eprintid: 7771
rev_number: 5
userid: 6
dir: disk0/00/00/77/71
datestamp: 2011-11-10 19:43:28
lastmod: 2016-11-15 13:43:08
status_changed: 2011-11-10 19:43:28
type: thesis_degree
metadata_visibility: show
contact_email: pem26@pitt.edu
item_issues_count: 0
eprint_status: archive
creators_name: Maksymovych, Petro
creators_email: pem26@pitt.edu
creators_id: PEM26
title: NOVEL SURFACE CHEMISTRY OF SINGLE MOLECULES AND SELF-ASSEMBLEDSTRUCTURES BY SCANNING TUNNELING MICROSCOPY
ispublished: unpub
divisions: sch_as_chemistry
full_text_status: public
keywords: alkanethiol; gold; hot-electron; microscopy; self-assembly; STM; tunneling
abstract: This thesis demonstrates the richness of Scanning Tunneling Microscopy (STM) as amethod to understand surface chemistry and physics and to explore the new frontiers in singlemoleculesurface reactions and molecular self-assembly. Organosulfur molecules on the Au(111)surface were studied to address unresolved and controversial issues about self-assembledmonolayers of alkanethiol molecules on gold surfaces. The key new finding is that the thermalsurface chemistry of alkanethiol molecules occurs in a dynamic chemical environment thatinvolves reactive gold adatoms to which the alkanethiol molecules chemically bond. Theproblem of alkanethiol self-assembly is thus transformed from the realm of adsorption on asurface toward organometallic surface chemistry, which is anticipated to have broad implicationsfor the field. Molecules containing a disulfide (S-S) bond were also found to be a spectacularmodel system for exploring electron-induced surface chemistry. In particular, the atomicallylocalizedinjection of electrons from the metal tip of the tunneling microscope is capable ofproducing highly delocalized chemical reactions by means of surface current of hot-electrons.Chemical reactions can therefore be a unique approach to the measurement of the local transportof hot-electrons on metal surfaces. Finally the concepts of self-assembly and electron-inducedchemistry are combined through an observation of an unusual process that flips the chirality ofmolecules self-assembled on the surface by a radical-like chain reaction. This experimentdemonstrates how self-assembly enables a new reaction coordinate by optimizing the stericfactor of the chemical reaction.
date: 2007-06-22
date_type: completed
institution: University of Pittsburgh
refereed: TRUE
etdcommittee_type: committee_chair
etdcommittee_type: committee_member
etdcommittee_type: committee_member
etdcommittee_type: committee_member
etdcommittee_name: Yates, John T
etdcommittee_name: Waldeck, David H
etdcommittee_name: Pratt, David
etdcommittee_name: Petek, Hrvoje
etdcommittee_email: johnt@virginia.edu
etdcommittee_email: dave@pitt.edu
etdcommittee_email: pratt@pitt.edu
etdcommittee_email: petek@pitt.edu
etdcommittee_id: 
etdcommittee_id: DAVE
etdcommittee_id: PRATT
etdcommittee_id: PETEK
etd_defense_date: 2007-04-25
etd_approval_date: 2007-06-22
etd_submission_date: 2007-05-03
etd_access_restriction: 5_year
etd_patent_pending: FALSE
assigned_doi: doi:10.5195/pitt.etd.2011.7771
thesis_type: dissertation
degree: PhD
committee: Prof. John T. Yates, Jr. (johnt@virginia.edu) - Committee Chair
committee: Prof. David H. Waldeck (dave@pitt.edu) - Committee Member
committee: Prof. David Pratt (pratt@pitt.edu) - Committee Member
committee: Prof. Hrvoje Petek (petek@pitt.edu) - Committee Member
etdurn: etd-05032007-155723
other_id: http://etd.library.pitt.edu/ETD/available/etd-05032007-155723/
other_id: etd-05032007-155723
citation:   Maksymovych, Petro  (2007) NOVEL SURFACE CHEMISTRY OF SINGLE MOLECULES AND SELF-ASSEMBLEDSTRUCTURES BY SCANNING TUNNELING MICROSCOPY.  Doctoral Dissertation, University of Pittsburgh.    (Unpublished)  
document_url: http://d-scholarship-dev.library.pitt.edu/7771/1/thesis1.pdf