Your search keyword '"Julia C. McCoy"' showing total 5 results

1. Enhancing STEM Education by Integrating Research and Teaching in Photochemistry: An Undergraduate Chemistry Laboratory in Spectroscopy and Photochemistry

Author

Eleanor J. Stelz-Sullivan, Jared M. Racca, Julia C. McCoy, Dana L. Charif, Lajmi Islam, Xiao-Dong Zhou, Barbara Marchetti, and Tolga N. V. Karsili

Subjects

photochemistry, thin-layer chromatography, undergraduate research, laboratory equipment/apparatus, spectroscopy, Education

Abstract

Molecular spectroscopy and photochemistry constitute an integral field in modern chemistry. However, undergraduate level classes provide limited opportunities for hands-on experimentation of photochemistry and photophysics. For this reason, a simple laboratory experiment was designed that may be easily implemented into undergraduate teaching laboratories with the aim of introducing undergraduate students to UV/visible spectroscopy and photochemistry/photophysics and its possible applications. Samples of three unknown sunscreen formulations are given to students and they are asked to use a set of techniques to identify their molecular composition and to test their efficacy using basic laboratory equipment available to them. In particular, the students are asked to complete the following tasks: (i) sample preparation using solvent extraction to extract active ingredients from the sunscreen lotion, (ii) identify the extracted molecular sunscreen constituents by Thin Layer Chromatography (TLC) and UV/visible spectroscopy, and finally (iii) study their photostability by means of steady state irradiation coupled with UV/visible spectroscopy. The students were provided with the following tools for data collection: silica-backed TLC plates, a short-wave lamp (254 nm, for TLC analysis), a UV-Vis spectrophotometer with an associated computer and software, and an LED lamp (315 nm) to irradiate the samples. Combined TLC and UV-Vis spectroscopy allowed the students to identify the extracted ingredients. UV irradiation confirmed the photostability of sunscreens.

Published

2022

2. Modeling the Conformer-Dependent Electronic Absorption Spectra and Photolysis Rates of Methyl Vinyl Ketone Oxide and Methacrolein Oxide

Author

Julia C. McCoy, Spencer J. Léger, Conrad F. Frey, Michael F. Vansco, Barbara Marchetti, and Tolga N. V. Karsili

Subjects

Photolysis, Oxides, Acrolein, Electronics, Physical and Theoretical Chemistry, Butanones

Abstract

Criegee intermediates are important atmospheric oxidants, formed via the reaction of ozone with volatile alkenes emitted into the troposphere. Small Criegee intermediates (e.g., CH

Published

2022

3. A Simple and Efficient Method for Simulating the Electronic Absorption Spectra of Criegee Intermediates: Benchmarking on CH2OO and CH3CHOO

Author

Mushir Thodika, Barbara Marchetti, Tolga N. V. Karsili, and Julia C. McCoy

Subjects

Molecular complexity, 010304 chemical physics, Absorption spectroscopy, Computational chemistry, Simple (abstract algebra), Chemistry, 0103 physical sciences, Photodissociation, Electronic structure, Physical and Theoretical Chemistry, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences

Abstract

Criegee intermediates (CIs) play a vital role in the atmosphere-known most prominently for enhancing the oxidizing capacity of the troposphere. Knowledge of their electronic absorption spectra is of vital importance for two reasons: (1) to aid experimentalists in detecting CIs and (2) in deciding if their removal is affected by solar photolysis. In this article we report a simple and efficient method based on the nuclear ensemble method that may be effectively used to compute the electronic absorption spectra of Criegee intermediates without the need for extensive computation of preparing the initial configurations of the starting geometry. We use this method to benchmark several excited-state electronic structure methods and their efficacy in reproducing the electronic absorption spectra of two well-known cases of CI: CH2OO and CH3CHOO. The success and computational feasibility of the methodology are crucial for its applicability to CIs of increasing molecular complexity, which have no known experimentally measured electronic absorption spectra, allowing a guide for experimentalists. Application of the methodology to more complex CIs (e.g., those with extended conjugation or those derived from endocyclic alkenes) will also reveal if solar photolysis becomes a competitive removal process when compared to unimolecular decay or bimolecular chemistry.

Published

2021

4. Affordable Setup for Studying Photochemistry in Action in Undergraduate Teaching Laboratories: Principles and Applications

Author

Lori M. Bailey, Ryan L. Simon, Barbara Marchetti, Tolga N. V. Karsili, Jennifer B. Tran, Brody P. McDaniel, and Julia C. McCoy

Subjects

Action (philosophy), Field (physics), Undergraduate research, Cost effectiveness, General Chemistry, Photochemistry, Education

Abstract

Molecular photochemistry is an integral field in chemistry. Despite this, it is often difficult to demonstrate an effective hands-on experiment that offers a unique opportunity to students to obser...

Published

2020

5. A Simple and Efficient Method for Simulating the Electronic Absorption Spectra of Criegee Intermediates: Benchmarking on CH

Author

Julia C, McCoy, Barbara, Marchetti, Mushir, Thodika, and Tolga N V, Karsili

Abstract

Criegee intermediates (CIs) play a vital role in the atmosphere-known most prominently for enhancing the oxidizing capacity of the troposphere. Knowledge of their electronic absorption spectra is of vital importance for two reasons: (1) to aid experimentalists in detecting CIs and (2) in deciding if their removal is affected by solar photolysis. In this article we report a simple and efficient method based on the nuclear ensemble method that may be effectively used to compute the electronic absorption spectra of Criegee intermediates without the need for extensive computation of preparing the initial configurations of the starting geometry. We use this method to benchmark several excited-state electronic structure methods and their efficacy in reproducing the electronic absorption spectra of two well-known cases of CI: CH

Published

2021