Observation of Superconductivity in Epitaxially Grown Atomic Layers

1 Introduction1.1 Historical background1.1.1 Two-dimensional electron systems1.1.2 Surface superstructures1.1.3 Superconductivity1.1.4 Two-dimensional superconductivity1.1.5 Superconductivity in surface states1.1.6 Atomic thick superconductors1.2 Direction of this study1.3 Structure of this thesisReferences2 Fundamentals2.1 Surface electronic states and spatial inversion symmetry2.1.1 Rashba effect2.2 Electrical transport2.2.1 Drude model2.2.2 Boltzmann equation2.2.3 Matthiessen's low2.2.4 Ioffe-Regel limit2.3 Basic properties of superconductivity2.3.1 London equation2.3.2 GL theory2.3.3 BCS theory2.3.4 Josephson effect and critical current2.4 Special cases of superconductivity2.4.1 Strong coupled superconductor2.4.2 Two-dimensional superconductivity2.4.3 Disorder-induced superconductor-insulator transition2.4.4 Superconductivity without spatial inversion symmetryReferences3 Experimental methods3.1 Electron diffraction3.2 Electrical transport measurement3.3 Experimental appratusReferences4 Thallium biatomic layer4.1 Background4.2 Structual properties of Si(111) - 6×6 - Tl4.2.1 Atomic arrangement4.2.2 Electronic structure4.3 Purpose of this study4.4 Electrical transport studies on Si(111) - 6×6 - Tl4.4.1 Sample preparation4.4.2 Results4.4.3 Discussion4.5 SummaryReferences5 Thallium-lead monatomiclayer compound5.1 Background5.2 Structual properties of Si(111) - √ 3× √ 3 - (Tl, Pb)5.2.1 Atomic arrangement5.2.2 Electronic structure5.3 Purpose of this study5.4 Electrical transport studies on Si(111) -√ 3× √ 3 - (Tl, Pb)5.4.1 Sample preparation5.4.2 Results5.4.3 Discussion5.5 SummaryReferences6 Intercalation Compounds of Bilayer Graphene6.1 Background6.1.1 Graphaite intercalation compounds6.1.2 Metal doping to graphene6.2 Structual properties of Intercalation Compounds of Bilayer Graphene6.2.1 Graphene on SiC6.2.2 Atomic arrangement6.2.3 Electronic structure6.3 Porpose of this study6.4 Electrical transport studies on intercalation compounds of bilayer graphene6.4.1 Sample preparation6.4.2 Results on pristine bilayer graphene6.4.3 Results on C 6 LiC 6 and C 6 CaC 66.4.4 Discussion6.5 SummaryReferences7 Conclusion7.1 General statement7.1.1 Electronic structure and superconductivity7.1.2 Two-dimensionality7.2 OutlookReferences

About the Author:

Satoru Ichinokura, a post-doctoral researcher of the Japan Society for the Promotion of Science (JSPS) at The University of Tokyo, is an experimentalist in surface physics and nanotechnology. His work is concerned with atomic-scale thin layer systems such as graphene, transition metal dichalcogenides, and metal-induced surface reconstructions on semiconductors. He is interested particularly in spintronics aspects and low-temperature properties of those materials, represented by superconductivity, and approaches them by electric transport measurements and scanning tunneling microscopy.

Satoru Ichinokura received both his Bachelor of Physics and Master of Science in physics from Tohoku University in 2011 and 2013, respectively. Thereafter he joined the group led by Professor Shuji Hasegawa in the Department of Physics, The University of Tokyo, and received his Ph.D. in physics from The University of Tokyo in 2016. During his Master's program, he received a research grant of Global Centers of Excellence Program from Tohoku University in 2012. During his doctoral program, he received a travel award and student award from the Surface Science Society and a Graduate School of Science award from the School of Science, The University of Tokyo, in 2014, 2015, and 2016, respectively. He was also awarded a research fellowship for young scientists from JSPS, and his research was supported by the JSPS between April 2015 and March 2017.