12 research outputs found
Measurement of Trace Water Vapor in a Carbon Dioxide Removal Assembly Product Stream
The International Space Station Carbon Dioxide Removal Assembly (CDRA) uses regenerable adsorption technology to remove carbon dioxide (COP) from cabin air. Product water vapor measurements from a CDRA test bed at the NASA Marshall Space Flight Center were made using a tunable infrared diode laser differential absorption spectrometer (TILDAS) provided by NASA Glenn Research Center. The TILDAS instrument exceeded all the test specifications, including sensitivity, dynamic range, time response, and unattended operation. During the COP desorption phase, water vapor concentrations as low as 5 ppmv were observed near the peak of CO2 evolution, rising to levels of approx. 40 ppmv at the end of a cycle. Periods of high water concentration (>100 ppmv) were detected and shown to be caused by an experimental artifact. Measured values of total water vapor evolved during a single desorption cycle were as low as 1 mg
Comparison of Remote Sensing and Extractive Sampling Measurements of Flare Combustion Efficiency
Analysis of local-scale background concentrations of methane and other gas-phase species in the Marcellus Shale
The Marcellus Shale is a rapidly developing unconventional natural gas resource found in part of the Appalachian region. Air quality and climate concerns have been raised regarding development of unconventional natural gas resources. Two ground-based mobile measurement campaigns were conducted to assess the impact of Marcellus Shale natural gas development on local scale atmospheric background concentrations of air pollution and climate relevant pollutants in Pennsylvania. The first campaign took place in Northeastern and Southwestern PA in the summer of 2012. Compounds monitored included methane (CH4), ethane, carbon monoxide (CO), nitrogen dioxide, and Proton Transfer Reaction Mass Spectrometer (PTR-MS) measured volatile organic compounds (VOC) including oxygenated and aromatic VOC. The second campaign took place in Northeastern PA in the summer of 2015. The mobile monitoring data were analyzed using interval percentile smoothing to remove bias from local unmixed emissions to isolate local-scale background concentrations. Comparisons were made to other ambient monitoring in the Marcellus region including a NOAA SENEX flight in 2013. Local background CH4 mole fractions were 140 ppbv greater in Southwestern PA compared to Northeastern PA in 2012 and background CH4 increased 100 ppbv from 2012 to 2015. CH4 local background mole fractions were not found to have a detectable relationship between well density or production rates in either region. In Northeastern PA, CO was observed to decrease 75 ppbv over the three year period. Toluene to benzene ratios in both study regions were found to be most similar to aged rural air masses indicating that the emission of aromatic VOC from Marcellus Shale activity may not be significantly impacting local background concentrations. In addition to understanding local background concentrations the ground-based mobile measurements were useful for investigating the composition of natural gas emissions in the region
Data from: Analysis of local-scale background concentrations of methane and other gas-phase species in the Marcellus Shale
The Marcellus Shale is a rapidly developing unconventional natural gas resource found in part of the Appalachian region. Air quality and climate concerns have been raised regarding development of unconventional natural gas resources. Two ground-based mobile measurement campaigns were conducted to assess the impact of Marcellus Shale natural gas development on local scale atmospheric background concentrations of air pollution and climate relevant pollutants in Pennsylvania. The first campaign took place in Northeastern and Southwestern PA in the summer of 2012. Compounds monitored included methane (CH4), ethane, carbon monoxide (CO), nitrogen dioxide, and Proton Transfer Reaction Mass Spectrometer (PTR-MS) measured volatile organic compounds (VOC) including oxygenated and aromatic VOC. The second campaign took place in Northeastern PA in the summer of 2015. The mobile monitoring data were analyzed using interval percentile smoothing to remove bias from local unmixed emissions to isolate local-scale background concentrations. Comparisons were made to other ambient monitoring in the Marcellus region including a NOAA SENEX flight in 2013. Local background CH4 mole fractions were 140 ppbv greater in Southwestern PA compared to Northeastern PA in 2012 and background CH4 increased 100 ppbv from 2012 to 2015. CH4 local background mole fractions were not found to have a detectable relationship between well density or production rates in either region. In Northeastern PA, CO was observed to decrease 75 ppbv over the three year period. Toluene to benzene ratios in both study regions were found to be most similar to aged rural air masses indicating that the emission of aromatic VOC from Marcellus Shale activity may not be significantly impacting local background concentrations. In addition to understanding local background concentrations the ground-based mobile measurements were useful for investigating the composition of natural gas emissions in the region
Atmospheric Emission Characterization of Marcellus Shale Natural Gas Development Sites
Limited direct measurements of criteria
pollutants emissions and
precursors, as well as natural gas constituents, from Marcellus shale
gas development activities contribute to uncertainty about their atmospheric
impact. Real-time measurements were made with the Aerodyne Research
Inc. Mobile Laboratory to characterize emission rates of atmospheric
pollutants. Sites investigated include production well pads, a well
pad with a drill rig, a well completion, and compressor stations.
Tracer release ratio methods were used to estimate emission rates.
A first-order correction factor was developed to account for errors
introduced by fenceline tracer release. In contrast to observations
from other shale plays, elevated volatile organic compounds, other
than CH<sub>4</sub> and C<sub>2</sub>H<sub>6</sub>, were generally
not observed at the investigated sites. Elevated submicrometer particle
mass concentrations were also generally not observed. Emission rates
from compressor stations ranged from 0.006 to 0.162 tons per day (tpd)
for NO<sub><i>x</i></sub>, 0.029 to 0.426 tpd for CO, and
67.9 to 371 tpd for CO<sub>2</sub>. CH<sub>4</sub> and C<sub>2</sub>H<sub>6</sub> emission rates from compressor stations ranged from
0.411 to 4.936 tpd and 0.023 to 0.062 tpd, respectively. Although
limited in sample size, this study provides emission rate estimates
for some processes in a newly developed natural gas resource and contributes
valuable comparisons to other shale gas studies
Combustion and Destruction/Removal Efficiencies of In-Use Chemical Flares in the Greater Houston Area
Alkene emissions from the petrochemical industry contribute
significantly
to ozone production in the greater Houston area but are underestimated
in emission inventories. It is not well-known which processes (e.g.,
fugitive emissions, chemical flare emissions, etc.) are responsible
for these underreported emissions. We use fast time response and ground-based
mobile measurements of numerous trace gas species to characterize
alkene plumes from three identified chemical flares in the greater
Houston area. We calculate the combustion efficiency and destruction
and removal efficiency (DRE) values of these flares using the carbon
balance method. All three flares were operating at DRE values lower
than required by regulation. An examination of photochemistry in flare
exhaust plumes indicates that the impact of direct formaldehyde emissions
from flares on ozone formation is small as compared to the impact
of alkene emissions
Goetz_etal_2017_data
The zip file holds six tab delimited text files that contain 1 Hz mobile lab data and accompanying local background estimates from 2012 measurements in SW PA and NE PA and 2015 measurements in NE PA. See publication for more details. The provided local background data is derived from 20 minute 35th percentile smoothing. All time information is in military format. Date information is in mm/dd/yy. Concentration data is in units of ppbv. GPS data is in units of decimal degrees and in datum WGS84. Please contact authors if additional information is needed. All use of the provided data should be accompanied by the proper citations