1. SUMMARY OF REACTIVITY-RELATED CHAMBER PROJECTS AT UCRBy
William P. L. Carter
CE-CERT, University of California, Riverside
Overview
Summary of recent and ongoing projects for UCR EPA chamber
Results of tests of base mechanisms
Preliminary results of coatings reactivity study
Selected water-based solvent VOCs
Selected petroleum distillates
Future research directions for chamber
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

2. DIAGRAM OF UCR EPA CHAMBER
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

3. PHOTOGRAPHS OF CHAMBER AND LIGHTS
Looking Towards Reactors (from light)
Looking Towards Lights and Air Inlet
Reflective walls and Ceiling
Black Lights
Arc Light
Partially Filled Reactors
Reflective walls
Air Intake
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

4. SUMMARY OF CHAMBER PROJECTS TO DATE
“Development of a Next-Generation Environmental Chamber Facility …”
Funded by U.S. EPA
Funded chamber construction and initial characterization
Initial exploratory experiments:
Low NOx experiments with selected VOCs
Reactive organic gas (ROG) surrogate – NOx experiments at varying ROG and NOx levels
Incremental reactivity of m-xylene and n-octane at varying ROG and NOx levels
Status: complete. Report in preparation
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

5. SUMMARY OF CHAMBER PROJECTS TO DATE
“Development and Evaluation of a Gas-Phase Atmospheric Reaction Mechanism for Low NOx Conditions”
Funded by the California Air Resources Board
Primary objective is to evaluate the SAPRC-99 mechanism using previous and new low NOx environmental chamber data
A limited number of low NOx ROG surrogate runs carried out for this project
Data from the CSIRO and TVA chambers also used in this evaluation
Project completed. Reporte available at
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

6. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
“Experimental Evaluation of Observational Based Methods for Evaluating the Sensitivity of O3 to VOCs and NOx”
Funded by U.S. EPA
Objective is to provide data to evaluate OBMs using well-characterized chamber data
ROG Surrogate – NOx experiments at varying ROG and NOx with measurements of key radical and “indicator” species
Collaborated with Bill Brune of Penn State University to provide OH, HO2, and “OH reactivity” measurements using LIF
Successfully completed 20 dual-chamber surrogate experiments with radical measurements; 40 separate ROG/NOx irradiations
Report and journal articles in preparation
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

7. TESTS OF BASE MECHANISM
Ambient ROG surrogate – NOx experiments
8-component ROG surrogate used to represent major classes of emitted VOCs (n-butane, n-octane, ethene, propene, trans-2-butene, toluene, m-xylene, formaldehyde)
Test ability to predict O3 as function of ROG and NOx
Establish model performance for “base case” used in incremental reactivity experiments and calculations
Aromatic mechanism evaluation experiments
Aromatics have significant impact on predicted ambient O3 but also have highly uncertain mechanisms
Parameterized mechanisms adjusted to fit chamber data
New aromatic – NOx and Aromatic – NOx + CO experiments provide new type of test for aromatics mechanism.
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

8. EFFECT OF CO ON AROMATIC - NOx RUNS
E:\CHAMCALC\EPACHAM\REPFIT3.XLS
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Reactivity-Related Chamber Projects at UCR

9. EFFECTS OF ADJUSTMENTS TO PARAMETERIZED TOLUENE MECHANISM
H:\mech\saprc99\NewTol.xls
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

10. MATRIX OF ROG SURROGATE – NOx EXPERIMENTS IN UCR EPA CHAMBER
MIR Reactivity
Base Case
MOIR / 2 Reactivity
Base Case
X:\epacham\surgnox.xls
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Reactivity-Related Chamber Projects at UCR

11. LOW NOx SURROGATE EXPERIMENT (ROG SURROGATE = 300 PPBC, NOx = 2 PPB)
E:\CHAMCALC\EPACHAM\REPFIT3.XLS
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

12. EXAMPLE DATA FROM AN OBM EXPERIMENT
G:\TXT\epacham\obm\exdata.xls
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Reactivity-Related Chamber Projects at UCR

13. EXPERIMENTAL AND CALCULATED O3 FOR CURRENT BASE CASE REACTIVITY EXPERIMENTS
SAPRC-99 Model simulations of representative experiments
MIR BASE CASE
(NOx=30 ppb, ROG=0.5 ppmC)
MOIR / 2 BASE CASE
(NOx=25 ppb, ROG=1 ppmC)
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

14. DEPENDENCE OF SAPRC-99 UNDERPREDICTION BIAS ON RELATIVE ROG/NOx LEVELS
G:\txt\arbpgm\lownox\present.xls “2004 eval” sheet, col AB
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

15. EFFECT OF PARAMETERS AND MECHANISM ON O3 PREDICTIONS FOR UCR EPA SURROGATE RUNS
\\ozone\carter\epacham\SurgNox.xls (“Plots” sheet, column BF)
ROG/NOx Ratio relative to ratio giving maximum O3
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

16. Reactivity-Related Chamber Projects at UCR
PRELIMINARY CONCLUSIONS FROM NEW BASE CASE REACTIVITY AND AROMATICS DATA
SAPRC-99 mechanism predicts O3 reasonably well in low NOx and high ROG/NOx ambient simulation experiments
SAPRC-99 consistently underpredicts O3 in low ROG/NOx ambient simulation experiments
Problem even worse with CB4
Conditions where O3 is most sensitive to VOCs (MIR)
Complicates use of MIR incremental reactivity experiments to assess mechanisms for added VOCs
Results of new aromatic – NOx + CO experiments suggest problems with formulation of current aromatics mechanisms
Aromatics mechanism formulation problems may be reason for O3 underprediction in low ROG/NOx ambient simulations
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

17. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
“Evaluation of Atmospheric Impacts of Selected Coatings VOC Emissions”
Funded by the California Air Resources Board
Objective is to reduce uncertainties in O3 impact estimates of major types of coatings VOCs where reactivity data needed
Environmental chamber incremental reactivity experiments were carried out for Texanol®, an important component in water-based coatings, and various types of petroleum distillates.
Experiments carried out at two ROG and NOx conditions and evaluated using SAPRC-99 mechanism
Most experiments completed, data now being analyzed
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

18. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
“Environmental Chamber Studies of VOC Species in Architectural Coatings And Mobile Source Emissions”
Funded by the South Coast Air Quality Management District
Primarily supplements CARB architectural coatings reactivity project to allow for additional work:
PM measurements during reactivity experiments
Incremental reactivity experiments with ethylene and propylene glycols, benzyl alcohol, and butyl carbitol
Limited experiments to investigate interactions between glycols and aerosols for availability assessment
Experiments near completion and being analyzed
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

19. MEASUREMENT OR CALCULATION OF OZONE REACTIVITIES OF VOCs
Ozone reactivities of VOCs cal be calculated using computer airshed models, given:
Models for airshed conditions
Chemical mechanism for VOC’s Atmospheric Reactions
BUT mechanisms have uncertainties. reactivity calculations can be no more reliable than the chemical mechanism used.
Reactivities can also be measured in chamber experiments, but the results are not the same as reactivity in the atmosphere.
Impractical to duplicate all relevant conditions
Chamber experiments have wall effects, static conditions, higher levels of test VOCs, etc.
Therefore, the purpose of chamber experiments is to test the ability of the mechanisms to predict reactivity in models
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

20. VOCs IDENTIFIED IN 1998 CALIFORNIA SURVEY OF WATER-BASED ARCHITERCURAL COATINGS
Compound
Mass %
Structures
“Texanol®”
Isobutyrate esters of 2,2,4-Trimethylpentyl-1,3-diol
28%
(1)
(2)
Propylene Glycol
Ethylene Glycol
16%
Various Petroleum Distillates (Main constituents of solvent-based coatings) 5%
C8+ Alkanes and Aromatics
“Butyl Carbitol”:
2-(2-Butoxyethoxy)-Ethanol 4%
See g:\txt\arbpgm\coatings\texanol.xls and
G:\txt\arbpgm\coatings\rctruns.xls for structures.
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

21. SAPRC-99 MECHANISM GENERATION SYSTEM
Used to derive SAPRC-99 mechanisms for alkanes, glycols, esters, etc.
Automated mechanism generation procedure
Estimation methods used to derive unknown rate constants and ratios
Measured rate constants and branching ratios used where known.
“Lumping Rules” use to derive condensed mechanism for model
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

22. REACTIVITY DATA FOR TEXANOL®
G:\txt\epacham\RctTalk.xls “TEXANOL” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

23. REACTIVITY DATA FOR BUTYL CARBITOL
G:\txt\epacham\RctTalk.xls “DGBE” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

24. COMPARISON OF CHAMBER AND AMBIENT REACTIVITY CALCULATION FOR TEXANOL®
Two curves almost on top of each other
G:\txt\meetings\rrwg\rrwg1104.xls “Added Texanol” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

25. REACTIVITY DATA FOR ETHYLENE AND PROPYLENE GLYCOLS
G:\txt\epacham\RctTalk.xls “Glycols” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

26. OH RADICAL RATE CONSTANTS DERIVED FROM CHAMBER DATA
Compound
kOH (cm3 molec-1 s-1)
Texanol 1
1.29 x 10-11
Texanol 2
1.62 x 10-11
Butyl Carbitol
4.29 x 10-11
G:\txt\arbpgm\coatings\kOH.xls
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

27. Reactivity-Related Chamber Projects at UCR
GLYCOL DECAY RATES IN REACTIVITY RUNS: COMPARISON WITH LITERATURE K(OH) VALUE
G:\TXT\EPACHAM\SCAQMD\GlyKoh.xls “PR-GLYCL” sheet. Scale=135%
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

28. Reactivity-Related Chamber Projects at UCR
GLYCOL DECAY RATES IN REACTIVITY RUNS: COMPARISON WITH LITERATURE K(OH) VALUE
G:\TXT\EPACHAM\SCAQMD\GlyKoh.xls “PR-GLYCL” sheet. Scale=135%
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

29. PRELIMINARY CONCLUSIONS FROM WATER-BASED COATINGS SOLVENT EXPERIMENTS
The new data for Texanol® and butyl carbitol tend to support the estimates of the SAPRC‑99 mechanism generation system
Very good predictions of OH rate constants
“Acceptable” fits to chamber data without adjustments
The SAPRC-99 mechanism may somewhat underestimate O3 impacts of ethylene and propylene glycols
Need to improve the model simulation of the base case experiment to improve the utility of the MIR incremental reactivity experiments for mechanism evaluation
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

30. REPRESENTATIVE PETROLEUM DISTILLATES CHOSEN FOR REACTIVITY EXPERIMENTS
Designation
Carbon Range
Aromatic Content
MIR (gm/gm)
Comment
ASTM Type 3C1
Mostly 11 -
0.87
Mostly branched alkanes
ASTM Type1C
9-12
0.98
VMP Naphtha
8-9
0.2%
1.4
Lower Molecular weight mixture
ASTM Type 1B 6%
1.3
ASTM Type 1A
19%
2.1
Aromatic 100
Mostly 9
100%
7.5
Detailed analysis provided
G:\txt\arbpgm\coatings\mscmps.xls
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

31. CHEMICAL TYPE DISTRIBUTIONS FOR PETROLEUM DISTILLATES STUDIED
ASTM Type 3C1
ASTM Type 1C
VMP Naphtha
ASTM Type 1B
ASTM Type 1A
Aromatic 100
G:\txt\epacham\RctTalk.xls “MS Pie Plots” sheet
3C1, 1A Corrected 10/28/04
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

32. REACTIVITY DATA FOR PETROLEUM DISTILLATES
G:\txt\epacham\RctTalk.xls “MS Runs” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

33. REACTIVITY DATA FOR PETROLEUM DISTILLATES
G:\txt\epacham\RctTalk.xls “MS Runs” sheet
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

34. Reactivity-Related Chamber Projects at UCR
COMPARISON OF CHAMBER AND AMBIENT REACTIVITY CALCULATION FOR ASTM TYPE 1A
G:\txt\meetings\rrwg\rrwg1104.xls “Added ASTM1C” sheet. Size=110%
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

35. PRELIMINARY ASSESSMENT OF MODEL PERFORMANCE FOR PETROLEUM DISTILLATES
Designation
Major Components
Model Performance for O3
ASTM Type 3C1
C11 Branched Alkanes
Model underestimates O3 impact
ASTM Type1C
C9-C12 Alkanes
Not inconsistent with data
VMP Naphtha
C8-C9 Alkanes
ASTM Type 1B
C9-C12 Alkanes with ~6% Aromatics
ASTM Type 1A
C9-C12 Alkanes with ~20% Aromatics
May underpredict O3 inhibition at low NOx
Aromatic 100
Methyl ethyl and trimethyl Benzenes
Underpredicts O3 inhibition at low NOx
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

36. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
“Updated Chemical Mechanisms for Airshed Model Applications”
Funded by the California Air Resources Board
Major effort is updating and improving the SAPRC mechanism:
Updating to be consistent with current literature
Improving performance for aromatics and low ROG/NOx
Developing condensed version for models to replace CB4
Includes limited funding to support mechanism update effort (primarily for aromatics) (~10 runs)
Project is now underway
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

37. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
“Utilization of a Next Generation Environmental Chamber Facility ...”
Funded by the U.S. EPA
Primary objective is to support research utilizing chamber for O3 and secondary PM mechanism evaluations
Experiments to be conducted include:
Studies of temperature and humidity effects on O3 and SOA
PM and SOA formation characterization experiments
Study effects of variable ROG and NOx on and SOA
Funding only recently made available.
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

38. SUMMARY OF CHAMBER PROJECTS TO DATE (continued)
PM Characterization and Secondary PM Formation Assessment Studies
Carried out in collaboration with Dr. David Cocker of CE-CERT
Funded in part by the SCAQMD and EPA projects and in part by other CE-CERT programs
Experiments include
PM characterization and background experiments, and experiments for comparison with data from other chambers
Studies of SOA formation from aromatics and the ROG surrogate mixture under various conditions
Work is underway. Some manuscripts submitted for publication
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR

39. FUTURE RESEARCH DIRECTIONS FOR UCR EPA CHAMBER
Continue O3 reactivity and mechanism evaluation experiments for VOCs of interest
Utilize the capabilities of chamber for well-characterized SOA studies needed for SOA model development and evaluation
Investigate temperature and humidity effects on O3 and SOA
Obtain instrumentation needed for NO3, N2O5, HOx, and other trace species to improve capabilities and utility of this facility
Serve as a resource for collaborative studies where environmental chamber measurements under highly controlled and characterized conditions would be useful
Serve as test bed for instrumentation for ambient monitoring
W. P. L. Carter /17/2018
Reactivity-Related Chamber Projects at UCR