Scanning Probe Microscopy Investigation of Hybrid Nano Systems Comprising Functional Molecules and Two-Dimensional Layers
Translated title:
Rastersondenmikroskop Untersuchung von Hybriden Nanosystemen Bestehend aus Funktionalen Molekülen und Zweidimensionalen Schichten
Author:
Ducke, Jacob Steffen
Year:
2018
Document type:
Dissertation
Faculty/School:
Fakultät für Physik
Advisor:
Auwärter, Wilhelm (Prof. Dr.)
Referee:
Auwärter, Wilhelm (Prof. Dr.); Simmel, Friedrich C. (Prof. Dr.)
Language:
en
Subject group:
PHY Physik
TUM classification:
PHY 650d; WER 000d
Abstract:
In this work, state-of-the-art scanning probe microscopy is used to investigate the interactions between functional molecules and two-dimensional materials at the atomic scale. The fundamental understanding of such hybrid systems is essential for the bottom-up fabrication of nano electronic devices. I.a., we introduce a scalable method to assemble layered heterostructures via porphine intercalation, and develop novel reactions for the on-surface synthesis of covalent nanostructures on h-BN/Cu(111).
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In this work, state-of-the-art scanning probe microscopy is used to investigate the interactions between functional molecules and two-dimensional materials at the atomic scale. The fundamental understanding of such hybrid systems is essential for the bottom-up fabrication of nano electronic devices. I.a., we introduce a scalable method to assemble layered heterostructures via porphine intercalation, and develop novel reactions for the on-surface synthesis of covalent nanostructures on h-BN/Cu(11...
»
Translated abstract:
In dieser Arbeit wird ein state-of-the-art Rastersondenmikroskop verwendet um die Wechselwirkungen von funktionalen Molekülen mit zweidimensionalen Materialien auf atomarer Skala zu untersuchen. Das fundamentale Verständnis solcher Hybridsysteme ist essentiell für die Bottom-Up Fabrikation nanoelektronischer Strukturen. U.a., führen wir eine skalierbare Methode zur Herstellung von geschichteten Heterostrukturen via Porphine Interkalation ein und entwickeln neue Reaktionen für die Oberflächensynthese von kovalenten Nanostrukturen auf h-BN/Cu(111).