What's New

The report for SCAQMD project, "Environmental Chamber Studies of VOC Species in Architectural Coatings and Mobile Source Emissions," dated July 5, 2005, is now been finalized. We wish to thank all of those who provided constructive comments on the draft, most of which were taken into account when preparing the final version (PDF)(Word)

The College of Engineering Center for Environmental Research and Technology (CE-CERT) has completed a multi-year experimental and methods and model development program aimed at reducing the uncertainties in estimating the impacts of architectural coatings emissions on photochemical ozone formation and other measures of air quality. The projects are now complete and the final reports are available for downloading. The titles, authors, abstracts, and links for downloading are given below.
 

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EVALUATION OF ATMOSPHERIC IMPACTS OF SELECTED COATINGS VOC EMISSIONS

William P. L. Carter and Irina L. Malkina

Final Report to California Air Resources Board Contract No. 00-333
March 21, 2005

An experimental and modeling study was carried out to reduce uncertainties in atmospheric ozone impacts of architectural coatings VOCs. The focus of this project was Texanol® (isobutyrate monoesters of 2,2,4-trimethyl-1,3-pentanediol), which is widely used in water-based coatings, and various hydrocarbon solvents representative of those used in solvent-based coatings. The hydrocarbon “bin” reactivity assignments developed by the CARB for hydrocarbon solvents were evaluated using compositional data from 124 different solvents, and a new methodology was developed for deriving such assignments that can be used when reactivity scales are updated or modified. Progress was made towards developing a direct reactivity measurement method that does not require gas chromatographic analyses, but additional work is needed before data can be obtained for solvents of interest. Environmental chamber experiments were carried out to evaluate the abilities of mechanisms of Texanol® and six different types of hydrocarbon solvents to predict their atmospheric ozone impacts, and comparable experiments were carried out with m-xylene and n-octane for control and comparison purposes. Chamber data were also used to derive rate constants for the reactions of OH radials with the Texanol® isomers that are in excellent agreement with current estimates. The UCR EPA environmental chamber was employed, and the experiments were carried out at NOx levels of 25-30 ppb and at ROG/NOx ratios representing maximum incremental reactivity (MIR) and NOx-limited conditions. The current SAPRC-99 mechanism was found to simulate the results of the experiments with Texanol® and the primarily alkane petroleum distillate solvents reasonably well, though uncertainties exist because of problems with the model simulating results of the MIR base case experiments. The mechanism also simulated the effects of Aromatic 100 on O3 formation in the MIR experiments, but underpredicted the tendency for the aromatics to inhibit O3 in NOx -limited experiments and had other problems. The results of the experiments with the synthetic C10-C12 isoparaffinic mixture were not well simulated by the model, and suggest that current mechanisms may underpredict their atmospheric reactivities by 25-75% depending on the source of the discrepancy. Recommended needs for additional research are discussed.

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Download spreadsheet file HCcalc.xls
(for calculation of reactivities of complex hydrocarbon mixtures)


 

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ENVIRONMENTAL CHAMBER STUDIES OF VOC SPECIES IN ARCHITECTURAL COATINGS AND MOBILE SOURCE EMISSIONS

William P. L. Carter, Irina L. Malkina, David R. Cocker III, and Chen Song

Final Report to South Coast Air Quality Management District Contract No. 03468
July 5, 2005

Environmental chamber experiments were carried out to assess the atmospheric ozone and particle matter (PM) impacts of selected representative VOCs emitted from architectural coatings. The UCR EPA environmental chamber was employed for the ozone and PM impact experiments, and most consisted of incremental reactivity experiments carried out at NO_x levels of 25-30 ppb and at ambient surrogate ROG/NO_x ratios representing maximum incremental reactivity (MIR) and NO_x-limited conditions. The compounds studied included the representative water-based coatings VOCs ethylene and propylene glycol, 2-(2-butoxyethoxy)-ethanol (DGBE), and benzyl alcohol. In addition, measurements of PM formation were made in experiments for these compounds and also in experiments with Texanol® (isobutyrate monoesters of 2,2,4-trimethyl-1,3-pentanediol), and several representative hydrocarbon solvents that were carried out for a separate project for the California Air Resources Board. Information was also obtained about PM background effects in the environmental chamber experiments.

The results of the chamber experiments were used to evaluate the predictions of the SAPRC-99 mechanism. The existing mechanism for DGBE was found to simulate the ozone reactivity data adequately, and a new mechanism for benzyl alcohol was developed that simulated the chamber data as well as mechanisms for other aromatics. The existing mechanisms for ethylene and propylene glycols were found to underpredict their ozone impacts by ~20% and 25-30% in some, but not all, experiments, but no scientifically acceptable basis was found to modify the mechanisms to improve these predictions. It is possible that that this is due to problems with the mechanisms for the aromatics present in the base ROG. The results of the experiments were also used to derive rate constants for the reactions of OH radicals with DGBE and benzyl alcohol relative to that for m-xylene, of 5.04 x 10^-11 and 2.56 x 10^-11, respectively. The rate constant for DGBE is in good agreement with the estimated value used by SAPRC-99, and that for benzyl alcohol is in good agreement with another measurement in the literature.

In terms of PM impacts in the incremental reactivity experiments, the relative ordering was found to be benzyl alcohol >> DGBE > petroleum distillates > a synthetic hydrocarbon solvent consisting mainly of branched alkanes " Texanol® > ethylene and propylene glycols. The benzyl alcohol was found to have a surprisingly high PM impact compared to other aromatics, and the glycols were found to actually reduce PM levels in the experiments, probably due to reducing rates of reactions of other VOCs present in the incremental reactivity experiment. No clear correlation between aromatic content and PM formation potential in the hydrocarbon solvents was seen. Background PM formation was observed in the chamber that will need to be characterized before these data can be used for PM model evaluation. Exploratory availability experiments were carried out to assess whether the presence of (NH₄)₂SO₄ and NH₄HSO₄ seed aerosol at levels up to ~10 µg/m³ and humidity up to ~10% RH affected the gas-phase loss rates or ozone formation potentials of ethylene and propylene glycol, but effects were seen.

Experiments with updated ambient reactive organic gas (ROG) surrogate mixtures that represents current emissions from mobile and other sources were also planned for this project, but they could not be carried out because of a lack of time and resources to derive a target composition for a new ROG surrogate within the timescale needed for this project.

Download Document

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Final Report and Related Materials
• Final report for CARB project: "Evaluation of Atmospheric Impacts of Selected Coatings VOC Emissions," dated March 21, 2005. (PDF)(Word)
• Spreadsheet HCcalc.xls for estimating reactivities of hydrocarbon solvents, as described in the draft report to the CARB, discussed above. (Excel)
• Presentation on CARB and SCAQMD Coatings projects to be given at the CARB on April 13, 2005 (Power Point) (Corrected 4/11/05)
• Final report for SCAQMD project, "Environmental Chamber Studies of VOC Species in Architectural Coatings and Mobile Source Emissions," dated July 5, 2005. (PDF)(Word)


Materials for the December 3, 2003 Reactivity Research Advisory Committee meeting

• Presentation slides giving progress and current status of the CARB coatings reactivity project and also the CARB "Low NOx" mechanism evaluation project (Word) (PDF)
• Presentation slides summarizing new SCAQMD chamber reactivity project and proposed CARB project to update the SAPRC mechanisms. (Word) (PDF)

 

 

Proposal to the South Coast Air Quality Management District to conduct chamber studies of architectural coatings and mobile source VOCs (PDF) (Word).

Progress Reports

• Combined fifth periodic progress report to the CARB project and first periodic progress report to the SCAQMD project. Covers work from September 15, 2003 through February 15, 2004. Dated April 27. (PDF)
• Fourth periodic progress report covering the period March 16, 2003 through September 15, 2003. Dated December 18, 2003. (PDF)
• Third periodic progress report covering the period November 16, 2002 through March 15, 2003. Dated March 26, 2003. (PDF)
• Second periodic progress report covering the period March 15 through November 15, 2002. Dated November 27, 2002. (PDF)
• Final project report for "Development and Application of Improved Methods for Measurement of Ozone Formation Potentials of Volatile Organic Compounds, CARB Contract 97-314, May 22, 2002. (Describes the initial development and evaluation of the direct reactivity measurement method that is being further developed for this project.) (Abstract and download page)
• First periodic progress report covering the period June 30, 2001 through March 15, 2002. Revised and corrected on June 7, 2002 to give corrected and updated data for reactivity analysis of solvents studied by Censullo et al (2002). (PDF)

 

 

Presentations for June 13, 2002 Reactivity Research Advisory Committee (RRAC) meeting

• Presentation on progress on project through June, 2002. Final version, June 12, 2002 (PDF)
• Presentation titled "Development of a Direct Reactivity Measurement Method for Volatile Organic Compounds," which includes a discussion of the direct reactivity method that will be further developed for this project. Final Version, June 11, 2002. (PDF )

 

 

Original Proposal Documents

• Proposal for "Evaluation of Atmospheric Impacts of Selected Coatings VOC Emissions," dated February 8, 2001 (PDF )
• Addendum to proposal for "Evaluation of Atmospheric Impacts of Selected Coatings VOC Emissions" stating more clearly what exact tasks are involved in this project. Prepared March, 2001 (PDF )
• Proposal for "Improved Reactivity Estimates for Volatile Organic Compounds Used in Architectural Coatings," dated August 16, 2001 ( PDF )

• CARB Reactivity Research Advisory Committee (RRAC) Page
• Main Information Page for UCR EPA Chamber (which is being used for this project)
• Abstract page for Progress Report titled "Development and Application of Improved Methods for Measurement of Ozone Formation Potentials of Volatile Organic Compounds," that serves as a basis for some of the work discussed in this project.
• Reactivity Research Working Group (RRWG)
• Carter's RRWG Page
• William P. L. Carter's Home Page
• College of Engineering, Center for Environmental Research and Technology (CE-CERT)

Contact Information