visual
visual
Development fund

Development
fund
gogle

세미나

  • HOME
  • >
  • 소식
  • >
  • 세미나

Spectroscopic studies of iron-based superconductors : what have we learned?

2016.04.07 12:57

Physics 조회 수:75

seminar Date  
Date & Time Apr. 08 (Fri.), 4:00 PM 
Venue E6-2. 5st fl. #1501 
Speaker Dr. Changyoung Kim, SEOUL NATIONAL UNIV. 

“Spectroscopic studies of iron-based superconductors : what have we learned?”

 

Apr. 08 (Fri.), 4:00 PM, E6-2. 5st fl. #1501
Dr. Changyoung Kim, SEOUL NATIONAL UNIV.


As in the cases for other materials, measuring the electronic structures is the first step towards understanding the microscopic mechanism for the superconductivity in of iron-based superconductors (IBS). Angle resolved photoelectron spectroscopy (ARPES) has played a key role in the studies of IBS, from band structure determination to superconducting gap measurements.

In this presentation, I will give an overview on the spectroscopic studies of IBS by using ARPES including recent progress on 100K superconductivity in mono-layer FeSe. I will start with a brief description of the general electronic structures (band dispersions and Fermi surfaces) and orbital characters of bands measured by ARPES. The main part of the presentation will be on two subjects, namely, nematic order and mono-layer superconductivity. The anisotropic electronic structure of the nematic order can be investigated by ARPES. In addition, ARPES is also surface sensitive which makes it suitable for the study of mono-layer superconductivity. I will discuss our recent work on these two subjects along with results from other groups.


Contact: Eun Gook Moon, Physics Dept., (egmoon@kaist.ac.kr)

목록
번호 seminar Date Venue 제목
공지     Spring 2019: Physics Seminar Serises
공지     Spring 2019: Physics Colloquium
공지   Seminar Room #1323  Fall 2017: Physics Seminar Serises
공지   Seminar Room 1501  Fall 2017: Physics Colloquium
»   E6-2. 5st fl. #1501  Spectroscopic studies of iron-based superconductors : what have we learned?
40   E6-2. 1st fl. #1322  A new impurity solver for multi-orbital systems: adaptive truncation of the Hilbert space
39   E6-2. 1st fl. #1501  Cotunneling drag effect in Coulomb-coupled quantum dots
38   E6-2. 1st fl. #1501  Interference of single charged particles without a loop and dynamic nonlocality
37   E6-2, RM #1323  Superconducting Quantum Interference Devices for Precision Detection
36   KAIST Natural Science Building (E6-2), RM #4314  Radio frequency engineering
35   E6-2, 1501  Physics Seminar Serises : 2016 Spring file
34   E6-2. 1st fl. #1501  Jan. Switching handedness of of chiral solitons in Z4 topological insulators
33   E6-2. 1st fl. #1501  Topological phases of matter in nonequilibrium: Topology of the Wannier-Stark ladder
32   E6, 1501  Physics Colloquium : 2016 Spring file
31   E6-2, #1323  Electrochemistry on Nano- and Atomic Levels: Scanning Probe Microscopy Meets Deep Data
30   E6-2, #1323  Mott Physics in the Strong Spin-Orbit Coupling Regime
29   E4(KI Building), Maxtrix Hall (2nd fl.)  Wavefront engineering for in-vivo Deep brain imaging
28   E6-2, #1323  Quantum spin liquid in the 1/3 depleted triangular lattice Ba3(Ru1-xIrx)Ti2O9
27   E6-2, #1323  Dynamical mean field theory studies on heavy fermion system
26   E6-2, #1323  SWELLABLE COLLOIDAL PARTICLES ARE SWELL
25   E4(KI Building), Connect room (2nd fl.)  Functional Imaging & Monitoring of Brain & Breast with Diffuse Light
24   E6-2, #1323  Hybrid solid state spin qubits in wide bandgap semiconductors
23   E6-2, #1323  Samarium Hexaboride: Is it a Topological insulator?
22   E6-2, #1323  Introducing extra dimensions to spectroscopic studies of advanced quantum materials
쓰기