Reconfigurable graphene complex oxide nanostructures

Guo, Qing (2020) Reconfigurable graphene complex oxide nanostructures. Doctoral Dissertation, University of Pittsburgh. (Unpublished)

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Abstract

Graphene and complex-oxide heterostructures collectively exhibit nearly all of the known major properties in solid-state materials. Our goal is to integrate these two materials to create new emergent properties and functionalities. A new wet graphene transfer method is
developed and used to integrate graphene with the complex-oxide system LaAlO3/SrTiO3. Interactions between the graphene and LaAlO3/SrTiO3 interface are controlled at nanoscale dimensions using a conductive atomic force microscopy technique developed previously for the complex-oxide interface. The resulting hybrid structures exhibit novel and useful electronic and optical properties, many of which depend critically on controlling the chemical potential of graphene relative to the charge-neutrality point. The local density of states can be altered in graphene by programmable changes of the conductance of the complex oxide interface. In one experiment, an edge-mixed quantum Hall effect is observed in sketched graphene/complex-oxide p-n junction devices. Magnetotransport measurements of superlattice structures show characteristic interference features that can be associated with the periodically patterned interface. Coulomb drag measurements between single-layer graphene
and a conductive LaAlO3/SrTiO3 interface is also performed in these hybrid devices. The metallic behavior and high transparency of graphene make it an ideal top electrode for controlling magnetic properties at the LaAlO3/SrTiO3 interface. We discuss possible new directions based on this highly versatile hybrid material platform.

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Details

Item Type:	University of Pittsburgh ETD
Status:	Unpublished
Creators/Authors:	Creators Email Pitt Username ORCID Guo, Qing qig7@pitt.edu qig7
ETD Committee:	Title Member Email Address Pitt Username ORCID Committee Chair Levy, Jeremy jlevy@pitt.edu jlevy Committee Member Petek, Hrvoje petek@pitt.edu petek Committee Member Mong, Roger rmong@pitt.edu rmong Committee Member Badenes, Carlos badenes@pitt.edu badenes Committee Member Fullerton, Susan fullerton@pitt.edu fullerton
Date:	16 September 2020
Date Type:	Publication
Defense Date:	29 May 2020
Approval Date:	16 September 2020
Submission Date:	30 July 2020
Access Restriction:	No restriction; Release the ETD for access worldwide immediately.
Number of Pages:	129
Institution:	University of Pittsburgh
Schools and Programs:	Dietrich School of Arts and Sciences > Physics
Degree:	PhD - Doctor of Philosophy
Thesis Type:	Doctoral Dissertation
Refereed:	Yes
Uncontrolled Keywords:	LAO/STO, Graphene, edge state, p-n junction, coulomb drag
Date Deposited:	16 Sep 2020 13:56
Last Modified:	16 Sep 2020 13:56
URI:	http://d-scholarship.pitt.edu/id/eprint/39492

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