eprintid: 38458 rev_number: 16 userid: 9485 dir: disk0/00/03/84/58 datestamp: 2020-07-31 13:16:00 lastmod: 2020-07-31 13:16:00 status_changed: 2020-07-31 13:16:00 type: thesis_degree metadata_visibility: show contact_email: wangyan2487@gmail.com eprint_status: archive creators_name: Wang, Yan creators_email: yaw47@pitt.edu creators_id: yaw47 creators_orcid: 0000-0002-9147-1136 title: Toward Rational Design of Graphene Nanomaterials: Manipulating Chemical Composition to Identify Governing Properties for Electrochemical and Biological Activities ispublished: unpub divisions: sch_eng_civilenvironmental full_text_status: public keywords: Sustainable Material Design, Surface Chemistry, Fuel Cell, Antioxidant Deactivation, Antimicrobial Activity, Density Functional Theory abstract: The unique properties of graphene-based nanomaterials (GMs) have enabled various applications in the fields of electronics, energy, environment, and biotechnology. Yet, their potential inherent hazard poses risks to human health and the environment, which could be a barrier to the success of these applications. A critical underpinning of sustainable material development is rational design. This approach involves the ability to control material outcomes, requiring the establishment of property-function and property-hazard relationships. This dissertation aims to demonstrate an ability to rationally design GMs by manipulating chemical composition and establishing the relationships that correlate material properties to their electrochemical activity (function) and bioactivity (hazard). The electrochemical activity is represented by the material reactivity for important electrochemical reactions (oxygen reduction reaction, ORR and oxygen evolution reaction, OER). The bioactivity is represented as the material propensity to oxidize a cellular biomolecule (glutathione) and inactivate the bacteria (Escherichia coli). Material sets of graphene oxide (GO) and nitrogen-doped graphene (NG) are investigated using various complementary characterization techniques to determine the material properties that govern electrochemical and biological activities as chemical composition changes. The results suggest both activities are governed by synergistic effects from multiple properties, including specific oxygen and nitrogen sites and properties arising as a consequence of changing chemical composition. Enhanced aqueous dispersion and defect density are important for GO bioactivity. Additionally, coupled experimental and computational approaches elucidate the synergistic role of adjacent epoxide and hydroxyl groups on GO in directly oxidizing glutathione. As the surface of GO is reduced, the electrochemical and biological activities are governed by a balance of carbonyl groups and electrical conductivity. For NG, N-types control electrochemical reactions, ORR (graphitic-N) and OER (pyridinic-N). Further, the predominance of graphitic-N enhances oxidative stress-related bioactivity, which is an important contribution since very little is known surrounding NG bioactivity. Collectively, this dissertation supports the use of chemical composition manipulation to control material properties and in turn, function and hazard outcomes. The established property-function and property-hazard relationships provide rational design guidance for GMs. The holistic approach herein is applicable to other nanomaterials and thus, will continue to contribute to the advancement of sustainable nanotechnology. date: 2020-07-31 date_type: published pages: 189 institution: University of Pittsburgh refereed: TRUE etdcommittee_type: committee_chair etdcommittee_type: committee_member etdcommittee_type: committee_member etdcommittee_type: committee_member etdcommittee_type: committee_member etdcommittee_name: Gilbertson, Leanne etdcommittee_name: Kumta, Prashant etdcommittee_name: Mckone, James etdcommittee_name: Ng, Carla etdcommittee_name: Vidic, Radisav etdcommittee_email: leanne.gilbertson@pitt.edu etdcommittee_email: pkumta@pitt.edu etdcommittee_email: jmckone@pitt.edu etdcommittee_email: carla.ng@pitt.edu etdcommittee_email: vidic@pitt.edu etd_defense_date: 2020-03-17 etd_approval_date: 2020-07-31 etd_submission_date: 2020-03-30 etd_release_date: 2020-07-31 etd_access_restriction: immediate etd_patent_pending: FALSE thesis_type: dissertation degree: PhD citation: Wang, Yan (2020) Toward Rational Design of Graphene Nanomaterials: Manipulating Chemical Composition to Identify Governing Properties for Electrochemical and Biological Activities. Doctoral Dissertation, University of Pittsburgh. (Unpublished) document_url: http://d-scholarship-dev.library.pitt.edu/38458/1/wangy_etdPitt2020.pdf