Identification of phases, symmetries and defects through local crystallography

Advances in electron and probe microscopies allow 10 pm or higher precision in measurements of atomic positions. This level of fidelity is sufficient to correlate the length (and hence energy) of bonds, as well as bond angles to functional properties of materials. Traditionally, this relied on mapping locally measured parameters to macroscopic variables, for example, average unit cell. This description effectively ignores the information contained in the microscopic degrees of freedom available in a high-resolution image. Here we introduce an approach for local analysis of material structure based on statistical analysis of individual atomic neighbourhoods. Clustering and multivariate algorithms such as principal component analysis explore the connectivity of lattice and bond structure, as well as identify minute structural distortions, thus allowing for chemical description and identification of phases. This analysis lays the framework for building image genomes and structure–property libraries, based on conjoining structural and spectral realms through local atomic behaviour.

[1]  M. Wuttig,et al.  Giant nonhysteretic responses of two-phase nanostructured alloys. , 2011, Physical review letters.

[2]  Sergei V. Kalinin,et al.  Big data and deep data in scanning and electron microscopies: deriving functionality from multidimensional data sets , 2015, Advanced Structural and Chemical Imaging.

[3]  Ian McNulty,et al.  Quantitative nanoscale imaging of lattice distortions in epitaxial semiconductor heterostructures using nanofocused X-ray Bragg projection ptychography. , 2012, Nano letters.

[4]  Andrew L. Goodwin,et al.  The crystallography of correlated disorder , 2015, Nature.

[5]  D. Alexander,et al.  Mapping chemical and bonding information using multivariate analysis of electron energy-loss spectrum images. , 2006, Ultramicroscopy.

[6]  Yi Zhang,et al.  Spontaneous vortex nanodomain arrays at ferroelectric heterointerfaces. , 2011, Nano letters.

[7]  J. Millet,et al.  Synthesis and Monitoring of MoVSbNbO Oxidation Catalysts Using V K and Sb L1-Edge Xanes Spectroscopy , 2011 .

[8]  Alexei Belianinov,et al.  Better Catalysts through Microscopy: Mesoscale M1/M2 Intergrowth in Molybdenum-Vanadium Based Complex Oxide Catalysts for Propane Ammoxidation. , 2015, ACS nano.

[9]  Stephen Jesse,et al.  Principal component and spatial correlation analysis of spectroscopic-imaging data in scanning probe microscopy , 2009, Nanotechnology.

[10]  P. Lu,et al.  Structural Mapping of Disordered Materials by Nanobeam Diffraction Imaging and Multivariate Statistical Analysis , 2013, Microscopy and Microanalysis.

[11]  Brian C. Sales,et al.  Atomically resolved spectroscopic study of Sr2IrO4: Experiment and theory , 2013, Scientific Reports.

[12]  B. E. Vugmeister,et al.  Polarization dynamics and formation of polar nanoregions in relaxor ferroelectrics , 2006 .

[13]  Lewys Jones,et al.  Identifying and Correcting Scan Noise and Drift in the Scanning Transmission Electron Microscope , 2013, Microscopy and Microanalysis.

[14]  W. Ueda,et al.  Comparative Study on the Catalytic Performance of Single-Phase Mo−V−O-Based Metal Oxide Catalysts in Propane Ammoxidation to Acrylonitrile , 2006 .

[15]  Peter Hawkes,et al.  Advances in Imaging and Electron Physics , 2002 .

[16]  Heinrich Rohrer,et al.  7 × 7 Reconstruction on Si(111) Resolved in Real Space , 1983 .

[17]  Hamers,et al.  Surface electronic structure of Si(111)-(7x7) resolved in real space. , 1986, Physical review letters.

[18]  Vadim V. Guliants,et al.  Recent developments in catalysis using nanostructured materials , 2009 .

[19]  J. Holmberg,et al.  Catalytic behaviour of M1, M2, and M1/M2 physical mixtures of the Mo-V-Nb-Te-oxide system in propane and propene ammoxidation , 2004 .

[20]  Marin Alexe,et al.  Atomic-scale study of electric dipoles near charged and uncharged domain walls in ferroelectric films. , 2008, Nature materials.

[21]  Weidong Luo,et al.  Atomic-scale compensation phenomena at polar interfaces. , 2010, Physical review letters.

[22]  J. Yates,et al.  Gold-adatom-mediated bonding in self-assembled short-chain alkanethiolate species on the Au(111) surface. , 2006, Physical review letters.

[23]  J. Bell,et al.  Experiment and Theory , 1968 .

[24]  Zheng Gai,et al.  Chemically induced Jahn–Teller ordering on manganite surfaces , 2014, Nature Communications.

[25]  P. Nellist,et al.  Rapid estimation of catalyst nanoparticle morphology and atomic-coordination by high-resolution Z-contrast electron microscopy. , 2014, Nano letters.

[26]  Michael Faley,et al.  Oxygen octahedron reconstruction in the SrTiO 3 /LaAlO 3 heterointerfaces investigated using aberration-corrected ultrahigh-resolution transmission electron microscopy , 2009 .

[27]  N. Bonnet,et al.  Multivariate statistical methods for the analysis of microscope image series: applications in materials science , 1998 .

[28]  Ye Xu,et al.  A combined HAADF STEM and density functional theory study of tantalum and niobium locations in the Mo–V–Te–Ta(Nb)–O M1 phases , 2012 .

[29]  Sergei V. Kalinin,et al.  Mapping octahedral tilts and polarization across a domain wall in BiFeO3 from Z-contrast scanning transmission electron microscopy image atomic column shape analysis. , 2010, ACS nano.

[30]  Elbio Dagotto,et al.  Complexity in Strongly Correlated Electronic Systems , 2005, Science.

[31]  Surface electronic structure of Si(111)-(7x7) resolved in real space. , 1986 .

[32]  Wenbin Wang Scanning Tunneling Microscopy , 2009 .

[33]  Stephen J. Pennycook,et al.  Scanning transmission electron microscopy : imaging and analysis , 2011 .

[34]  M. Chi,et al.  Point defect characterization in HAADF-STEM images using multivariate statistical analysis. , 2011, Ultramicroscopy.

[35]  Manfred von Ardenne,et al.  Das Elektronen-Rastermikroskop , 1938 .

[36]  A V Crewe,et al.  Scanning Electron Microscopes: Is High Resolution Possible? , 1966, Science.

[37]  I. Reaney,et al.  Review of crystal and domain structures in the PbZrxTi1−xO3 solid solution , 2005 .

[38]  Takashi Hotta,et al.  Colossal Magnetoresistant Materials: The Key Role of Phase Separation , 2000, cond-mat/0012117.

[39]  Sergei V. Kalinin,et al.  Atomically Resolved Mapping of Polarization and Electric Fields Across Ferroelectric/Oxide Interfaces by Z‐contrast Imaging , 2011, Advanced materials.

[40]  Sergei V. Kalinin,et al.  Probing oxygen vacancy concentration and homogeneity in solid-oxide fuel-cell cathode materials on the subunit-cell level. , 2012, Nature materials.