Jorge Quintanilla, "Broken Time-Reversal Symmetry and Topological Order in Triplet Superconductors" - Research seminar, Max Planck Institute for the Physics of Complex Systems (Dresden), 27 November 2014
Abstract:
The concept of broken symmetry is one of the cornerstones of modern physics, for which
superconductors stand out as a major paradigm. In conventional superconductors electrons form
isotropic singlet pairs that then condense into a coherent state, similar to that of photons in a laser.
We understand this in terms of the breaking of global gauge symmetry, which is the invariance of a
system under changes to the overall phase of its wave function. In unconventional superconductors,
however, more complex forms of pairing are possible, leading to additional broken symmetries and
even to topological forms of order that fall outside the broken-symmetry paradigm.
In this talk I will discuss such phenomena, making emphasis on triplet pairing and the spontaneous
breaking of time-reversal symmetry in some superconductors. I will pay particular attention to
large-facility experiments using muons to detect tiny magnetic fields inside superconducting
samples and group-theoretical arguments that enable us to constrain the type of pairing present in
the light of such experiments. I will also address the possibility of mixed singlet-triplet pairing
without broken time-reversal symmetry in superconductors whose crystal lattices lack a centre of
inversion, and predict bulk experimental signatures of topological transitions expected to occur in
such systems.
Introduction.
Superconductivity.
Meissner effect.
Flux Quantization.
Types of Superconductors.
London Equations.
BCS Theory.
London Penetration Depth
Applications of Super conductors.
This presentation contains various aspects of Graphene like synthesis techniques, characterization, commercialization, mechanical and electrical properties and present and future application.
Basics of Band Structure and semiconductors.pdfDr Biplab Bag
Basics of Band Structure and semiconductors: How the energy bands and energy gaps are formed, Classification of metals/insulators/semiconductors, Fermi level, conduction & valance bands have been discussed
Introduction.
Superconductivity.
Meissner effect.
Flux Quantization.
Types of Superconductors.
London Equations.
BCS Theory.
London Penetration Depth
Applications of Super conductors.
This presentation contains various aspects of Graphene like synthesis techniques, characterization, commercialization, mechanical and electrical properties and present and future application.
Basics of Band Structure and semiconductors.pdfDr Biplab Bag
Basics of Band Structure and semiconductors: How the energy bands and energy gaps are formed, Classification of metals/insulators/semiconductors, Fermi level, conduction & valance bands have been discussed
This PPT gives introduction
to Dielectrics, Piezoelectrics & Ferroelectrics Materials, Methods and Applications. A quick glance at the dielectric phenomena, symmetry, classification, modelling, figures of merit and applications.
Comprehensive overview of the physics and applications of
ferroelectric
Grassellino - Application of Muon Spin Rotation to studies of cavity performa...thinfilmsworkshop
http://www.surfacetreatments.it/thinfilms
Application of Muon Spin Rotation to studies of cavity performance limitations (Anna Grassellino - 20')
Speaker: Anna Grassellino - TRIUMF - Vancouver, Canada | Duration: 20 min.
Abstract
In this contribution a new experiment to investigate magnetic flux entry in Nb coupons and HFQS limited cutout samples will be presented. The experimental technique, called muSR (muon spin rotation), utilizes a probe magnetic moment to reveal local magnetic fields in the sample under study. Through the use of low energy spin polarized muons, the experiment can probe near surface local magnetic fields with extreme sensitivity. Being a ‘local’ rather than external and global technique, it offers a different and precise way to measure the field of first penetration in type-II superconductors. The experiment will study the nature of the transition from superconducting to mixed state in the marginal type II superconductor Nb, for samples with different treatment and grain size, and for RF characterized (via thermometry) HFQS limited cutout samples. Studying the latest will provide an opportunity to look for correlation of the onset of HFQS with the appearance of flux entry into the sample, detectable via the extremely sensitive muSR probe. Models for HFQS and MFQS which muSR can help probing will be discussed.
This PPT gives introduction
to Dielectrics, Piezoelectrics & Ferroelectrics Materials, Methods and Applications. A quick glance at the dielectric phenomena, symmetry, classification, modelling, figures of merit and applications.
Comprehensive overview of the physics and applications of
ferroelectric
Grassellino - Application of Muon Spin Rotation to studies of cavity performa...thinfilmsworkshop
http://www.surfacetreatments.it/thinfilms
Application of Muon Spin Rotation to studies of cavity performance limitations (Anna Grassellino - 20')
Speaker: Anna Grassellino - TRIUMF - Vancouver, Canada | Duration: 20 min.
Abstract
In this contribution a new experiment to investigate magnetic flux entry in Nb coupons and HFQS limited cutout samples will be presented. The experimental technique, called muSR (muon spin rotation), utilizes a probe magnetic moment to reveal local magnetic fields in the sample under study. Through the use of low energy spin polarized muons, the experiment can probe near surface local magnetic fields with extreme sensitivity. Being a ‘local’ rather than external and global technique, it offers a different and precise way to measure the field of first penetration in type-II superconductors. The experiment will study the nature of the transition from superconducting to mixed state in the marginal type II superconductor Nb, for samples with different treatment and grain size, and for RF characterized (via thermometry) HFQS limited cutout samples. Studying the latest will provide an opportunity to look for correlation of the onset of HFQS with the appearance of flux entry into the sample, detectable via the extremely sensitive muSR probe. Models for HFQS and MFQS which muSR can help probing will be discussed.
Brandt - Superconductors and Vortices at Radio Frequency Magnetic Fieldsthinfilmsworkshop
Superconductors and Vortices at Radio Frequency Magnetic Fields (Ernst Helmut Brandt - 50')
Speaker: Ernst Helmut Brandt - Max Planck Institute for Metals Research, D-70506 Stuttgart, Germany | Duration: 50 min.
Abstract
After an introduction to superconductivity and Abrikosov vortices, the statics and dynamics of pinned and unpinned vortices in bulk and thin film superconductors is presented. Particular interesting is the case of Niobium, which has a Ginzburg-Landau parameter near 0.71, the boundary between type-I and type-II superconductors. This causes the appearance of a so called type-II/1 state in which the vortex lattice forms round or lamellar domains that are surrounded by ideally superconducting Meissner state. This state has been observed by decoration experiments and by small-angle neutron scattering.
Also considered are the ac losses caused at the surface of clean superconductors, in particular Niobium, in the Meissner state, when no vortices have yet penetrated. The linear ac response is then xpressed by a complex resistivity or complex magnetic penetration depth, or by a surface impedance. At higher amplitudes, several effects can make the response nonlinear and increase the ac losses.
In particular, at sharp edges or scratches of a rough surface the magnetic field is strongly enhanced by demagnetization effects and the induced current may reach its depairing limit, leading to the nucleation of short vortex segments. Strong ac losses appear when such vortex segments oscillate. In high-quality microwave cavities the nucleation of vortices has thus to be avoided. Once nucleated, some vortices may remain in the superconductor even when the applied magnetic field goes through zero. This phenomenon of flux-trapping is caused by weak pinning in the bulk or by surface pinning.
Superconductors and NANOTECHNOLOGY,Properties of nanomaterial's,Production of Buckyballs,Uses of Buckyballs,Carbon Nano tubes (CNTs) ,Applications of Superconductivity,BCS THEORY,London Penetration depth,TYPE OF SUPERCONDUCTORS,Meissner Effect (Effect of magnetic field)
A history of the development of the methods and applications of muon spin rotation/relaxation/resonance at the TRIUMF accelerator laboratory in Canada.
Basic Information regarding superconductors.
Superconductivity is a phenomenon of exactly zero electrical resistance and expulsion of magnetic fields occurring in certain materials when cooled below a characteristic critical temperature.
This power-point presentation include
1. Introduction to Superconductors
2. Discovery
3. Properties
4. Important factors
5. Types
6. High Tc Superconductors
7. Magnetic Levitation and its application
8. Josephson effect
9. Application of superconductors
#Tip- You can further add videos which are available in vast amount on YouTube regarding superconductivity(specially magnetic levitation)
P.S.Does not contain information about Cooper pairs and BCS theory
Doulbe Occupancy as a Probe of the Mott Transition for Fermions in One-dimens...Jorge Quintanilla
Contributed talk at the Annual MSCES 2011, Cambridge. We study theoretically double occupancy D as a probe of the Mott transition for trapped fermions in
one-‐dimensional optical lattices and compare our results to the three-‐dimensional case. The ground
state is described using the Bethe Ansatz in a local density approximation and the behavior at finite
temperatures is modelled using a high-‐temperature series expansion. In addition, we solve
analytically the model in the limit in which the interaction energy is the dominant energy scale.
We find that enhanced quantum fluctuations in one dimension lead to increased double occupancy
in the ground state, even deep in the Mott insulator region of the phase diagram (see figure).
Similarly, thermal fluctuations lead to high double occupancies at high temperatures. Nevertheless,
D is found to be a good indicator of the Mott transition just as in three dimensions. Moreover, unlike
other global observables, the bulk value of D in the Mott phase coincides, quantitatively, with that of
a suitably-‐prepared trapped system. We discuss possible experiments to verify these results and
argue that the one-‐dimensional Hubbard model could be used as a benchmark for quantitative
quantum analogue simulations.
Plenary lecture of the XIV SBPMat Meeting, given by Prof. Nader Engheta (University of Pennsylvania) on September 28, 2015, in Rio de Janeiro (Brazil).
Principal Component Analysis of Quantum Materials Data: a Study in Augmented ...Jorge Quintanilla
Sessions:
SCES / Quantum Magnets / Superconductivity
Authors:
D S Barker (1,5), S R Giblin (2), A D Hillier (3), E E McCabe (1,4), G Möller (1), James Molony (1), J Quintanilla (1), S Ramos (1), T Tula (1), Robert Twyman (1,6)
(1) University of Kent (2) University of Cardiff (3) ISIS Facility (4) University of Durham (6) UCL
Abstract:
There is much interest currently in the potential of machine learning to tease useful information out of complex data on materials. Here we ask whether this can work when only experimentally accessible data, i.e. averages rather than microstates, are available. We use Principal Component Analysis to study simulated neutron-scattering data on cluster quantum magnets [1] and experimental muon-spin relaxation curves from various superconducting and magnetic materials [2]. While the algorithms can perform certain functions, such as detection of phase transitions, automatically, I will argue that their best use is in providing human scientists with new ways to look at the data - an approach that can be best characterised as "augmented", rather than "artificial", intelligence.
References:
[1] R. Twyman, S. J. Gibson, J. Molony, J. Quintanilla, "Principal Component Analysis of Diffuse Magnetic Scattering: a Theoretical Study", Special Issue on Machine Learning in Condensed Matter Physics, J. Phys.: Condens. Matt. (accepted). arXiv: 2011.08234.
[2] T. Tula, G. Möller, J. Quintanilla, S. R. Giblin, A. D. Hillier, E. E. McCabe, S. Ramos, D. S. Barker, S. Gibson, "Machine Learning approach to muon spectroscopy analysis", Special Issue on Machine Learning in Condensed Matter Physics, J. Phys.: Condens. Matt. 33, 194002 (2021). DOI: 10.1088/1361-648X/abe39e.
Time-reversal symmetry breaking in superconductors through loop Josephson-cur...Jorge Quintanilla
Presentation given at the "Oxford Symposium on Quantum Materials 2018".
Abstract:
Broken time-revesal symmetry has been observed in a number of supercondcutors which do not seem to fit the mould of standard unconventional pairign models. We propose a superconducting instability where loop Josephson-currents form spontaneously within a unit cell at the critical temperature, Tc. Such currents break time-reversal symmetry (TRS) without needing an unconventional pairing mechanism. Using Ginzburg-Landau theory we show how they emerge in a toy model and estimate the size of the resulting magnetization, which is consistent with recent muon-spin relaxation experiments. We discuss the crystal symmetry requirements, which are quite non-trivial, = and show that they are met by the Re6X (X=Zr, Hf, Ti) family of TRS-breaking, but otherwise seemingly conventional, superconductors.
This presentation explores a brief idea about the structural and functional attributes of nucleotides, the structure and function of genetic materials along with the impact of UV rays and pH upon them.
Earliest Galaxies in the JADES Origins Field: Luminosity Function and Cosmic ...Sérgio Sacani
We characterize the earliest galaxy population in the JADES Origins Field (JOF), the deepest
imaging field observed with JWST. We make use of the ancillary Hubble optical images (5 filters
spanning 0.4−0.9µm) and novel JWST images with 14 filters spanning 0.8−5µm, including 7 mediumband filters, and reaching total exposure times of up to 46 hours per filter. We combine all our data
at > 2.3µm to construct an ultradeep image, reaching as deep as ≈ 31.4 AB mag in the stack and
30.3-31.0 AB mag (5σ, r = 0.1” circular aperture) in individual filters. We measure photometric
redshifts and use robust selection criteria to identify a sample of eight galaxy candidates at redshifts
z = 11.5 − 15. These objects show compact half-light radii of R1/2 ∼ 50 − 200pc, stellar masses of
M⋆ ∼ 107−108M⊙, and star-formation rates of SFR ∼ 0.1−1 M⊙ yr−1
. Our search finds no candidates
at 15 < z < 20, placing upper limits at these redshifts. We develop a forward modeling approach to
infer the properties of the evolving luminosity function without binning in redshift or luminosity that
marginalizes over the photometric redshift uncertainty of our candidate galaxies and incorporates the
impact of non-detections. We find a z = 12 luminosity function in good agreement with prior results,
and that the luminosity function normalization and UV luminosity density decline by a factor of ∼ 2.5
from z = 12 to z = 14. We discuss the possible implications of our results in the context of theoretical
models for evolution of the dark matter halo mass function.
Slide 1: Title Slide
Extrachromosomal Inheritance
Slide 2: Introduction to Extrachromosomal Inheritance
Definition: Extrachromosomal inheritance refers to the transmission of genetic material that is not found within the nucleus.
Key Components: Involves genes located in mitochondria, chloroplasts, and plasmids.
Slide 3: Mitochondrial Inheritance
Mitochondria: Organelles responsible for energy production.
Mitochondrial DNA (mtDNA): Circular DNA molecule found in mitochondria.
Inheritance Pattern: Maternally inherited, meaning it is passed from mothers to all their offspring.
Diseases: Examples include Leber’s hereditary optic neuropathy (LHON) and mitochondrial myopathy.
Slide 4: Chloroplast Inheritance
Chloroplasts: Organelles responsible for photosynthesis in plants.
Chloroplast DNA (cpDNA): Circular DNA molecule found in chloroplasts.
Inheritance Pattern: Often maternally inherited in most plants, but can vary in some species.
Examples: Variegation in plants, where leaf color patterns are determined by chloroplast DNA.
Slide 5: Plasmid Inheritance
Plasmids: Small, circular DNA molecules found in bacteria and some eukaryotes.
Features: Can carry antibiotic resistance genes and can be transferred between cells through processes like conjugation.
Significance: Important in biotechnology for gene cloning and genetic engineering.
Slide 6: Mechanisms of Extrachromosomal Inheritance
Non-Mendelian Patterns: Do not follow Mendel’s laws of inheritance.
Cytoplasmic Segregation: During cell division, organelles like mitochondria and chloroplasts are randomly distributed to daughter cells.
Heteroplasmy: Presence of more than one type of organellar genome within a cell, leading to variation in expression.
Slide 7: Examples of Extrachromosomal Inheritance
Four O’clock Plant (Mirabilis jalapa): Shows variegated leaves due to different cpDNA in leaf cells.
Petite Mutants in Yeast: Result from mutations in mitochondrial DNA affecting respiration.
Slide 8: Importance of Extrachromosomal Inheritance
Evolution: Provides insight into the evolution of eukaryotic cells.
Medicine: Understanding mitochondrial inheritance helps in diagnosing and treating mitochondrial diseases.
Agriculture: Chloroplast inheritance can be used in plant breeding and genetic modification.
Slide 9: Recent Research and Advances
Gene Editing: Techniques like CRISPR-Cas9 are being used to edit mitochondrial and chloroplast DNA.
Therapies: Development of mitochondrial replacement therapy (MRT) for preventing mitochondrial diseases.
Slide 10: Conclusion
Summary: Extrachromosomal inheritance involves the transmission of genetic material outside the nucleus and plays a crucial role in genetics, medicine, and biotechnology.
Future Directions: Continued research and technological advancements hold promise for new treatments and applications.
Slide 11: Questions and Discussion
Invite Audience: Open the floor for any questions or further discussion on the topic.
What is greenhouse gasses and how many gasses are there to affect the Earth.moosaasad1975
What are greenhouse gasses how they affect the earth and its environment what is the future of the environment and earth how the weather and the climate effects.
Nutraceutical market, scope and growth: Herbal drug technologyLokesh Patil
As consumer awareness of health and wellness rises, the nutraceutical market—which includes goods like functional meals, drinks, and dietary supplements that provide health advantages beyond basic nutrition—is growing significantly. As healthcare expenses rise, the population ages, and people want natural and preventative health solutions more and more, this industry is increasing quickly. Further driving market expansion are product formulation innovations and the use of cutting-edge technology for customized nutrition. With its worldwide reach, the nutraceutical industry is expected to keep growing and provide significant chances for research and investment in a number of categories, including vitamins, minerals, probiotics, and herbal supplements.
This pdf is about the Schizophrenia.
For more details visit on YouTube; @SELF-EXPLANATORY;
https://www.youtube.com/channel/UCAiarMZDNhe1A3Rnpr_WkzA/videos
Thanks...!
Cancer cell metabolism: special Reference to Lactate PathwayAADYARAJPANDEY1
Normal Cell Metabolism:
Cellular respiration describes the series of steps that cells use to break down sugar and other chemicals to get the energy we need to function.
Energy is stored in the bonds of glucose and when glucose is broken down, much of that energy is released.
Cell utilize energy in the form of ATP.
The first step of respiration is called glycolysis. In a series of steps, glycolysis breaks glucose into two smaller molecules - a chemical called pyruvate. A small amount of ATP is formed during this process.
Most healthy cells continue the breakdown in a second process, called the Kreb's cycle. The Kreb's cycle allows cells to “burn” the pyruvates made in glycolysis to get more ATP.
The last step in the breakdown of glucose is called oxidative phosphorylation (Ox-Phos).
It takes place in specialized cell structures called mitochondria. This process produces a large amount of ATP. Importantly, cells need oxygen to complete oxidative phosphorylation.
If a cell completes only glycolysis, only 2 molecules of ATP are made per glucose. However, if the cell completes the entire respiration process (glycolysis - Kreb's - oxidative phosphorylation), about 36 molecules of ATP are created, giving it much more energy to use.
IN CANCER CELL:
Unlike healthy cells that "burn" the entire molecule of sugar to capture a large amount of energy as ATP, cancer cells are wasteful.
Cancer cells only partially break down sugar molecules. They overuse the first step of respiration, glycolysis. They frequently do not complete the second step, oxidative phosphorylation.
This results in only 2 molecules of ATP per each glucose molecule instead of the 36 or so ATPs healthy cells gain. As a result, cancer cells need to use a lot more sugar molecules to get enough energy to survive.
Unlike healthy cells that "burn" the entire molecule of sugar to capture a large amount of energy as ATP, cancer cells are wasteful.
Cancer cells only partially break down sugar molecules. They overuse the first step of respiration, glycolysis. They frequently do not complete the second step, oxidative phosphorylation.
This results in only 2 molecules of ATP per each glucose molecule instead of the 36 or so ATPs healthy cells gain. As a result, cancer cells need to use a lot more sugar molecules to get enough energy to survive.
introduction to WARBERG PHENOMENA:
WARBURG EFFECT Usually, cancer cells are highly glycolytic (glucose addiction) and take up more glucose than do normal cells from outside.
Otto Heinrich Warburg (; 8 October 1883 – 1 August 1970) In 1931 was awarded the Nobel Prize in Physiology for his "discovery of the nature and mode of action of the respiratory enzyme.
WARNBURG EFFECT : cancer cells under aerobic (well-oxygenated) conditions to metabolize glucose to lactate (aerobic glycolysis) is known as the Warburg effect. Warburg made the observation that tumor slices consume glucose and secrete lactate at a higher rate than normal tissues.
A brief information about the SCOP protein database used in bioinformatics.
The Structural Classification of Proteins (SCOP) database is a comprehensive and authoritative resource for the structural and evolutionary relationships of proteins. It provides a detailed and curated classification of protein structures, grouping them into families, superfamilies, and folds based on their structural and sequence similarities.
Comparing Evolved Extractive Text Summary Scores of Bidirectional Encoder Rep...University of Maribor
Slides from:
11th International Conference on Electrical, Electronics and Computer Engineering (IcETRAN), Niš, 3-6 June 2024
Track: Artificial Intelligence
https://www.etran.rs/2024/en/home-english/
In silico drugs analogue design: novobiocin analogues.pptx
Broken Time-Reversal Symmetry and Topological Order in Triplet Superconductors
1. Broken Time-Reversal Symmetry and Topological Order
in Triplet Superconductors
Jorge Quintanilla1,2
1SEPnet and Hubbard Theory Consortium, University of Kent
2ISIS Neutron and Muon Source, STFC Rutherford Appleton Laboratory
Dresden, 27 November 2014
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 1 / 119
2. People and Money
People: James F. Annett (Bristol) , Adrian D. Hillier (RAL)
Bayan Mazidian (RAL/Bristol) , Bob Cywinski (Huddersfield) .
Ravi P. Singh , Gheeta Balakrishnan , Don Paul ,
Martin Lees (Birmingham). Amitava Bhattacharyya ,
Devashibai Adroja (RAL). A. M. Strydom (Johannesburg) .
Naoki Kase, Jun Akimitsu (Aoyama Gakuin).
Money: STFC (UK) + HEFCE/SEPnet (UK) + UJ and NRF (South Africa) +
Bristol + Kent.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 2 / 119
3. The Hubbard Theory Consortium
Director: Piers Coleman (RHUL/Rutgers)
SEPnet fellows: Matthias Eschrig (RHUL/RAL)
Claudio Castelnovo (RHUL/RAL)
Jorge Quintanilla (Kent/RAL)
Associate: Jörg Schmalian (Karlsruhe)
+ several SEPnet PhD students.
Strong correlations theory in close
collaboration with experiments at
• RAL (ISIS/Diamond)
• London Centre for Nanotech.
• RHUL
Coleman (RHUL/Rutgers)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 3 / 119
Eschrig (RHUL/RAL)
4. Overview
Two Paradigms in Condensed Matter ...
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
5. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
6. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Topological Transitions
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
7. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Topological Transitions
... interlock via triplet pairing in superconductors:
Superconductors
Broken time-reversal
symmetry
Topological
Triplet transitions
pairing
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
8. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Topological Transitions
... interlock via triplet pairing in superconductors:
Superconductors
Broken time-reversal
symmetry
Topological
Triplet transitions
pairing
SimpleTheories + Standard Measurements:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
9. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Topological Transitions
... interlock via triplet pairing in superconductors:
Superconductors
Broken time-reversal
symmetry
Topological
Triplet transitions
pairing
SimpleTheories + Standard Measurements:
Group Theory / Bogolibov Quasiparticles
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
10. Overview
Two Paradigms in Condensed Matter ...
Broken Symmetry
Topological Transitions
... interlock via triplet pairing in superconductors:
Superconductors
Broken time-reversal
symmetry
Topological
Triplet transitions
pairing
SimpleTheories + Standard Measurements:
Group Theory / Bogolibov Quasiparticles
Neutron diffraction / Muon Spin Rotation / Specific Heat / Penetration Depth
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 4 / 119
11. Outline
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 5 / 119
12. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
13. Broken symmetry
Photo: Eddie Hui-Bon-Hoa, www.shiromi.com
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 7 / 119
14. Broken symmetry
Photo: Eddie Hui-Bon-Hoa, www.shiromi.com
Photo: Kenneth G. Libbrecht, snowflakes.com
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 7 / 119
15. Broken symmetry
Photo: Eddie Hui-Bon-Hoa, www.shiromi.com
Photo: Kenneth G. Libbrecht, snowflakes.com
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Photo: commons.wikimedia.org
Unconventional superconductors
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 7 / 119
16. Broken symmetry
Photo: Eddie Hui-Bon-Hoa, www.shiromi.com
Photo: Kenneth G. Libbrecht, snowflakes.com
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Photo: commons.wikimedia.org
Unconventional superconductors
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 7 / 119
17. Broken symmetry
Photo: Eddie Hui-Bon-Hoa, www.shiromi.com
Photo: Kenneth G. Libbrecht, snowflakes.com
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Photo: commons.wikimedia.org
Unconventional superconductors
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 7 / 119
21. Time-reversal Symmetry
p
r
x
y
z
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 11 / 119
22. Time-reversal Symmetry
r -p
x
y
z
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 11 / 119
23. Time-reversal Symmetry
r -p
x
y
z
Classical time-reversal symmetry:
t ! t equivalent to
r ! r and p ! p
Also inverts angular momenta.
True in the absence of friction/magnetic fields.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 11 / 119
24. Time-reversal Symmetry
r -p
x
y
z
Classical time-reversal symmetry:
t ! t equivalent to
r ! r and p ! p
Also inverts angular momenta.
True in the absence of friction/magnetic fields.
Quantum time-reversal symmetry:
t ! t equivalent to
y ! y and S ! S.
True if Hˆ = Hˆ and spin-invariant.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 11 / 119
25. Time-reversal Symmetry
r -p
x
y
z
Classical time-reversal symmetry:
t ! t equivalent to
r ! r and p ! p
Also inverts angular momenta.
True in the absence of friction/magnetic fields.
Quantum time-reversal symmetry:
t ! t equivalent to
y ! y and S ! S.
True if Hˆ = Hˆ and spin-invariant.
For quasi-particles in a superconductor:
Hˆ = Hˆ 0 + Dcˆ †
k ˆc†
k + H.c. ) TRS: D = D
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 11 / 119
26. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
28. Muon Spin Rotation
Adrian Hillier
(Muons group leader, ISIS)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 14 / 119
29. Muon Spin Rotation
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Zero field muon spin relaxation
_
e
e
backward
detector
forward
detector
sample
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 15 / 119
30. Kubo-Toyabe x exponential
Asymmetry:
NF NB
NF + NB
= G (t)
s : randomly-oriented fields (e.g. nuclear moments)
L :smoothly-modulated fields (e.g. electronic moments)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 16 / 119
31. The “classic” examples: UPt3 and Sr2RuO4
UPt3
Luke et al. PRL (1993)
Sr2RuO4
Luke et al. Nature (1998)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 17 / 119
32. Confirmed by Kerr effect
UPt3
Schemm et al. Science (2014)
Sr2RuO4
Jing Xia et al. PRL (2006)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 18 / 119
33. More recent finds: LaNiC2
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 19 / 119
34. More recent finds: LaNiC2
Relaxation due to electronic moments
Moment
size
~ 0.1G
(~ 0.01μB
)
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
(longitudinal)
_
e
e
backward
detector
Timescale:
10-4s
~
forward
detector
sample
+
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 20 / 119
35. More recent finds: LaNiGa2
A. D. Hillier, J. Quintanilla, B. Mazidian, J. F. Annett,
Physical Review Letters 109, 097001 (2012).
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 21 / 119
36. More recent finds: Re6Zr
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 22 / 119
37. More recent finds: Lu5Rh6Sn18
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 23 / 119
38. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
39. Singlet, triplet, or both?
It’s all in the gap function:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 25 / 119
40. Singlet, triplet, or both?
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Symmetry of the gap function
It’s all in the gap function:
k k
k k
ˆ k
See J.F. Annett Adv. Phys. 1990.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 25 / 119
41. Singlet, triplet, or both?
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Symmetry of the gap function
It’s all in the gap function:
k k
k k
ˆ k
See J.F. Annett Adv. Phys. 1990. Pauli )
ˆD
(k) = ˆD
T (k)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 25 / 119
42. Singlet, triplet, or both?
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Symmetry of the gap function
It’s all in the gap function:
k k
k k
ˆ k
See J.F. Annett Adv. Phys. 1990. Pauli )
T (k) Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
ˆD
(k) = ˆD
Singlet, triplet, or both?
ˆ k
0 0
0 0
dx idy dz
dz dx idy
singlet
[ 0(k) even ]
triplet
[ d(k) odd ]
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 25 / 119
43. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Neglect (for now!) spin-orbit coupling:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 26 / 119
44. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Neglect (for now!) spin-orbit coupling:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 27 / 119
45. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Neglect (for now!) spin-orbit coupling:
Singlet and triplet representations of SO(3):
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 28 / 119
46. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Neglect (for now!) spin-orbit coupling:
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
s)T , Γn
t = + (Γn
t)T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 29 / 119
47. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Neglect (for now!) spin-orbit coupling:
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
s)T , Γn
Impose Pauli’s exclusion principle:
t = + (Γn
t)T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 30 / 119
48. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Impose Pauli’s exclusion principle:
, 'k ', k
Neglect (for now!) spin-orbit coupling:
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
s)T , Γn
t = + (Γn
t)T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 31 / 119
49. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
Impose Pauli’s exclusion principle:
, 'k ', k
Neglect (for now!) spin-orbit coupling:
ˆ k either singlet
s)T , Γn
t = + (Γn
t)T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 32 / 119
50. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
s)T , Γn
Impose Pauli’s exclusion principle:
t = + (Γn
t)T
, 'k ', k
Neglect (for now!) spin-orbit coupling:
ˆ k either singlet y i ˆ , ' 0 k k
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 33 / 119
51. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
Impose Pauli’s exclusion principle:
, 'k ', k
Neglect (for now!) spin-orbit coupling:
ˆ k either singlet y i ˆ , ' 0 k k
or triplet
s)T , Γn
t = + (Γn
t)T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 34 / 119
52. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Singlet and triplet representations of SO(3):
Γn
s = - (Γn
s)T , Γn
Impose Pauli’s exclusion principle:
t = + (Γn
t)T
, 'k ', k
Neglect (for now!) spin-orbit coupling:
ˆ k either singlet y i ˆ , ' 0 k k
or triplet y i .ˆ ˆ , ' k d k σ
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 35 / 119
53. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
Gap function may have both singlet and triplet components
d id d
x y z
d d id
0 k
z x y
0
0
ˆ
0
k k spin orbit
, ' , '
• However, if we have a centre of inversion
basis functions either even or odd under inversion
still have either singlet or triplet pairing (at Tc)
Jorge Quintanilla• (NKeont acnednRAtLr)e of inversion: mwawyw .hcoandv-mea ts.oirngglet and triplet (even at TDcre)s den 2014 36 / 119
54. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = [SO(3)×Gc]×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 37 / 119
55. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = [SO(3)×Gc]×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 38 / 119
56. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = [SO(3)×Gc]×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 39 / 119
57. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = [SO(3)×Gc]×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 40 / 119
58. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = [SO(3)×Gc]×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 41 / 119
59. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = Gc,J×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 42 / 119
60. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = Gc,J×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 43 / 119
61. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
G = Gc,J×U(1)×T
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 44 / 119
62. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 45 / 119
63. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 46 / 119
64. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 47 / 119
65. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 48 / 119
66. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
This affects d(k) (a vector under
spin rotations).
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 49 / 119
67. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
E.g. reflection through a vertical
plane perpendicular to the y axis:
y
v J J I C , 2,
This affects d(k) (a vector under
spin rotations).
It does not affect 0(k) (a scalar).
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
z
y x
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 50 / 119
68. The role of spin-orbit coupling (SOC)
When can we have singlet-triplet mixing?
We must now use basis functions of the double group:
Gap function may have both singlet and triplet components
ˆD
(k) =
dGå
n=1
hnˆG
n (k)
d id d
x y z
d d id
0 k
z x y
0
0
ˆ
0
k k spin orbit
, ' , '
• However, if we have a centre of inversion
basis functions either even or odd under inversion
still have either singlet or triplet pairing (at Tc)
• No centre of inversion: may have singlet and triplet (even at Tc)
Crystal symmetry
Centrosymmetric Non-centrosymmetric
Spin-orbit coupling Weak N N
Strong N Y
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 51 / 119
69. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
70. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
71. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
72. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
The singlet irrep of SO(3) has d = 1 ) for singlet pairing, the point group Gc
must have a d 1 irrep.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
73. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
The singlet irrep of SO(3) has d = 1 ) for singlet pairing, the point group Gc
must have a d 1 irrep.
The triplet irrep of SO(3) had d = 3 ) for triplet pairing, broken TRS is
possible even for d = 1 irreps of Gc .
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
74. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
The singlet irrep of SO(3) has d = 1 ) for singlet pairing, the point group Gc
must have a d 1 irrep.
The triplet irrep of SO(3) had d = 3 ) for triplet pairing, broken TRS is
possible even for d = 1 irreps of Gc .
Strong spin-orbit coupling: Gc,J (double group)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
75. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
The singlet irrep of SO(3) has d = 1 ) for singlet pairing, the point group Gc
must have a d 1 irrep.
The triplet irrep of SO(3) had d = 3 ) for triplet pairing, broken TRS is
possible even for d = 1 irreps of Gc .
Strong spin-orbit coupling: Gc,J (double group)
The dimensionality of the irreps is the same as for Gc therefore if all irreps are
d = 1 then there can be no broken TRS.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
76. When can we have broken time-reversal symmetry?
For ˆD
(k) to be non-trivially complex, it must have more than one
component:
ˆD
(k) = h1ˆG
1 (k) + h2ˆG
2 (k) , arg h16= arg h2
The instability must therefore take place in an irrep with d 1.
Weak spin-orbit coupling: SO(3) Gc
The singlet irrep of SO(3) has d = 1 ) for singlet pairing, the point group Gc
must have a d 1 irrep.
The triplet irrep of SO(3) had d = 3 ) for triplet pairing, broken TRS is
possible even for d = 1 irreps of Gc .
Strong spin-orbit coupling: Gc,J (double group)
The dimensionality of the irreps is the same as for Gc therefore if all irreps are
d = 1 then there can be no broken TRS.
Broken TRS involves always a d 1 irrep and it requires both the singlet and
triplet components
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 52 / 119
77. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
78. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Character table
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 54 / 119
79. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Character table
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 55 / 119
80. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Character table
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 56 / 119
81. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Character table
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
180o
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 57 / 119
82. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
C
2v
Character table
Symmetries and
their characters
Sample basis
functions
Irreducible
representation
E C
2
v
’
v
Even Odd
A
1
1 1 1 1 1 Z
A
2
1 1 -1 -1 XY XYZ
B
1
1 -1 1 -1 XZ X
B
2
1 -1 -1 1 YZ Y
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
All irreps d = 1
) weak SOC
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 58 / 119
83. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
SO(3)xC
2v
Gap function
(unitary)
Gap function
(non-unitary)
1A
1 (k)=1 -
1A
2 (k)=k
k
x
Y
-
1B
1 (k)=k
k
X
Z
-
1B
2 (k)=k
k
Y
Z
-
3A
1
d(k)=(0,0,1)k
Z
d(k)=(1,i,0)k
Z
3A
2
d(k)=(0,0,1)k
k
X
k
Y
Z
d(k)=(1,i,0)k
k
X
k
Y
Z
3B
1
d(k)=(0,0,1)k
X
d(k)=(1,i,0)k
X
3B
2
d(k)=(0,0,1)k
Y
d(k)=(1,i,0)k
Y
Possible order parameters
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 59 / 119
84. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
SO(3)xC
2v
Gap function
(unitary)
Gap function
(non-unitary)
1A
1 (k)=1 -
1A
2 (k)=k
k
x
Y
-
1B
1 (k)=k
k
X
Z
-
1B
2 (k)=k
k
Y
Z
-
3A
1
d(k)=(0,0,1)k
Z
d(k)=(1,i,0)k
Z
3A
2
d(k)=(0,0,1)k
k
X
k
Y
Z
d(k)=(1,i,0)k
k
X
k
Y
Z
3B
1
d(k)=(0,0,1)k
X
d(k)=(1,i,0)k
X
3B
2
d(k)=(0,0,1)k
Y
d(k)=(1,i,0)k
Y
Possible order parameters
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 60 / 119
85. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
SO(3)xC
2v
Gap function
(unitary)
Gap function
(non-unitary)
1A
1 (k)=1 -
1A
2 (k)=k
k
x
Y
-
1B
1 (k)=k
k
X
Z
-
1B
2 (k)=k
k
Y
Z
-
3A
1
d(k)=(0,0,1)k
Z
d(k)=(1,i,0)k
Z
3A
2
d(k)=(0,0,1)k
k
X
k
Y
Z
d(k)=(1,i,0)k
k
X
k
Y
Z
3B
1
d(k)=(0,0,1)k
X
d(k)=(1,i,0)k
X
3B
2
d(k)=(0,0,1)k
Y
d(k)=(1,i,0)k
Y
Possible order parameters
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 61 / 119
86. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Possible order parameters
SO(3)xC
2v
Gap function
(unitary)
Gap function
(non-unitary)
1A
1 (k)=1 -
1A
2 (k)=k
k
x
Y
-
1B
1 (k)=k
k
X
Z
-
1B
2 (k)=k
k
Y
Z
-
3A
1
d(k)=(0,0,1)k
Z
d(k)=(1,i,0)k
Z
3A
2
d(k)=(0,0,1)k
k
X
k
Y
Z
d(k)=(1,i,0)k
k
X
k
Y
Z
3B
1
d(k)=(0,0,1)k
X
d(k)=(1,i,0)k
X
3B
2
d(k)=(0,0,1)k
Y
d(k)=(1,i,0)k
Y
Non-unitary
d x d* ≠ 0
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 62 / 119
87. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Possible order parameters
SO(3)xC
2v
Gap function
(unitary)
Gap function
(non-unitary)
1A
1 (k)=1 -
1A
2 (k)=k
k
x
Y
-
1B
1 (k)=k
k
X
Z
-
1B
2 (k)=k
k
Y
Z
-
3A
1
d(k)=(0,0,1)k
Z
d(k)=(1,i,0)k
Z
3A
2
d(k)=(0,0,1)k
k
X
k
Y
Z
d(k)=(1,i,0)k
k
X
k
Y
Z
3B
1
d(k)=(0,0,1)k
X
d(k)=(1,i,0)k
X
3B
2
d(k)=(0,0,1)k
Y
d(k)=(1,i,0)k
Y
Non-unitary
d x d* ≠ 0
breaks only SO(3) x U(1) x T
* C.f. Li2Pd3B Li2Pt3B,
H. Q. Yuan et al. PRL’06
*
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 63 / 119
88. LaNiC2
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Non-unitary pairing
Spin-up superfluid
coexisting with spin-down
Fermi liquid.
0 0
0
The A1 phase of
liquid 3He.
0
or
0 0
ˆ
C.f.
Also FM SC - but this is a paramagnet!
A. D. Hillier, J. Quintanilla and R. Cywinski, Physical Review Letters (2009).
J. Quintanilla, J. F. Annett, A. D. Hillier, R. Cywinski, Physical Review B (2010).
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 64 / 119
89. LaNiGa2
Centrosymmetric, but again all irreps d = 1 ) again weak SOC and non-unitary
triplet
A.D. Hillier, J. Quintanilla, B. Mazidian, J.F. Annett, and R. Cywinski, PRL 109, 097001
(2012).
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 65 / 119
A new family of superconductors?
90. Why non-unitary?
Generic Landau theory for a triplet superconductor (1D irrep):
F = a jhj2 +
b
2
124. + b0 jh hj2 +
m2
2c
+ b00m (ih h) .
Magnetisation as a sub-dominant order parameter:
Superconductivity
magnetisation
Temperature
Theory (left): A. D. Hillier, J. Quintanilla, B. Mazidian, J. F. Annett, PRL 109, 097001 (2012).
Experiment (right): Akihiko Sumiyama et al., JPSJ (2014).
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 66 / 119
126. Re6Zr
Td group:
noncentrosymmetric;
d = 1, 2, 3
) can have broken TRS with strong SOC
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 67 / 119
127. Re6Zr
Td group:
noncentrosymmetric;
d = 1, 2, 3
) can have broken TRS with strong SOC
) broken TRS with singlet-triplet mixing
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 67 / 119
128. Re6Zr
Td group:
noncentrosymmetric;
d = 1, 2, 3
) can have broken TRS with strong SOC
) broken TRS with singlet-triplet mixing
E irrep (d = 2) )
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 67 / 119
129. Re6Zr
Td group:
noncentrosymmetric;
d = 1, 2, 3
) can have broken TRS with strong SOC
) broken TRS with singlet-triplet mixing
E irrep (d = 2) )
F1, F2 irreps (d = 3) ) several more mixed singlet-triplet states.
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 67 / 119
130. Lu5Rh6Sn18
Group D4h:
centrosymmetric ) no singlet-triplet mixing;1
d = 1, 2, 3
) can have broken TRS with strong SOC.
Only two states allowed: 1Eg (c) (singlet) and Eu(c) (triplet).
1c.f. recent ARPES-based claim for Sr2RuO4: C.N. Veenstra et al., PRL 112,
127002 (2014). +
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 68 / 119
131. Lu5Rh6Sn18
Singlet state:
k k y x
kz
Triplet:
kz
ky
kx
ky
kz
kx
ky
kx
kz
kz
ky
kx
ky
kz
kx
ky
kx
kz
kz
ky
kx
ky
kz
kx
N.B. “shallow” point nodes.
These results should apply just as well to Sr2RuO4, in the regime of strong
spin-orbit coupling [see Veenstra et al. results + ].
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 69 / 119
132. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
133. A bowl is not a mug
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
134. A bowl is not a mug
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
135. A bowl is not a mug
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
136. A bowl is not a mug
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
137. A bowl is not a mug
?
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
138. A bowl is not a mug
?
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
139. A bowl is not a mug
?
Is there a thermodynamic signature?
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 71 / 119
140. Power laws in nodal superconductors
Low-temperature specific heat of a superconductor gives information on the
spectrum of low-lying excitations:
Fully gapped Point nodes Line nodes
Cv eD/T Cv T3 Cv T2
D
This simple idea has been around for a while.2
Widely used to fit experimental data on unconventional superconductors.3
2Anderson Morel (1961), Leggett (1975)
3Sigrist, Ueda (’89), Annett (’90), MacKenzie Maeno (’03)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 72 / 119
141. Linear nodes
It all comes from the density of states: +
g (E) En1 ) Cv Tn
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 73 / 119
142. Linear nodes
It all comes from the density of states: +
g (E) En1 ) Cv Tn
linear
point node line node
D2k= I1
kx
jj
2 + ky
jj
2
D2k
= I1kx
jj
2
g(E) = E2
2(2p)2I1
pI2
g(E) = LE
(2p)3pI1
pI2
n = 3 n = 2
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 73 / 119
143. Linear nodes
It all comes from the density of states: +
g (E) En1 ) Cv Tn
linear
point node line node
D2k= I1
kx
jj
2 + ky
jj
2
D2k
= I1kx
jj
2
g(E) = E2
2(2p)2I1
pI2
g(E) = LE
(2p)3pI1
pI2
n = 3 n = 2
Key assumption: linear increase of the gap away from the node
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 73 / 119
144. Shallow nodes
Relax the linear assumption and we also get different exponents:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 74 / 119
145. Shallow nodes
Relax the linear assumption and we also get different exponents:
shallow
point node line node
D2k
= I1(kx
jj
2 + ky
jj
2
)2 D2k
= I1kx
jj
4
g(E) = E
2(2p)2pI1
pI2
g(E) = L
p
E
(2p)3I
1
4
1
pI2
n = 2 n = 1.5
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 74 / 119
146. Shallow nodes
Relax the linear assumption and we also get different exponents:
shallow
point node line node
D2k
= I1(kx
jj
2 + ky
jj
2
)2 D2k
= I1kx
jj
4
g(E) = E
2(2p)2pI1
pI2
g(E) = L
p
E
(2p)3I
1
4
1
pI2
n = 2 n = 1.5
Shallow point nodes first discussed (speculatively) by Leggett [1979].
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 74 / 119
147. Shallow nodes
Relax the linear assumption and we also get different exponents:
shallow
point node line node
D2k
= I1(kx
jj
2 + ky
jj
2
)2 D2k
= I1kx
jj
4
g(E) = E
2(2p)2pI1
pI2
g(E) = L
p
E
(2p)3I
1
4
1
pI2
n = 2 n = 1.5
Shallow point nodes first discussed (speculatively) by Leggett [1979].
A shallow point node may be required by symmetry e.g. the proposed E2u
pairing state in UPt3 [see J.A. Sauls, Adv. Phys. 43, 113-141 (1994)] and our
own result for R5Rh6Sn18 [A. Bhattacharyya, D. T. Adroja, JQ et al.
(unpublished)].
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 74 / 119
148. Shallow nodes
Relax the linear assumption and we also get different exponents:
shallow
point node line node
D2k
= I1(kx
jj
2 + ky
jj
2
)2 D2k
= I1kx
jj
4
g(E) = E
2(2p)2pI1
pI2
g(E) = L
p
E
(2p)3I
1
4
1
pI2
n = 2 n = 1.5
Shallow point nodes first discussed (speculatively) by Leggett [1979].
A shallow point node may be required by symmetry e.g. the proposed E2u
pairing state in UPt3 [see J.A. Sauls, Adv. Phys. 43, 113-141 (1994)] and our
own result for R5Rh6Sn18 [A. Bhattacharyya, D. T. Adroja, JQ et al.
(unpublished)].
A shallow line node may result at the boundary between gapless and line node
behaviour in pnictides [Fernandes and Schmalian, PRB 84, 012505 (’11)]. +
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 74 / 119
149. Line crossings
A different power law is expected at line crossings
(e.g. d-wave pairing on a spherical Fermi surface):
crossing
of linear line nodes
D2k
= I1
kx
jj
2 ky
jj
2
2
or I1kx
jj
2ky
jj
2
g(E) =
E(1+2lnj
L+
1
4
1
p
E/I
1
4
1
p
E/I
j)
(2p)3pI1I2
E0.8
n = 1.8 ( 2 !!)
+
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 75 / 119
150. Crossing of shallow line nodes
When shallow lines cross we get an even lower exponent:
crossing
of shallow line nodes
D2k= I1
kx
jj
2 ky
jj
2
4
or I1kx
jj
4ky
jj
4
g (E) =
p
E(1+2lnj
L+E
14
/I
18
1
E
14
/I
18
1
j)
(2p)3I
1
4
1
pI2
E0.4
n = 1.4 *
* c.f. gapless excitations of a Fermi liquid: g (E) = constant ) n = 1
+
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 76 / 119
151. Numerics
n = d ln Cv/d lnT
4.5
4
3.5
3
2.5
2
1.5
1
linear point node
shallow point node
linear line node
crossing of linear line nodes
shallow line node
crossing of shallow line nodes
0 0.05 0.1 0.15 0.2 0.25 0.3 0.35
n
T / T
c
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 77 / 119
152. A generic mechanism
We propose that shallow nodes will exist generically at topological phase
transitions in superocnductors with multi-component order parameters:
D0
D1
Fermi Sea
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 78 / 119
153. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 79 / 119
154. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 80 / 119
155. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Linear
nodes
Linear
nodes
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 81 / 119
156. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 82 / 119
157. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 83 / 119
158. A generic mechanism
We propose that shallow nodes will exist generically at quantum phase
transitions in superocnductors with multi-component order parameters:
D1
Fermi Sea
D0
Shallow
node
Shallow
node
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 84 / 119
159. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
160. Singlet-triplet mixing in noncentrosymmetric
superconductors
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Non-centrosymmetric superconductors are the multi-component order
parameter supercondcutors par excellence:
ˆ k
0 0
0 0
dx idy dz
dz dx idy
singlet
[ 0(k) even ]
triplet
[ d(k) odd ]
4Batkova et al. JPCM (2010)
5Zuev et al. PRB (2007)
6Adrian D. Hillier, JQ and R. Cywinski PRL (2009)
7Adrian D. Hillier, JQ, B. Mazidian, J. F. Annett, R. Cywinski PRL (2012)
8Bauer et al. PRL (2004)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 86 / 119
161. Singlet-triplet mixing in noncentrosymmetric
superconductors
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Non-centrosymmetric superconductors are the multi-component order
parameter supercondcutors par excellence:
ˆ k
0 0
0 0
dx idy dz
dz dx idy
singlet
[ 0(k) even ]
triplet
[ d(k) odd ]
In practice, there is a varied phenomenology:
4Batkova et al. JPCM (2010)
5Zuev et al. PRB (2007)
6Adrian D. Hillier, JQ and R. Cywinski PRL (2009)
7Adrian D. Hillier, JQ, B. Mazidian, J. F. Annett, R. Cywinski PRL (2012)
8Bauer et al. PRL (2004)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 86 / 119
162. Singlet-triplet mixing in noncentrosymmetric
superconductors
Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Singlet, triplet, or both?
Non-centrosymmetric superconductors are the multi-component order
parameter supercondcutors par excellence:
ˆ k
0 0
0 0
dx idy dz
dz dx idy
singlet
[ 0(k) even ]
triplet
[ d(k) odd ]
In practice, there is a varied phenomenology:
Some are conventional (singlet) superconductors:
BaPtSi34, Re3W5,...
Others seem to be correlated, purely triplet superconductors: +
LaNiC26 (c.f. centrosymmetric LaNiGa27) + , CePtr3Si (?) 8
4Batkova et al. JPCM (2010)
5Zuev et al. PRB (2007)
6Adrian D. Hillier, JQ and R. Cywinski PRL (2009)
7Adrian D. Hillier, JQ, B. Mazidian, J. F. Annett, R. Cywinski PRL (2012)
8Bauer et al. PRL (2004)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 86 / 119
163. Li2PdxPt3xB: tunable singlet-triplet mixing
The Li2Pdx Pt3xB family (0 x 3; cubic point group O) provides a tunable
realisation of this singlet-triplet mixing:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 87 / 119
164. Li2PdxPt3xB: tunable singlet-triplet mixing
The Li2Pdx Pt3xB family (0 x 3; cubic point group O) provides a tunable
realisation of this singlet-triplet mixing:
Pd is a lighter element with weak spin-orbit coupling (Tc 7K)
Pt is a heavier element with strong spin orbit coupling (Tc 2.7K)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 87 / 119
165. Li2PdxPt3xB: tunable singlet-triplet mixing
The Li2Pdx Pt3xB family (0 x 3; cubic point group O) provides a tunable
realisation of this singlet-triplet mixing:
Pd is a lighter element with weak spin-orbit coupling (Tc 7K)
Pt is a heavier element with strong spin orbit coupling (Tc 2.7K)
The series goes from fully-gapped
(x = 3) to nodal (x = 0):
H.Q. Yuan et al.,
Phys. Rev. Lett. 97, 017006 (2006).
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 87 / 119
166. Li2PdxPt3xB: tunable singlet-triplet mixing
The Li2Pdx Pt3xB family (0 x 3; cubic point group O) provides a tunable
realisation of this singlet-triplet mixing:
Pd is a lighter element with weak spin-orbit coupling (Tc 7K)
Pt is a heavier element with strong spin orbit coupling (Tc 2.7K)
The series goes from fully-gapped
(x = 3) to nodal (x = 0):
H.Q. Yuan et al.,
Phys. Rev. Lett. 97, 017006 (2006).
NMR suggests nodal state a triplet:
M.Nishiyama et al.,
Phys. Rev. Lett. 98, 047002 (2007)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 87 / 119
167. Li2PdxPt3xB: Phase diagram
Bogoliubov Hamiltonian with Rashba spin-orbit coupling:
H(k) =
ˆh(k) ˆD
(k)
ˆD
†(k) ˆhT (k)
ˆh(k) = #kI + gk s
ˆD
(k) = [D0 (k) + d (k) ˆs
] iˆs
y (most general gap matrix)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 88 / 119
168. Li2PdxPt3xB: Phase diagram
Bogoliubov Hamiltonian with Rashba spin-orbit coupling:
H(k) =
ˆh(k) ˆD
(k)
ˆD
†(k) ˆhT (k)
ˆh(k) = #kI + gk s
ˆD
(k) = [D0 (k) + d (k) ˆs
] iˆs
y (most general gap matrix)
Assuming j#kj jgkj jd (k)j the quasi-particle spectrum is
E =
8
:
q
2
(#k m + jg2 kj)+ (D0 (k) + jd (k)j); and
q
(#k m jgkj)2 + (D0 (k) jd (k)j)2 .
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 88 / 119
169. Li2PdxPt3xB: Phase diagram
Bogoliubov Hamiltonian with Rashba spin-orbit coupling:
H(k) =
ˆh(k) ˆD
(k)
ˆD
†(k) ˆhT (k)
ˆh(k) = #kI + gk s
ˆD
(k) = [D0 (k) + d (k) ˆs
] iˆs
y (most general gap matrix)
Assuming j#kj jgkj jd (k)j the quasi-particle spectrum is
E =
8
:
q
2
(#k m + jg2 kj)+ (D0 (k) + jd (k)j); and
q
(#k m jgkj)2 + (D0 (k) jd (k)j)2 .
Take most symmetric (A1) irreducible representation: +
D0 (k) = D0
d(k) = D0 f
A (x) (kx , ky , kz ) B (x)
kx
k2
y + k2
z
, ky
k2
z + k2
x
, kz
k2
x + k2
y
g
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 88 / 119
170. Li2PdxPt3xB: Phase diagram
Treat A and B as independent tuning parameters and study quasiparticle
spectrum. We find a very rich phase diagram with topollogically-distinct phases:9
9C. Beri, PRB (2010); A. Schnyder, S. Ryu, PRB(R) (2011); A. Schnyder et al.,
PRBJorg(e2Q0u1in2ta)n;illaB(.KeMntaanzdidRiAaLn) , JQ, A.D. Hillierw,wJw..cFo.ndA-mnatn.oergtt, arXiv:1302.2161. Dresden 2014 89 / 119
181. Li2PdxPt3xB: predicted specific heat power-laws
5
n = 2 j
n = 2
n = 1.8
n = 1.4
4
3
11
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182. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
183. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
184. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
A = 3
3.6 3.8 4 4.2 4.4
B
0.25
0.2
0.15
0.1
0.05
0
T/Tc
2.2
2.1
2
1.9
1.8
1.7
1.6
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
185. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
A = 3
3.6 3.8 4 4.2 4.4
B
0.25
0.2
0.15
0.1
0.05
0
T/Tc
2.2
2.1
2
1.9
1.8
1.7
1.6
The conventional exponent (n = 2 in this example) is only seen below a
temperature scale that converges to zero at the transition
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
186. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
A = 3
3.6 3.8 4 4.2 4.4
B
0.25
0.2
0.15
0.1
0.05
0
T/Tc
2.2
2.1
2
1.9
1.8
1.7
1.6
The conventional exponent (n = 2 in this example) is only seen below a
temperature scale that converges to zero at the transition
The anomalous exponent (here n = 1.8) is seen everywhere else
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
187. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
A = 3
3.6 3.8 4 4.2 4.4
B
0.25
0.2
0.15
0.1
0.05
0
T/Tc
2.2
2.1
2
1.9
1.8
1.7
1.6
The conventional exponent (n = 2 in this example) is only seen below a
temperature scale that converges to zero at the transition
The anomalous exponent (here n = 1.8) is seen everywhere else )
the influence of the topo transition extends throughout the phase diagram
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
188. Anomalous power laws throughout the phase diagram
Does the observation of these effects require fine-tuning?
Let’s put these curves on a density plot:
A = 3
3.6 3.8 4 4.2 4.4
B
0.25
0.2
0.15
0.1
0.05
0
T/Tc
2.2
2.1
2
1.9
1.8
1.7
1.6
The conventional exponent (n = 2 in this example) is only seen below a
temperature scale that converges to zero at the transition
The anomalous exponent (here n = 1.8) is seen everywhere else )
the influence of the topo transition extends throughout the phase diagram
c.f. quantum critical endpoints but here we did not have to fine-tune Tc ! 0
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 101 / 119
189. Quantum Materials Theory
1 Broken time-reversal symmetry in superconductors
2 Experimental evidence for broken TRS
3 Singlet, triplet, or both?
4 A symmetry zoo
5 Topological transitions in Superconductors
6 Topological transition state: Li2Pdx Pt3xB
7 Take-home message
190. What to take home
Superconductors
Broken time-reversal
symmetry
Topological
Triplet transitions
pairing
The relationship between triplet pairing and broken timre-reversal symmetry
is complicated
Non-unitary triplet pairing breaks time-reversal symmetry and couples to
magnetism in a special way
Singlet-triplet mixing may induce broken time-reversal symmetry or
topological transitions
There are bulk signatures of topological transitions
The thermodynamic transition is a distinct state
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 103 / 119
193. Spin-orbit coupling in Sr2RuO4
Recent spin-polarised ARPES find strong spin-orbit coupling in Sr2RuO4
[C.N. Veenstra et al., PRL 112, 127002 (2014)]:
Veenstra et al.’s claim is that this will lead to singlet-triplet mixing.
This seems at odds with our approach.
back
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 105 / 119
194. Power laws in nodal superconductors
Let’s remember where this came from:
Cv = T
dS
dT
=
1
2kBT2åk
0
BB@
Ek T dEk
|d{Tz}
0
1
CCA
Ek sech2 Ek
2kBT | {z }
4eEk /KBT
T2
Z
dEg (E) E2eE/kBT at low T
g (E) En1 ) Cv Tn
Z
dee2+n1ee
| {z }
a number
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 106 / 119
195. Power laws in nodal superconductors
Ek =
q
e2
k + D2k
r
I2k2?
+ D
kx
jj , ky
jj
2
on the Fermi surface k
||
x
y
x,k
k
||
k
| _
D(k
||
||
y)
Compute density of states:
g(E) =
Z Z Z
d(Ek E)dkx dky dkz
back
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 107 / 119
196. Shallow line nodes in pnictides
back
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197. Logarithm ) power law (n 1 = 0.8)
The power-law expression is asymptotically very good at E ! 0:
back
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198. Logarithm ) power law (n 1 = 0.4)
The power-law expression is asymptotically very good at E ! 0:
back
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 110 / 119
199. LaNiC2 – a weakly-correlated, paramagnetic
superconductor?
specific heat susceptibility
0 = 6.5 mJ/mol K2
Tc=2.7 K
W. H. Lee et al., Physica C 266, 138 (1996)
V. K. Pecharsky, L. L. Miller, and Zy, Physical Review B 58, 497 (1998)
ΔC/TC=1.26
(BCS: 1.43)
c 0 = 22.2 10-6 emu/mol
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 111 / 119
200. Relaxation due to electronic moments
Moment
size
~ 0.1G
(~ 0.01μB
)
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
(longitudinal)
_
e
e
backward
detector
Timescale:
10-4s
~
forward
detector
sample
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 112 / 119
201. Relaxation due to electronic moments
Moment
size
~ 0.1G
(~ 0.01μB
)
(longitudinal)
Spontaneous, quasi-static fields appearing at Tc
⇒ superconducting state breaks time-reversal symmetry
Hillier, Quintanilla Cywinski,
PRL 102 117007 (2009)
[ c.f. Sr2RuO4 - Luke et al., Nature (1998) ]
_
e
e
backward
detector
Timescale:
10-4s
~
forward
detector
sample
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 113 / 119
202. LaNiC2 is a non-ceontrsymmetric superconductor
Neutron diffraction
35000
30000
25000
20000
15000
10000
5000
0
30 40 50 60 70 80
Intensity (arb units)
o
2
Orthorhombic Amm2 C
2v
a=3.96 Å
b=4.58 Å
c=6.20 Å
Data from
D1B @ ILL
Note no inversion centre.
C.f. CePt
Si (1), Li
3
Pt
2
B Li
3
Pd
2
B (2), ...
3
(1) Bauer et al. PRL’04 (2) Yuan et al. PRL’06
back
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 114 / 119
203. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
C
2v,Jno t
Gap function,
singlet component
Gap function,
triplet component
A
(k) = A d(k) = (Bk
1
,Ck
y
,Dk
x
k
x
k
y
z
)
A
2 (k) = Ak
k
x
Y
d(k) = (Bk
,Ck
x
,Dk
y
z
)
B
1 (k) = Ak
k
X
Z
d(k) = (Bk
k
x
k
y
z
,Ck
z
,Dk
)
y
B
2 (k) = Ak
k
Y
Z
d(k) = (Bk
, Ck
z
k
x
k
y
,Dk
z
)
x
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 115 / 119
204. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
The role of spin-orbit coupling (SOC)
C
2v,Jno t
Gap function,
singlet component
Gap function,
triplet component
A
(k) = A d(k) = (Bk
1
,Ck
y
,Dk
x
k
x
k
y
z
)
A
2 (k) = Ak
k
x
Y
d(k) = (Bk
,Ck
x
,Dk
y
z
)
B
1 (k) = Ak
k
X
Z
d(k) = (Bk
k
x
k
y
z
,Ck
z
,Dk
)
y
B
2 (k) = Ak
k
Y
Z
d(k) = (Bk
, Ck
z
k
x
k
y
,Dk
z
)
x
None of these break time-reversal symmetry!
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 116 / 119
205. Virginia Tech, 18 March 2011 blogs.kent.ac.uk/strongcorrelations
Relativistic and non-relativistic
instabilities: a complex relationship
singlet
Pairing
instabilities
non-unitary
triplet
pairing
instabilities
unitary
triplet
pairing
instabilities
A1 B1
1A1 1A2
3B1(b)
3B2(b)
3A1(a) 3A2(a)
A2 B2
1B1 1B2
3A1(b)
3A2(b)
3B1(a) 3B2(a)
Quintanilla, Hillier, Annett and Cywinski,
PRB 82, 174511 (2010)
Jorge Quintanilla (Kent and RAL) www.cond-mat.org Dresden 2014 117 / 119
206. Li2PdxPt3xB: Phase diagram
Bogoliubov Hamiltonian with Rashba spin-orbit coupling:
H(k) =
h(k) D(k)
D†(k) hT (k)
h(k) = #k I + gk s
Assuming j#kj jgkj jd (k)j the quasi-particle spectrum is
E =
8
:
q
(#k m + jgk j)2 + (D0 + jd(k)j)
2; and
q
(#k m jgk j)2 + (D0 jd(k)j)
2 .
Take the most symmetric (A1) irreducible representation
d(k)/D0 = A (X,Y , Z) B
X
Y 2 + Z2,Y
Z2 + X2
, Z
X2 + Y 2
back
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