohs, John M.; Bonnell, Dawn A. Mater. Res. Soc. Symp. Proc. (1992), 237 (Interface Dynamics and Growth), 453-8.
  42. A scanning tunneling microscopy and spectroscopy study of the titanium oxide (TiO2-x)(110) surface.
    Rohrer, Gregory S.; Henrich, Victor E.; Bonnell, Dawn A.. Surf. Sci. (1992),278(1-2), 146-56.
  43. A scanning tunneling microscopy study of the reduced titania(110) surface.
    Rohrer, Gregory S.; Henrich, Victor E.; Bonnell, Dawn A. Mater. Res. Soc. Symp. Proc. (1991), 209(Defects Mater.), 611-16.
  44. A scanning tunneling microscopy study of single crystal zinc oxide and titanium dioxide surfaces.
    Rohrer, Gregory S.; Bonnell, Dawn A.. NIST Spec. Publ. (1991), 804(Chem. Electron. Ceram. Mater.),  447-54.
  45. Probing the surface chemistry of polycrystalline zinc oxide with scanning tunneling microscopy and tunneling spectroscopy.
    Rohrer, Gregory S.; Bonnell, Dawn A. J. Vac. Sci. Technol. B  (1991), 9(2, Pt. 2), 783-8
  46. Some theoretical and experimental considerations in scanning tunneling microscopy of ceramic materials.
    Bonnell, Dawn A. Ceram. Trans. (1990), 5(Adv. Charact. Tech. Ceram.), 315-26.
  47. Characterization of carbides by scanning tunneling microscopy.
    Bonnell, Dawn A. Mater. Sci. Eng. A (1988), A105-106 55-63.
  48. Scanning tunneling microscopy and spectroscopy of ceramics: silicon carbide and zinc oxide.
    Bonnell, Dawn A.; Clarke, David R. J. Am. Ceram. Soc (1988), 71(8), 629-37.