Chemistry

Home » Archives for January 2020

January 2020

Archives for January 2020

Brantley Group Publishes in Polymer Chemistry

by

The Brantley Group published their work “Ion Specific Fluorescence Modulation of Polyvinyl Alcohol-Boronate Matrices” in Polymer Chemistry. Brian Jacobs, graduate student in the Brantley Lab, is the primary author. 

Borylated polymers are emerging as valuable chemosensors that can report analyte binding through an array of responses. Fluorescent materials are particularly valuable in this regard, as modulation of their photophysical properties can facilitate rapid substrate detection and quantitation.

“In this manuscript, we report the condensation of aryl boronic acids onto polyvinyl alcohol (PVA) to afford fluorescent polymers, a phenomenon that has been widely overlooked,” Jacobs said. “ Importantly, selective modulation of the photophysical properties was observed in the presence of borophilic anions (e.g. fluoride, hydroxide, and cyanide).”

Density functional theory (DFT) calculations, performed by collaborator Jacob Townsend in the Vogiatzis Research Group, suggested that a combination of covalent and non-covalent interactions were crucial for anion binding. Time-dependent DFT computations were also performed to explain the appearance of a distinct peak in the polymer’s absorbace profile.

“Lastly, films of these PVA-aryl boronates were employed in ion extraction studies, highlighting a useful secondary function these materials possess,” Jacobs said. “Given the ease with which these polymers can be accessed, they could serve as general platforms for developing ion selective membranes or detectors.”

Learn More

Roy and Long Collaborative Work Published

by

Catalysis Science & Technology published a collaborative piece from the Roy and Long groups titled  “A mechanistic study of microstructure modulation in olefin polymerizations using a redox-active Ni(ii) alpha-diimine catalyst.”

Polyolefins are among the world’s most widely produced and utilized classes of polymers, serving as synthetic alternatives to traditional materials such as wood, glass, and metal. While numerous prior research efforts have focused on the development of faster, more efficient, and less expensive catalysts, recent studies have demonstrated that redox-active olefin polymerization catalysts may also be employed to modulate catalytic activity, reactivity, and selectivity in situ.

The group reports a computational study based on density functional theory designed to better understand the structure and underlying olefin polymerization mechanisms of the active catalytic species in two distinct redox states. These findings are further supported through experimental evidence and suggest that upon activation of the reduced catalyst species, the added electron density of the catalyst is transferred from the active metal center to the alpha-diimine ligand.

The observed decrease in polyethylene branching that results from catalyst reduction is believed to stem from changes in the subtle balance of steric, electronic, and entropic effects, primarily perturbing the coordination of subsequent monomer units. This perturbation is expressed not only in the monomer-inserted-product energy differences but also in the catalysts’ deviation from square planarity about the Ni center. Through these studies, we can better understand how the addition of an electron to a Ni(ii) alpha-diimine catalyst perturbs its catalytic behavior, which may influence the design of future generations of redox-active olefin polymerization catalysts.

Awards Within the Vogiatzis Group

by

The Vogiatzis Group’s research centers on the development of computational methods based on electronic structure theory and machine learning algorithms for describing chemical systems relevant to clean, green technologies. We are particularly interested in new methods for non-covalent interactions and bond-breaking reactions of small molecules with transition metals. Our overall objectives are to elucidate the fundamental physical principles underlying the magnetic, catalytic, and sorption properties of polynuclear systems, as well as to assist in the interpretation of experimental data.

Recent group awards:

    1. Mrs. Alexa Griffith, an undergraduate student pursuing research in my group, was awarded a DAAD exchange fellowship for pursuing research for three months at the Technical University of Kaiserslautern, Germany (2018).
    2. Mr. John Hymel, an undergraduate student pursuing research in the Vogiatzis Group, won the Award of Excellence in Natural Sciences and Office of Research and Engagement Bronze Award at the Exhibition of Undergraduate Research and Creative Achievement (EUReCA) (2018).
    3. Mr. Jacob Townsend, graduate student in the Vogiatzis Group, won the best Lightning Talk Award at PsiCon, the annual Psi4 software developers meeting (2018).
    4. Mr. Grier Jones, graduate student the Vogiatzis Group, received a travel grant from the Molecular Science Software Institute (MolSSI) to attend the MolSSI Workshop: The Open Molecular Science Cloud in Perugia and Rome, Italy (2019).
    5. Ms. Rebekah Duke, REU student who worked in the Vogiatzis Group during Summer 2019, was accepted to present her results that obtained at the University of Tennessee at the Posters on the Hill, an annual undergraduate poster session on Capitol Hill, Washington, DC (2020).