Dr. Haleigh Boswell, Research Chemist at Chevron, joins the Concentrating on Chromatography podcast to discuss her fascinating career journey and cutting-edge analytical work in the energy industry. In this in-depth interview, Dr. Boswell shares:🔬 Technical Insights:- How two-dimensional gas chromatography (GCxGC) differs from traditional GC and why it's revolutionary for complex sample analysis- Applications of GCxGC in analyzing hydrocarbon and renewable matrices- Detector selection strategies (FID, SCD, NCD, TOF-MS) for different analytical challenges- Sample preparation considerations for complex energy industry matrices🎯 Industry Applications:- Real-world problem-solving in refinery operations and catalyst development- Non-targeted analysis for trace contaminants in renewable feedstocks- Process optimization and quality control in energy production- Safety considerations and instrument maintenance in industrial settings📈 Career Journey:- Transition from forensic science undergraduate studies to analytical chemistry- Moving from academia to industry: challenges and adaptations- The importance of networking in scientific careers- Advice for graduate students considering industry positions🏢 Behind the Scenes at Chevron:- Day-to-day responsibilities as a subject matter expert (SME)- Collaborative work across multiple R&D teams- Modernizing analytical instrumentation in a legacy company- Balancing innovation with business needs and safety requirementsThis episode provides valuable insights for analytical chemists, graduate students, and anyone interested in the practical applications of advanced chromatography techniques in industrial settings[#Chromatography #AnalyticalChemistry #EnergyIndustry #GCxGC #CareerAdvice #ChemistryPodcast

In this episode of Concentrating on Chromatography, host David Oliva interviews Dr. Petr Vozka, Assistant Professor at California State University, Los Angeles, about his journey establishing the Complex Chemical Composition Analysis Lab (C³AL).Dr. Vozka shares how he built his research facility during the pandemic, focusing on creating opportunities for first-generation and underrepresented undergraduate students. Learn about the groundbreaking LECO-C³AL partnership that provides students with hands-on experience using advanced comprehensive two-dimensional gas chromatography (GC×GC) instrumentation.The conversation explores:- Building a cutting-edge analytical chemistry lab during challenging circumstances- Creating research opportunities for underrepresented undergraduate students- The innovative fingerprint aging research in collaboration with the Hertzberg-Davis Forensic Science Center- How multidimensional chromatography enables detection of thousands of compounds in complex mixtures- The workflow for analyzing fingerprint samples using GC×GC-TOFMS- The advantages of nitrogen generators in laboratory settingsDr. Vozka also discusses the upcoming 17th Multidimensional Chromatography Workshop (MDCW), a FREE conference taking place January 13-15, 2026, in Williamsburg, VA, bringing together experts in multidimensional separation techniques.Visit Dr. Vozka's lab website: https://www.calstatela.edu/research/c3alLearn more about MDCW: https://www.multidimensionalchromatography.com/#Chromatography #GCGC #ForensicScience #AnalyticalChemistry #Fingerprints #MDCW #CalStateLA

Eugene Oga, a PhD student in Analytical Chemistry at the University of North Dakota, joins David Oliva to discuss his innovative research on silicone sealant degradation using evolved gas analysis and thermal desorption-pyrolysis gas chromatography. With his background in materials chemistry and current focus on analytical techniques, Eugene shares insights into how these advanced methods can characterize material breakdown over time, with significant implications for the construction industry and beyond.Eugene's Background and Research FocusEugene Oga is pursuing his PhD in Analytical Chemistry at the University of North Dakota, following his Bachelor's and Master's degrees from the University of Buea in Cameroon. His academic journey began with a focus on materials chemistry before transitioning to analytical chemistry, recognizing that material properties and performance depend heavily on proper characterization.His current research employs advanced analytical techniques like evolved gas analysis and pyrolysis gas chromatography to understand how materials break down over time and identify the specific fragments produced during degradation. This work aims to provide recommendations to manufacturers about potential improvements to their processes.Understanding Structural Sealant Glazing and Its ImportanceStructural Sealant Glazing (SSG) plays a critical role in modern construction, particularly in buildings that extensively use glass and metal. Eugene explains that sealants are thick liquids used to bind different construction materials together.These sealants serve multiple important functions, including preventing air infiltration, moisture penetration, and enhancing building stability. While studies have estimated how long sealants and buildings should last, they often don't explain the actual breakdown mechanisms. Eugene's research aims to fill this gap by identifying which components are lost over time and how this degradation occurs, ultimately enabling better prediction of failure and development of solutions.Different Failure Modes and Analytical ApproachesEugene identifies several categories of sealant failure that require different analytical approaches:1. Adhesive/cohesive failures: These occur when materials don't properly bind together, often due to surface preparation issues that can be addressed through proper cleaning.2. Chemical degradation: This includes processes like UV exposure, hydrolysis, and oxidation.3. Environmental factors: Temperature fluctuations, moisture, and pollutants can contribute to degradation.4. Physical degradation: Manifesting as cracking, fatigue, and creep.While mechanical analysis can identify physical changes like cracking and strength loss, it doesn't reveal which chemical components are being lost. For all these failure modes, gas chromatography and mass spectrometry prove essential.In all of these different failure modes and causes, gas chromatography and mass spectrometry would be very important to identify the volatile degradation products and the changes that are accompanying the backbone.Innovative Methodological ApproachEugene's research employs a two-step analytical approach that modifies standard GC-MS protocols to accommodate siloxane chemistry:1. Evolved Gas Analysis (EGA-MS): This serves as a rapid screening technique to identify temperature ranges where components evolve.2. Thermal Desorption-Pyrolysis GC-MS: This follows as a verification tool, focusing on the specific temperature zones identified by EGA to perform detailed analysis of components evolving at different temperatures.This sequential approach allows for more targeted analysis and better characterization of degradation products. The method is particularly valuable because it eliminates extensive sample preparation—samples can be analyzed as received, saving significant time and reducing potential preparation errors.