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» Authors » Michael L Myrick

Michael L Myrick

Explore the profile of Michael L Myrick including associated specialties, affiliations and a list of published articles. Areas
Snapshot
Articles 38
Citations 36
Followers 0
Related Specialties
Chemistry
Pathology
Biotechnology
Top 10 Co-Authors
Stephen L Morgan
Tammi L Richardson
Brianna M Cassidy
Stephanie A DeJong
Zhenyu Lu
Timothy J Shaw
Heather Brooke
Jessica N McCutcheon
Megan R Pearl
Caitlyn M English
Published In
Appl Spectrosc
Anal Chem
Appl Opt
J Nanosci Nanotechnol
Rev Sci Instrum
Affiliations
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Recent Articles
1.
Using Polarization to Increase Contrast of Water OH Raman Scattering Relative to Fluorescence of Dissolved Organic Matter
Twining C, Williams P, Schuler W, English C, Richardson T, Myrick M
Appl Spectrosc . 2024 Dec; :37028241303944. PMID: 39686593
Environmental fluorescence measurements sometimes use water Raman scattering as an internal standard to compensate for path length, lensing effects, and turbidity. Fluorescent dissolved organic matter (FDOM) in water may interfere...
2.
Filter Fluorometer Calibration Without the Fluorometer
English C, Kitzhaber Z, Sanim K, Vitzilaios N, Hodgson M, Richardson T, et al.
Appl Spectrosc . 2023 Jun; 77(9):1053-1063. PMID: 37350765
We recently described a lightweight, low-power, waterproof filter fluorometer using a 180° backscatter geometry for chlorophyll-a (chl-) detection. Before it was constructed it was modeled to ensure it would have...
3.
Fluorometer Control and Readout Using an Arduino Nano 33 BLE Sense Board
Kitzhaber Z, English C, Sanim K, Kalaitzakis M, Kosaraju B, Hodgson M, et al.
Appl Spectrosc . 2022 Oct; 77(2):220-224. PMID: 36197285
We describe the control and interfacing of a fluorometer designed for aerial drone-based measurements of chlorophyll- using an Arduino Nano 33 BLE Sense board. This 64 MHz controller board provided...
4.
Chlorophyll Fluorometer for Intelligent Water Sampling by a Small Uncrewed Aircraft System (sUAS)
English C, Kitzhaber Z, Sanim K, Kalaitzakis M, Kosaraju B, Pinckney J, et al.
Appl Spectrosc . 2022 Sep; 77(1):94-105. PMID: 36065908
We describe a waterproof, lightweight (1.3 kg), low-power (∼1.1 W average power) fluorometer operating on 5 V direct current deployed on a small uncrewed aircraft system (sUAS) to measure chlorophyll...
5.
Diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) detection limits for blood on fabric: Orientation and coating uniformity effects
McCutcheon J, Trimboli A, Pearl M, Brooke H, Myrick M, Morgan S
Sci Justice . 2021 Sep; 61(5):603-616. PMID: 34482941
Diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) was used to analyze four types of forensically relevant fabrics coated with varying dilutions of blood. The blood was applied in two manners,...
6.
Direct Identification of Mixed-Metal Centers in Metal-Organic Frameworks: Cu(BTC) Transmetalated with Rh Ions
Metavarayuth K, Ejegbavwo O, McCarver G, Myrick M, Makris T, Vogiatzis K, et al.
J Phys Chem Lett . 2020 Sep; 11(19):8138-8144. PMID: 32894952
Raman spectroscopy was used to establish direct evidence of heterometallic metal centers in a metal-organic framework (MOF). The Cu(BTC) MOF HKUST-1 (BTC = benzenetricarboxylate) was transmetalated by heating it in...
7.
In Situ Methane Determination in Petroleum at High Temperatures and High Pressures with Multivariate Optical Computing
Jones C, Price J, Dai B, Li J, Perkins D, Myrick M
Anal Chem . 2019 Oct; 91(24):15617-15624. PMID: 31660727
Multivariate optical computing (MOC) is a compressed sensing technique enabling the measurement of analytes in a complex interfering mixture under harsh conditions. In this work, we describe the design, modeling,...
8.
A New Multivariate Optical Computing Microelement and Miniature Sensor for Spectroscopic Chemical Sensing in Harsh Environments: Design, Fabrication, and Testing
Jones C, Dai B, Price J, Li J, Pearl M, Soltmann B, et al.
Sensors (Basel) . 2019 Feb; 19(3). PMID: 30744066
Multivariate optical computing (MOC) is a compressed sensing technique with the ability to provide accurate spectroscopic compositional analysis in a variety of different applications to multiple industries. Indeed, recent developments...
9.
Single-Cell and Bulk Fluorescence Excitation Signatures of Seven Phytoplankton Species During Nitrogen Depletion and Resupply
Faulkner S, Rekully C, Lachenmyer E, Kara E, Richardson T, Shaw T, et al.
Appl Spectrosc . 2018 Oct; 73(3):304-312. PMID: 30345799
Phytoplankton play a vital role as primary producers in aquatic ecosystems. One common approach to classifying phytoplankton is fluorescence excitation spectroscopy, which leverages the variation in types and concentrations of...
10.
Fluorescence Excitation Spectroscopy for Phytoplankton Species Classification Using an All-Pairs Method: Characterization of a System with Unexpectedly Low Rank
Rekully C, Faulkner S, Lachenmyer E, Cunningham B, Shaw T, Richardson T, et al.
Appl Spectrosc . 2017 Oct; 72(3):442-462. PMID: 29069908
An all-pairs method is used to analyze phytoplankton fluorescence excitation spectra. An initial set of nine phytoplankton species is analyzed in pairwise fashion to select two optical filter sets, and...