Time Domain Spectroscopy of Graphene

This dissertation describes the response of graphene and graphene fragments to ultrafast optical pulses. I will first describe how we created few-cycle optical pulses for interacting with the graphene lattice. These pulses are created through filamentation based pulse compression. I studied how t...

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Bibliographic Details
Main Author: Roberts, Adam
Other Authors: Sandhu, Arvinder
Language:en
Published: The University of Arizona. 2012
Subjects:
Online Access:http://hdl.handle.net/10150/228120
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spelling ndltd-arizona.edu-oai-arizona.openrepository.com-10150-2281202015-10-23T04:55:54Z Time Domain Spectroscopy of Graphene Roberts, Adam Sandhu, Arvinder Jones, Jason Binder, Rolf Sandhu, Arvinder Optical Sciences This dissertation describes the response of graphene and graphene fragments to ultrafast optical pulses. I will first describe how we created few-cycle optical pulses for interacting with the graphene lattice. These pulses are created through filamentation based pulse compression. I studied how the filamentation process can be optimized through simple means to create the shortest possible pulse. I then examine the extent to which graphene can withstand irradiation from intense ultra-fast pulses. I examine both the high intensity regime at which a single laser pulse will ablate the graphene and a more moderate regime that slowly degrades the graphene from long term exposure to ultrafast pulses. The knowledge lets us both identify a safe working regime for driving the graphene lattice with optical fields as well as use ultrafast lasers to create graphene nano-fragments down to 2nm. Next, I explore the ultrafast dynamics of photo-excited graphene. Graphene undergoes electronic band renormalization after photo exciting carriers. By measuring a differential transmission spectrum, small changes to the band structure can be quantified. I will explain how screened exchange and electron phonon self energies provide corrections to the band structure for different times after carrier excitation. Lastly, I will describe measurements that determine the extent of electron-electron correlations in graphene fragments. By measuring the energy of the two photon state and comparing it the lowest energy one photon state in graphene fragments, we can determine the strength of the correlations in graphene systems. 2012 text Electronic Dissertation http://hdl.handle.net/10150/228120 en Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author. The University of Arizona.
collection NDLTD
language en
sources NDLTD
topic Optical Sciences
spellingShingle Optical Sciences
Roberts, Adam
Time Domain Spectroscopy of Graphene
description This dissertation describes the response of graphene and graphene fragments to ultrafast optical pulses. I will first describe how we created few-cycle optical pulses for interacting with the graphene lattice. These pulses are created through filamentation based pulse compression. I studied how the filamentation process can be optimized through simple means to create the shortest possible pulse. I then examine the extent to which graphene can withstand irradiation from intense ultra-fast pulses. I examine both the high intensity regime at which a single laser pulse will ablate the graphene and a more moderate regime that slowly degrades the graphene from long term exposure to ultrafast pulses. The knowledge lets us both identify a safe working regime for driving the graphene lattice with optical fields as well as use ultrafast lasers to create graphene nano-fragments down to 2nm. Next, I explore the ultrafast dynamics of photo-excited graphene. Graphene undergoes electronic band renormalization after photo exciting carriers. By measuring a differential transmission spectrum, small changes to the band structure can be quantified. I will explain how screened exchange and electron phonon self energies provide corrections to the band structure for different times after carrier excitation. Lastly, I will describe measurements that determine the extent of electron-electron correlations in graphene fragments. By measuring the energy of the two photon state and comparing it the lowest energy one photon state in graphene fragments, we can determine the strength of the correlations in graphene systems.
author2 Sandhu, Arvinder
author_facet Sandhu, Arvinder
Roberts, Adam
author Roberts, Adam
author_sort Roberts, Adam
title Time Domain Spectroscopy of Graphene
title_short Time Domain Spectroscopy of Graphene
title_full Time Domain Spectroscopy of Graphene
title_fullStr Time Domain Spectroscopy of Graphene
title_full_unstemmed Time Domain Spectroscopy of Graphene
title_sort time domain spectroscopy of graphene
publisher The University of Arizona.
publishDate 2012
url http://hdl.handle.net/10150/228120
work_keys_str_mv AT robertsadam timedomainspectroscopyofgraphene
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