Superconductivity and magnetism in organic materials Russell W. Giannetta, University of Illinois at Urbana-Champaign, DMR 0503882 Our goal is to uncover.

Slides:

Advertisements

Similar presentations

Amorphous States of Phase Change Materials: Effects of Cooling Rate and Composition Stephen G. Bishop, University of Illinois at Urbana-Champaign, DMR.

Advertisements

New World Record for Superconducting Coil Performance PI: Gregory S. Boebinger, Director National High Magnetic Field Laboratory Supported by NSF (No.

High Temperature Copper Oxide Superconductors: Properties, Theory and Applications in Society Presented by Thomas Hines in partial fulfillment of Physics.

Stringing together the quantum phases of matter Talk online: sachdev.physics.harvard.edu Talk online: sachdev.physics.harvard.edu.

CHAPTER 4 Heat and Temperature.

Mott Transition, i.e., the interaction-driven metal-to- insulator transition (MIT), is a fundamental issue in the physics of strongly correlated electron.

Strands of DNA have been used as tiny scaffolds to create superconducting nanodevices that demonstrate a new quantum interference phenomenon. These nanowire.

T, K NBO BO4 Pressure effects on borosilicate glass structure Jonathan F. Stebbins, Stanford University, DMR

Matter – Properties and Change

A image of the flux line lattice in the magnetic superconductor TmNi2B2C The hexagonal arrangement of magnetic flux lines in pure Nb imaged using neutrons.

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

Two Particle Response in Cluster Dynamical Mean Field Theory Rosemary F. Wyse, Aspen Center for Physics, PHY/DMR Dynamical Mean Field Theory is.

Reduced magnetic moment of the 3.86 µm thick In sample in perpendicular field, H ci is the critical field of the transition from the intermediate to the.

1 Superconductivity  pure metal metal with impurities 0.1 K Electrical resistance  is a material constant (isotopic shift of the critical temperature)

Below a temperature of  256 o C (17 K), a novel state of matter is realized in the material URu 2 Si 2. Understanding this state is not only an intellectual.

Thermal Stabilization and Mechanical Properties of nc Fe-Ni-Cr Alloys Ronald O. Scattergood, North Carolina State University, DMR A study was completed.

MgB2 Since 1973 the limiting transition temperature in conventional alloys and metals was 23K, first set by Nb3Ge, and then equaled by an Y-Pd-B-C compound.

Insert Figure 1 approximately here. Bismuth nanowires or bismuth nanotubes? -Bismuth nanowires are a vehicle for the study of size- dependent electronic.

M.T. Bell et al., Quantum Superinductor with Tunable Non-Linearity, Phys. Rev. Lett. 109, (2012). Many Josephson circuits intended for quantum computing.

Magnetization divided by magnetic field vs. temperature T for SmFe 2 Zn 20, SmCo 2 Zn 20, SmRu 2 Zn 20, SmNi 2 Cd 20, and SmPd 2 Cd 20. Inset: low temperature.

Broken symmetries in bulk condensed matter systems have implications for the spectrum of Fermionic excitations bound to surfaces and topological defects.The.

Graphene at High Magnetic Fields I kyky E kxkx Recently, a new form of carbon has become a laboratory for new physics: a single sheet of graphite, known.

CHEMISTRY Matter and Change

States of Matter and Phase Changes Kinetic theory of matter.

Nanoscale Self-Organization of Metallic Alloys under Ion Irradiation Robert Averback and Pascal Bellon, University of Illinois, MET DMR Award#

Constant Book Definition In your own words… Picture Something in an experiment that does not change.

A magnetically-controlled superconducting switch Norman Birge, Michigan State University, DMR The interplay between superconductivity and ferromagnetism.

Michael Browne 11/26/2007.

Matter and Change Chapter 1. Objectives Define Chemistry Define properties of matter.

Matter and Change Chapter 3. Matter Everything around us Everything around us Can be substances Can be substances (pure) by definition, with uniform and.

Materials Learning Objectives. Lesson 1 1.Understand that there is a huge variety of materials 2.Understand that there is a small number of elements from.

Define physical change and list several common physical changes.

High-pressure study on the crystal structure and the spin-state of Ni ions in the triple-layer T′-La 4 Ni 3 O 8 John B. Goodenough, University of Texas.

J.P. Eisenstein, Caltech, DMR When two layers of electrons are brought close together in the presence of an intense magnetic field a new state.

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

Anomalous correlated electron phenomena in Yb 2 Fe 12 P 7 M. Brian Maple, University of California-San Diego, DMR Temperature – magnetic field.

Competing Orders, Quantum Criticality, Pseudogap & Magnetic Field-Induced Quantum Fluctuations in Cuprate Superconductors Nai-Chang Yeh, California Institute.

Metal-Insulator Transition via Spatially Heterogeneous State Jongsoo Yoon, University of Virginia, DMR Differential resistance (dV/dI) of a 5nm.

Correlated Electron State in Ce 1-x Yb x CoIn 5 Stabilized by Cooperative Valence Fluctuations Brian M. Maple, University of California, San Diego, DMR.

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

Fe As A = Ca, Sr, Ba Superconductivity in system AFe 2 (As 1-x P x ) 2 Dulguun Tsendsuren Kitaoka Lab. Division of Frontier Materials Sc. Department of.

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

The iron-pnictide/chalcogenide (Fe-Pn/Ch) compounds have attracted intense interest recently, largely due to the observation of high-temperature superconductivity.

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

From Local Moment to Mixed-Valence Regime in Ce 1−x Yb x CoIn 5 alloys Carmen Almasan, Kent State University, DMR Ce 1−x Yb x CoIn 5 alloys have.

Superconductivity. Work on Worksheets. Superconductivity Lecture

Spin-orbital effects in frustrated antiferromagnets Oleg A. Starykh, University of Utah, DMR Electron spin resonance (ESR) measures absorption.

Spatially resolved quasiparticle tunneling spectroscopic studies of cuprate and iron-based high-temperature superconductors Nai-Chang Yeh, California Institute.

Physics Department, Technion, Israel Meni Shay, Ort Braude College, Israel and Physics Department, Technion, Israel Phys. Rev. B.

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.

Quantum Criticality in Magnetic Single-Electron Transistors T p Physics of non-Fermi-liquid Metals Qimiao Si, Rice University, DMR Quantum criticality.

Rare earth substitutions in the heavy-fermion superconductor CeCoIn 5 M. Brian Maple, University of California, San Diego, DMR Single crystal of.

How are Liquid Crystals like Superconductors? Charles Rosenblatt, Case Western Reserve University, DMR Many seemingly different phase transitions.

Nuclear magnetic resonance study of organic metals Russell W. Giannetta, University of Illinois at Urbana-Champaign, DMR Our lab uses nuclear magnetic.

Non-Fermi liquid behavior with and without quantum criticality in Ce 1−x Yb x CoIn 5 Carmen C. Almasan, Kent State University, DMR One of the greatest.

Gregory Gabadadze (NYU, CCPP) with R. A. Rosen, JCAP, JHEP 08,09 D. Pirtskhalava, JCAP 09.

High temperature superconductivity…a bad case of stripes?

Chemistry- Matter and change HONORS CHEMISTRY CHAPTERS

Properties of Matter GPS 3.

Superconductivity and Superfluidity The Microscopic Origins of Superconductivity The story so far -what do we know about superconductors?: (i) Superconductors.

TOPIC 0A: Chemistry, Scientific Method and Chemical & Physical Change

PROPERTIES AND CHANGES OF MATTER

Evidence for fully gapped superconductivity from microwave penetration depth measurements in PrFeAsO1-y single crystals K. Hashimoto1, T. Shibauchi1,

Scientific Achievement

The Nature of Matter.

CHAPTER 3 Matter and Change.

Ch. 2 Matter & Change.

Chapter 3: States of Matter Section 1: Matter & Energy

第２７回応用物理学科セミナー日時： 10月2５日（火） 16:０0 – 17:３0 場所：葛飾キャンパス研究棟８Ｆ第１セミナー室

Presentation transcript:

Superconductivity and magnetism in organic materials Russell W. Giannetta, University of Illinois at Urbana-Champaign, DMR Our goal is to uncover the connections between magnetism and superconductivity. We study organic superconductors, based on the BEDT-TTF molecule as shown. These materials separate into magnetic and superconducting phases as we vary the cooing rate. The thermal properties of the superconducting phase are determined by its excited states, known as quasiparticles. By carefully measuring how far a magnetic field penetrates into the crystal we can study how the quasiparticle population grows with temperature. In the plot, the time to cool the crystal varies from 20 sec to 3 weeks. This changes the relative amount of magnetic and superconducting material by a factor of 30. Nonetheless, each of the curves shown obeys a T 3/2 power law. This implies that the quasiparticle energy spectrum is “robust”. This same robustness is observed in the high temperature copper oxides, despite an entirely different chemical composition and a factor of 10 higher transition temperature. The T 3/2 power law that we observe in all experiments suggests that the quasiparticles in organic superconductors behave unlike anything predicted by the BCS theory of superconductivity. H S C S C S C S H C C Structure of BEDT-TTF molecule. Change of London penetration depth of BEDT-TTF superconductor versus T 3/2. Curves shown vary in cooling time from 20 (bottom curve ) sec to 3 weeks (top curve). All obey the same power law.

Superconductivity and magnetism in organic materials Russell W. Giannetta (University of Illinois at Urbana-Champaign) DMR Broader Impact Understanding the connection between magnetism and superconductivity is a central goal of condensed matter physics. Organic materials hold the promise of controlling these two phenomena by chemical means. Education, outreach, collaborations Graduate students T.Olheiser and N. Salovich are involved in penetration depth experiments, along with undergrads Will Maulbetsch and Matthew Feickert. We are collaborating with C.P. Slichter (UIUC) to do NMR measurements on the organics. Slichter’s group produced the earliest evidence for unconventional superconductivity in these materials. Graduate students Tak-Kei Lui, Mike Murray and Joe Gezo, as well as undergrads Alex Ford and Nate Burdick are continuing this work. Organic superconductor crystals were obtained in a collaboration with P. Tea (UIUC-chemistry dept.) and J. Schleuter (Argonne Labs). Giannetta is also collaborating with former postdocs R. Prozorov (Ames Lab, ISU) and A. Carrington (U. Bristol) to write a book on penetration depth measurements in superconductors. NMR spin-lattice relaxation times of organic and copper oxide superconductors, showing close similarity. Neither material obeys the BCS prediction. [S.M.deSoto, C.P. Slichter, Phys. Rev. B 52, (1995)] 13 C NMR spectrum of organic superconductor recently obtained by Tak-Kei Lui.