Multifunctional electronic complex oxides with coexisting properties such as polarization, magnetization, and strain states are attracting significant.

Slides:

Advertisements

Similar presentations

Bandgap Engineering of UV-Luminescent Nanomaterials Leah Bergman, University of Idaho, DMR CAREER One of the main advantages of a nanomaterial.

Advertisements

2012 Transfer-to-Excellence Research Experiences for Undergraduates Program (TTE REU) Characterization of layered gallium telluride (GaTe) Omotayo O Olukoya.

For the first time, Raman spectroscopic imaging has been performed to map structural changes across a ferroelectric domain wall in the technologically.

Thickness (nm) Wavelength (nm) Tunable asymmetric reflectance in percolating silver films Miriam Deutsch, University of Oregon,

Mesoscopic phase modulations in complex materials Sang-W Cheong, Rutgers University NSF-DMR Intriguing cross-coupling phenomena in multiferroics.

Dielectric and Piezoelectric Properties of Epitaxial Ferroelectric Bilayers Alexei Y. Grigoriev, University of Tulsa, DMR Thermodynamic theory.

National Science Foundation Developing Oxides for Solar Energy Conversion Steven May, Drexel University, DMR Outcome: Researchers at Drexel University.

Magnetoelastic Coupling and Domain Reconstruction in La 0.7 Sr 0.3 MnO 3 Thin Films Epitaxially Grown on SrTiO 3 D. A. Mota IFIMUP and IN-Institute of.

Materials World Network: Self-assembled Nanocomposite Magnetoelectric Thin Films Nian Sun, Northeastern University, DMR Intellectual Merit:Fig.

When and why are ultrathin films of metallic oxides not metallic? Jiandi Zhang, Louisiana State University & Agricultural and Mechanical College, DMR

Kansas State University III-Nitride Deep Ultraviolet Photonic Materials and Structures Jingyu Lin & Hongxing Jiang DMR Growth of III-nitride Photonic.

The study of ferroelectric switching using x-ray synchrotron radiation

National Science Foundation Materials World Network-- Ultrafast Switching of Phase Change Materials: Combined Nanosecond and Nanometer Exploration Bryan.

12th International Workshop on Piezoresponse Force Microscopy (PFM): Theory, Techniques, and Applications Achievement Significance Details Multiple breakthroughs.

Magnetic domain characterization  Lorentz transmission electron microscopy (LTEM) imaging techniques are used to image the magnetic domain structure of.

Strong spin-phonon coupling is responsible for a wide range of scientifically rich and technologically important phenomena—including multiferroic properties,

Improving ZnO for Use in Ultraviolet Light Emission and Sensor Applications Larry Halliburton, West Virginia University, DMR Zinc oxide (ZnO) is.

CAREER: The Evolution of Polar Nanoregions and Its Coupling with Cation-Ordered Domains in Pb(B'B'')O 3 Relaxor Ferroelectrics Xiaoli Tan (Iowa State University),

Electro-Optic Studies of Charge Density Wave Conductors Joseph W. Brill, University of Kentucky, DMR One-dimensional charge-density-wave (CDW)

“Electron dynamics in organic semiconductors and at organic metal interfaces” Xiaoyang Zhu, University of Minnesota, NSF DMR March 1 st,

Interfacial Characteristics of Semi fluorinated Polymers Dvora Perahia (Clemson University) DMR Thin layers of semifluorinated and fluorinated.

Multiferroic Thin Films Nanoscience Symposium 2006 June 15 By: Arramel RuGRuG.

Complex Epitaxial Oxides: Synthesis and Scanning Probe Microscopy Goutam Sheet, 1 Udai Raj Singh, 2 Anjan K. Gupta, 2 Ho Won Jang, 3 Chang-Beom Eom 3 and.

National Science Foundation Enhanced Pyroelectric and Electrocaloric Effects in Complex Oxide Thin Film Heterostructures Lane W. Martin, University of.

Fabrication of (Fe,Zn) 3 O 4 -BiFeO 3 nano-pillar structure by self- assembled growth Tanaka Laboratory Takuya Sakamoto.

This Materials World Network collaborative program brings researchers (Alford and Mayer) from Arizona State University (ASU) and (D. Adams and N. Tile)

Photon2 Internship PENN STATE UNIVERSITY Materials Research Lab June 2005 Paul Longwell.

University of Wisconsin-Madison Department of Materials Science and Engineering Opportunities for Coherent Scattering in Ferroelectrics and Multiferroics.

National Science Foundation Outcome: Unique vertical aligned nanocomposite thin films with multifunctionalities Impact: Highly strained and ordered nanostructured.

Collaborative Research: Analysis of Defects and Their Causes in Bulk Aluminum Nitride Crystals – Jharna Chaudhuri, Texas Tech University, Lubbock, TX DMR

Spin polarization with a twist Nancy P. Sandler, Ohio University, DMR MWN/CIAM COLLABORATION USA-Brazil-Chile A well-known relativistic effect,

National Science Foundation Disorder Makes Materials Slower Paul G. Evans, University of Wisconsin-Madison, DMR Explanation: Electronic materials.

Structure-Function-Property Relationships in Charged Conjugated Polymers (CCPs) Thuc-Quyen Nguyen DMR  The aim of this project is to understand.

Role of Glass Composition in Waveguide Fabrication with Femtosecond Laser Pulses Denise Krol, University of California, Davis, DMR Tightly focused.

Effect of Thermal Quench on Ferroelectric Domain Structures in Two-Dimensional Polymers Xia Hong, University of Nebraska-Lincoln, DMR Understanding.

István Kézsmárki Budapest University of Technology Giant Directional Optical Anisotropies in the THz regime Spinwave Excitations in Multiferroics Collegues.

Direct visualization of nanoscale structural domains in complex sulfide glasses Sabyasachi Sen (University of California at Davis), DMR The existence.

National Science Foundation GOALI: Epitaxial Growth of Perovskite Films and Heterostructures by Atomic Layer Deposition and Molecular Beam Epitaxy John.

Self-Assembled Nanoparticle Array for Spintronics and High Frequency Materials DMR PI: Hao Zeng W.L. Shi, Y. Sahoo and Hao Zeng, et al., “Anisotropic.

Correlating Anomalous Viscosity of Polymer Films and Their Interfacial Dynamics by the Two-layer Model Ophelia Tsui, Trustees of Boston University, DMR.

DMR : Carrier and Spin Dynamics in InSb- and InMnSbBased Heterostructures, PI: Giti Khodaparast, Physics Department, Virginia Tech.,,  The goal.

Ferroelectric Nanolithography Extended to Flexible Substrates Dawn A. Bonnell, University of Pennsylvania, DMR Recent advances in materials synthesis.

Example: Magnetic field control of the conducting and orbital phases of layered ruthenates, J. Karpus et al., Phys. Rev. Lett. 93, (2004)  Used.

Electrooptic Materials Based On Molecular Compasses And Gyroscopes: Effects Of Symmetry, Conjugation, And Correlated Dipolar Rotation Miguel A. Garcia-Garibay,

Negative Capacitance Devices to Enable Low- Voltage/Low-Power Switching In Electronic Devices John G. Ekerdt, University of Texas at Austin, DMR

Photoinduced phase-separation in Bi 0.4 Ca 0.6 MnO 3 thin films Vera Smolyaninova DMR Doped rare-earth manganese oxides (manganites) exhibit a.

New Applications of Strongly Correlated Materials James K. Freericks, Georgetown University, DMR Strongly correlated materials are materials in.

LCMO layered Noise Studies of Disordered Condensed Matter M. B. Weissman, UIUC, DMR Colossal Magnetoresistive (CMR) materials have inspired interest.

Frustrated magnets exhibit novel and useful properties, including dramatic field-sensitive properties and suppressed magnetic ordering temperatures. To.

Exploiting geometry to generate anisotropic interactions at the nanoscale and self-assembly of living clusters Angelo Cacciuto, Columbia University, DMR.

Exploring the effect of uniaxial strain in Ba(Fe 1-x Co x ) 2 As 2 Stephen D. Wilson, Boston College, DMR Physical Review Letters 108, (2012).

Spectroscopy with a Twist Infrared magneto-polarization measurements John Cerne, University at Buffalo, SUNY, DMR Hall conductivity in the high.

From quasi-2D metal with ferromagnetic bilayers to Mott insulator with G-type antiferromagnetic order in Ca 3 (Ru 1−x Ti x ) 2 O 7 Zhiqiang Mao, Tulane.

Doped rare-earth manganese oxides (manganites) exhibit a wide variety of physical phenomena due to complex interplay of electronic, magnetic, orbital,

Kinetics of Structural Transformations in Metal and Ceramic Systems Microstructure in Decomposition of Metastable Ceramic Materials Armen G Khachaturyan,

Developing Nanostructured Inorganic-Organic Hybrid Semiconductors Jing Li, Rutgers University, DMR Activities and Findings Developed the FIRST.

The fabric, or the microscopic structure, of unconventional superconductivity in heavy-fermion materials continues to elude our complete understanding.

Tuning magnetic anisotropy in (001) oriented L1 0 (Fe 1-x Cu x ) 55 Pt 45 films Kai Liu, University of California-Davis, DMR Meeting the demand.

National Science Foundation Outcome: Researchers at the University of Florida have directly measured the mechanism that creates frequency-dependent material.

Recently a surface spin valve effect was observed within a few atomic layers at the ferromagnet/normal (F/N) interface. This is due to the fact that the.

Conclusion Room- temperature ferrimagnet with large magnetism P. S. Wang, H. J. Xiang* Key Laboratory of Computational Physical Sciences (Ministry of Education),

ZnO and Mg x Zn 1-x O are technologically promising materials for luminescence applications in the ultraviolet (UV) range. ZnO has a bandgap ~3.3 eV, while.

National Science Foundation Outcome: Unique vertical aligned nanocomposite thin films with multifunctionalities Impact: Highly strained and ordered nanostructured.

National Science Foundation Outcome: Unique vertical aligned nanocomposite thin films with multifunctionalities Impact: Highly strained and ordered nanostructured.

Multiferroics as Data Storage Elements

The defect is the device: (A) An atomic-resolution scanning transmission electron microscopy (STEM) image of a 109° domain wall in the multiferroic BiFeO3.

Through the Looking Glass at the Atomic Scale

Fig. 1 Schematics of the experiment.

Revealing Hidden Phases in Materials

Fig. 1 Structural and electrical properties of Bi2Se3/BaFe12O19.

Presentation transcript:

Multifunctional electronic complex oxides with coexisting properties such as polarization, magnetization, and strain states are attracting significant interest due to the possibility of a rich array of coupled phenomena that allow tuning of these properties, or even inducing new properties with electric field, magnetic field or strain. Recent work by our collaborator (J.H. Haeni, D. G. Schlom et al., Nature 430, 758 (2004)) has shown that SrTiO 3 which is not a ferroelectric in bulk form, can be made ferroelectric by strained growth in thin film form. We have made further key advances: First direct imaging of ferroelectric domains (Fig. (a)) and domain switching under electric fields (Fig. (b)) in strained SrTiO 3 by Piezoelectric Force Microscopy. Comparison with phase-field simulations (Fig. (c) and (d)) indicates 90  domain wall motion. (Y. L. Li, et al. Phys. Rev. B, 73, (2006); A. Vasudevarao et al., Phys. Rev. B., accepted (2006)). First probing of multiferroicity: Strain not only induces ferroelectricity, but also induces multiferroicity, that is, the coexistence of both ferroelectric and ferroelastic domains in SrTiO 3. Unlike other ferroelectrics, the ferroelectric polarization (p, which is a polar property) and antiferroelastic rotation of oxygen cages (denoted by q, which is an axial property) are independent, and give rise to two transitions (Fig. (e) measured using nonlinear optical probing). Significance: From a symmetry perspective, strained SrTiO 3 has striking resemblance to multiferroics such as BiFeO 3 that exhibit coexistence of ferroelectricity (p) and antiferromagnetism (q), that may allow electric control of magnetism. By dynamically straining complex oxides, new properties can be induced and tuned in materials, leading to a vast array of tunable ferroelectric, piezoelectric, pyroelectric, and optical devices. Strain Induced Multifunctionality in Complex Oxides Venkatraman Gopalan, Pennsylvania State University, DMR (a) (b) Antiferrodistortive transition Ferroelectric transition p p (c)(d) E= 1kV/mm (e) 10  m

The Science and Technology of Light: Douglass Science Camp for High School Girls: A workshop (panels (a)-(d)) was organized by Gopalan, at Rutgers university in March 2006 (In conjunction with Prof. Darrell Schlom (PI, NSF-NIRT)). 48 of the top high school girls interested in science from across New Jersey attended this one day event. Gopalan conducted the workshop for 6 groups of 8 girls each. The response was enormously positive. See Art from an attendee (right panel (b)): “I Love Science”. The scribble relates to the measurement we made that the velocity of light in a glass fiber was 1.5 times slower than in air. The refractive index of glass was therefore deduced to be 1.5. Women in Science and Engineering (WISE) High School Girls Camp at Penn State: This event was held in June 2006, and presented the above-mentioned optical voice link module to visiting high school girls. Two graduate students from Gopalan group, Eftihia Vlahos and Lili Tian conducted this workshop. Two high school teachers in Pennsylvania, Paul Longwell from Hollidaysburg, PA (see panel (e)), working with graduate student, Lili Tian on electro-optic measurements) and Wendy McCoullough from State College, PA spent time in Gopalan group in summer (2005) to develop teaching curricula in optics and lasers to take back to their classes in Fall. Faculty from Undergraduate Institution : David McGee from Drew University spent time in PIs lab (July 2006), learning prism coupling in optical waveguides. The PIs group shared the home- built design of the coupler with David, who is reproducing it in Drew University for purposes of undergraduate education and research. The Science and Technology of Light: Workshop for High School Girls Venkatraman Gopalan, Pennsylvania State University, DMR (a) (b) (c) (e) (d)