Your search keyword '"Mazzoleni, Lynn R."' showing total 7 results

1. Photochemical mobilization of dissolved hydrocarbon oxidation products from petroleum contaminated soil into a shallow aquifer activate human nuclear receptors

Author

Zito, Phoebe, Bekins, Barbara A., Martinović-Weigelt, Dalma, Harsha, Maxwell L., Humpal, Katherine E., Trost, Jared, Cozzarelli, Isabelle, Mazzoleni, Lynn R., Schum, Simeon K., and Podgorski, David C.

Published

2023

2. Separation of common organic and inorganic anions in atmospheric aerosols using a piperazine buffer and capillary electrophoresis

Author

Noblitt, Scott D., Mazzoleni, Lynn R., Hering, Susanne V., Collett, Jeffrey L., Jr., and Henry, Charles S.

Published

2007

3. Water-soluble organic compounds at a mountain-top site in Colorado, USA

Author

Samy, Shar, Mazzoleni, Lynn R., Mishra, Subhashree, Zielinska, Barbara, and Hallar, Anna G.

Subjects

*SOLUBILITY, *ORGANIC compounds & the environment, *MOUNTAINS, *PARTICULATE matter, *METEOROLOGY, *ATMOSPHERIC aerosols, *WATER chemistry, *CARBOXYLIC acids

Abstract

Abstract: Water extracts of atmospheric particulate matter (PM2.5) collected at the Storm Peak Laboratory (SPL) (3210 MSL, 40.45° N, 106.74° W) were analyzed for a wide variety of polar organic compounds. The unique geographical character of SPL allows for extended observations/sampling of the free tropospheric interface. Under variable meteorological conditions between January 9th and January14th 2007, the most abundant compounds were levoglucosan (9–72 ng m−3), palmitic acid (10–40 ng m−3) and succinic acid (18–27 ng m−3). Of 84 analytes included in the GC–MS method, over 50 individual water extractable polar organic compounds (POC) were present at concentrations greater than 0.1 ng m−3. During a snow event (Jan. 11th–13th), the concentrations of several presumed atmospheric transformation compounds (dicarboxylic acids) were reduced. Lower actinic flux, reduced transport distance, and ice crystal scavenging may explain this variability. Diurnal averages over the sampling period revealed a higher total concentration of water extractable POC at night, 211 ng m−3 (105–265 ng m−3), versus day, 160 ng m−3 (137–205 ng m−3), which suggests a more aged nighttime aerosol character. This may be due to the increased daytime convective mixing of local primary emissions from the Yampa Valley. XAD resin extracts revealed a gas-phase partitioning of several compounds, and analysis of cloud water collected at this site in 2002 revealed a similar compound abundance trend. Levoglucosan, a wood smoke tracer was generally found to be the most abundant compound in both aerosol and cloud water samples. Variations in meteorological parameters and local/regional transport analysis play an important interpretive role in understanding these results. [Copyright &y& Elsevier]

Published

2010

4. Modelling the hygroscopic growth factors of aerosol material containing a large water-soluble organic fraction, collected at the Storm Peak Laboratory.

Author

Clegg, Simon L., Mazzoleni, Lynn R., Samburova, Vera, Taylor, Nathan F., Collins, Don R., Schum, Simeon K., and Hallar, A. Gannet

Subjects

*GROWTH factors, *ATMOSPHERIC aerosols, *AEROSOLS, *CHEMICAL formulas, *SEMIVOLATILE organic compounds, *CARBONACEOUS aerosols, *ORGANIC acids, *COMPLEX compounds

Abstract

The compositions of six aggregated aerosol samples from the Storm Peak Laboratory site have been comprehensively analysed (Hallar et al., 2013), focusing particularly on the large water-extractable organic fraction which consists of both high molecular weight organic compounds and a range of acids and sugar-alcohols. The contribution of the soluble organic fraction of atmospheric aerosols to their hygroscopicity is hard to quantify, largely because of the lack of a detailed knowledge of both composition and the thermodynamic properties of the functionally complex compounds and structures the fraction contains. In this work we: (i) develop a means of predicting the relative solubility of the compounds in the water-extractable organic material from the Storm Peak site, based upon what is known about their chemical composition; (ii) derive the probable soluble organic fraction from comparisons of model predictions with the measured hygroscopicity; (iii) test a model of the water uptake of the total aerosol (inorganic plus total water-extractable organic compounds). Using a novel UNIFAC-based method, different assignments of functional groups to the high molecular weight water soluble organic compounds (WSOC) were explored, together with their effects on calculated hygroscopic growth factors, constrained by the known molecular formulae and the double bond equivalents associated with each molecule. The possible group compositions were compared with the results of ultrahigh resolution mass spectrometry measurements of the organic material, which suggest large numbers of alcohol (–OH) and acid (–COOH) groups. A hygroscopicity index (HI) was developed. The measured hygroscopic growth is found to be consistent with a dissolution of the WSOC material that varies approximately linearly with RH , such that the dissolved fraction is about 0.45–0.85 at 90% relative humidity when ordering by HI , depending on the assumptions made. This relationship, if it also applies to other types of organic aerosol material, provides a simple approach to calculating both water uptake and CCN activity (and the κ parameter for hygroscopic growth). The hygroscopicity of the total aerosol was modelled using a modified Zdanovskii-Stokes-Robinson approach as the sum of that of the three analysed fractions: inorganic ions (predicted), individual organic acids and "sugar alcohols" (predicted), and the high molecular weight WSOC fraction (measured). The calculated growth factors broadly agree with the measurements, and validate the approach taken. The insights into the dissolution of the organic material seem likely to apply to other largely biogenic secondary organic aerosols from similar remote locations. • A hygroscopicity index is developed for secondary organic aerosol material. • The estimated molecular group compositions confirm large numbers of –OH and –COOH. • Dissolution of water-extractable organic material varies linearly with RH. • Results suggest simple methods of modelling water uptake of atmospheric organics. • Measured and predicted growth factors of the total soluble aerosol agree well. [ABSTRACT FROM AUTHOR]

Published

2019

5. Transformations of dissolved organic matter induced by UV photolysis, Hydroxyl radicals, chlorine radicals, and sulfate radicals in aqueous-phase UV-Based advanced oxidation processes.

Author

Varanasi, Lathika, Coscarelli, Erica, Khaksari, Maryam, Mazzoleni, Lynn R., and Minakata, Daisuke

Subjects

*WASTEWATER treatment, *ORGANIC water pollutants, *TRACE element analysis, *ULTRAVIOLET photolysis, *DISSOLVED organic matter

Abstract

Considering the increasing identification of trace organic contaminants in natural aquatic environments, the removal of trace organic contaminants from water or wastewater discharge is an urgent task. Ultraviolet (UV) and UV-based advanced oxidation processes (AOPs), such as UV/hydrogen peroxide (UV/H 2 O 2 ), UV/free chlorine and UV/persulfate, are attractive and promising approaches for the removal of these contaminants due to the high reactivity of active radical species produced in these UV-AOPs with a wide variety of organic contaminants. However, the removal efficiency of trace contaminants is greatly affected by the presence of background dissolved organic matter (DOM). In this study, we use ultrahigh resolution mass spectrometry to evaluate the transformation of a standard Suwanee River fulvic acid DOM isolate in UV photolysis and UV-AOPs. The use of probe compounds allows for the determination of the steady-state concentrations of active radical species in each UV-AOP. The changes in the H/C and O/C elemental ratios, double bond equivalents, and the low-molecular-weight transformation product concentrations of organic acids reveal that different DOM transformation patterns are induced by each UV-AOP. By comparison with the known reactivities of each radical species with specific organic compounds, we mechanistically and systematically elucidate the molecular-level DOM transformation pathways induced by hydroxyl, chlorine, and sulfate radicals in UV-AOPs. We find that there is a distinct transformation in the aliphatic components of DOM due to HO• in UV/H 2 O 2 and UV/free chlorine. Cl• induced transformation of olefinic species is also observed in the UV/free chlorine system. Transformation of aromatic and olefinic moieties by SO 4 •- are the predominant pathways in the UV/persulfate system. [ABSTRACT FROM AUTHOR]

Published

2018

6. Molecular formula composition of β-caryophyllene ozonolysis SOA formed in humid and dry conditions.

Author

Kundu, Shuvashish, Fisseha, Rebeka, Putman, Annie L., Rahn, Thom A., and Mazzoleni, Lynn R.

Subjects

*CARYOPHYLLENE, *OZONOLYSIS, *HUMIDITY, *ATMOSPHERIC aerosols, *CLIMATE change

Abstract

We studied the molecular formula composition of six β-caryophyllene SOA samples using ultrahigh resolution Fourier transform ion cyclotron resonance mass spectrometry under various reaction conditions. The SOA samples were generated in dry or low relative humidity (RH) chamber conditions with or without cyclohexane. All of the studied SOA mass spectra have three distinct clusters of hundreds of negative ions referred to as Group I (100 < m/z < 400), Group II (400 < m/z < 700) and Group III (700 < m/z < 1 000) compounds. C 14-16 H 22-28 O 2-11 , C 28-29 H 42-48 O 6-16 and C 42-43 H 68-70 O 14-16 were observed as highly abundant organic compounds in the compound class of Group I, II and III, respectively. The relative intensities of most analytes were higher in humid conditions compared to those in dry conditions, indicating the importance of water-dependent reactions and the catalytic role of water both in the presence and absence of cyclohexane. In addition, molecular formulas with higher average carbon numbers were observed in humid SOA than in dry SOA in the absence of cyclohexane, suggesting a decrease of cleavage reactions in humid condition. This study characterizes β-caryophyllene ozonolysis SOA based on ultrahigh mass resolution and demonstrates the significance of humidity in terms of the molecular distributions and relative abundances of the analytes. We also discuss the possible mechanism for the formation of Group I-III compounds based on the current understanding of SOA formation in the atmosphere. [ABSTRACT FROM AUTHOR]

Published

2017

7. Ultrahigh-resolution FT-ICR mass spectrometry characterization of α-pinene ozonolysis SOA

Author

Putman, Annie L., Offenberg, John H., Fisseha, Rebeka, Kundu, Shuvashish, Rahn, Thom A., and Mazzoleni, Lynn R.

Subjects

*OZONOLYSIS, *FOURIER transform infrared spectroscopy, *PINENE, *AEROSOLS, *CYCLOTRON resonance, *HYDROXYL group, *MOLECULAR weights

Abstract

Abstract: Secondary organic aerosol (SOA) of α-pinene ozonolysis with and without hydroxyl radical scavenging hexane was characterized by ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS). Molecular formulas for more than 900 negative ions were identified over the mass range of 100–850u. Hydroxyl radicals formed during the ozonolysis of α-pinene might be expected to alter the composition of SOA, however a majority of the molecular formulas were identified in all three experiments and with a few exceptions they had similar relative abundances. Thus, the detailed composition of SOA was only slightly influenced by the presence or absence of hydroxyl radical scavenging hexane. The negative-ion mass spectra of the SOA contained four groups of peaks with increasing mass spectral complexity corresponding to increasing molecular weight. The mean values of O:C decreased from 0.55 to 0.42 with increasing molecular weight, but the mean value of H:C, approximately 1.5, did not change with increasing molecular weight. The molecular formulas with the highest relative abundances in Groups I and II contained 5–7 and 7–10 oxygen atoms and 3–4 and 5–7 double bond equivalents, respectively. The molecular formulas with the highest relative abundances in Groups III and IV contained 10–13 and 13–16 oxygen atoms and 7–9 and 9–11 double bond equivalents, respectively. Observations of the oxygen content and the double bond equivalents of the SOA products suggest a complex mixture of accretion reaction mechanisms, without an easily confirmable dominating pathway. [ABSTRACT FROM AUTHOR]

Published

2012