Changes in mixing ratio and isotopic composition of CO<sub>2</sub> in urban air from the Los Angeles basin, California, between 1972 and 2003

Newman, Sally; Xu, Xiaomei; Affek, Hagit P.; Stolper, Edward M.; Epstein, Samuel

doi:10.1029/2008jd009999

Cited by 61 publications

(73 citation statements)

References 74 publications

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“…On the diurnal time scale, δ 13 C S variability can be affected by the atmospheric mixing condition variation and the distribution of CO 2 sources (Wada et al, 2011;Sturm et al, 2006). In Wrocław, Poland and the Los Angeles basin, USA, the δ 13 C S differences over different time periods indicate changes in energy usage patterns (Gorka and Lewicka-Szczebak, 2013;Newman et al, 2008). In this study, the consistent δ 13 C S values of heating seasons I and II indicate that local energy consumption did not change during this period.…”

Section: Comparing the Characteristics Of δ 13 C S With Other Citiesmentioning

confidence: 47%

“…Measurements of δ 13 C only have been performed at 4 sites: Dallas, Texas, USA (Clark- Thorne and Yapp, 2003); Paris, France (Lopez et al, 2013;Widory and Javoy, 2003); Bangalore City, Karnataka State, India (Guha and Ghosh, 2010); and Wrocław, Poland (Gorka and Lewicka-Szczebak, 2013). Both δ 13 C and δ 18 O observations have been conducted at another 4 sites: Kraków, Poland (Zimnoch et al, 2012, Zimnoch et al, 2004; Bern, Switzerland (Sturm et al, 2006); and Los Angeles Basin, California, USA (Djuricin et al, 2010;Newman et al, 2008). Only 3 urban sites have had long-term continuous observations of the mixing ratio and isotopic composition by IRIS technology.…”

Section: Introductionmentioning

confidence: 99%

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Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Pang

Wen

Sun

2016

Science of The Total Environment

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• Continuous measurement of atmospheric CO 2 and δ 13 C in Beijing. • δ 13 C depleted in heating season and enriched in vegetative season.• Diurnal variation of δ 13 C showed two peaks in heating season.• Coal combustion was the main local CO 2 source. • δ 13 C showed significant liner relationship with air quality index (AQI). G R A P H I C A L A B S T R A C Ta b s t r a c t a r t i c l e i n f o The stable isotope composition of atmospheric CO 2 can be used as a tracer in the study of urban carbon cycles, which are affected by anthropogenic and biogenic CO 2 components. Continuous measurements of the mixing ratio and δ 13 C of atmospheric CO 2 were conducted in Beijing from Nov. 15, 2012 to Mar. 8, 2014 including two heating seasons and a vegetative season. Both δ 13 C and the isotopic composition of source CO 2 (δ 13 C S ) were depleted in the heating seasons and enriched in the vegetative season. The diurnal variations in the CO 2 mixing ratio and δ 13 C contained two peaks in the heating season, which are due to the effects of morning rush hour traffic. Seasonal and diurnal patterns of the CO 2 mixing ratio and δ 13 C were affected by anthropogenic emissions and biogenic activity. Assuming that the primary CO 2 sources at night (22:00-04:00) were coal and natural gas combustion during heating seasons I and II, an isotopic mass balance analysis indicated that coal combustion had average contributions of 83.83 ± 14.11% and 86.84 ± 12.27% and that natural gas had average contributions of 16.17 ± 14.11% and 13.16 ± 12.27%, respectively. The δ 13 C of background CO 2 in air was the main error source in the isotopic mass balance model. Both the mixing ratio and δ 13 C of atmospheric CO 2 had significant linear relationships with the air quality index (AQI) and can be used to indicate local air pollution conditions. Energy structure optimization, for example, reducing coal consumption, will improve the local air conditions in Beijing.

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Section: Comparing the Characteristics Of δ 13 C S With Other Citiesmentioning

confidence: 47%

Section: Introductionmentioning

confidence: 99%

Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Pang

Wen

Sun

2016

Science of The Total Environment

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“…[20] Observations have been made discontinuously at Caltech since the early 1970s [Newman et al, 2008]. Analysis of carbon isotopes from whole air flask samples has been performed to assess the observed CO 2 attributable to local emissions, and it was found that~10 ppm more CO 2 was attributable to local emissions in the 1970s than the early 2000s, in seeming contrast to the known emissions increase in that time frame [Newman et al, 2008].…”

Section: Caltechmentioning

confidence: 99%

“…Analysis of carbon isotopes from whole air flask samples has been performed to assess the observed CO 2 attributable to local emissions, and it was found that~10 ppm more CO 2 was attributable to local emissions in the 1970s than the early 2000s, in seeming contrast to the known emissions increase in that time frame [Newman et al, 2008]. This finding can possibly be explained by analysis of the footprint of the Caltech site, seen in Figure 2a.…”

Section: Caltechmentioning

confidence: 99%

Surface observations for monitoring urban fossil fuel CO₂ emissions: Minimum site location requirements for the Los Angeles megacity

et al. 2013

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[1] The contemporary global carbon cycle is dominated by perturbations from anthropogenic CO 2 emissions. One approach to identify, quantify, and monitor anthropogenic emissions is to focus on intensely emitting urban areas. In this study, we compare the ability of different CO 2 observing systems to constrain anthropogenic flux estimates in the Los Angeles megacity. We consider different observing system configurations based on existing observations and realistic near-term extensions of the current ad hoc network. We use a high-resolution regional model (Stochastic TimeInverted Lagrangian Transport-Weather Research and Forecasting) to simulate different observations and observational network designs within and downwind of the Los Angeles (LA) basin. A Bayesian inverse method is employed to quantify the relative ability of each network to improve constraints on flux estimates. Ground-based column CO 2 observations provide useful complementary information to surface observations due to lower sensitivity to localized dynamics, but column CO 2 observations from a single site do not appear to provide sensitivity to emissions from the entire LA megacity. Surface observations from remote, downwind sites contain weak, sporadic urban signals and are complicated by other source/sink impacts, limiting their usefulness for quantifying urban fluxes in LA. We find a network of eight optimally located in-city surface observation sites provides the minimum sampling required for accurate monitoring of CO 2 emissions in LA, and present a recommended baseline network design. We estimate that this network can distinguish fluxes on 8 week time scales and 10 km spatial scales to within~12 g C m -2 d -1 (~10% of average peak fossil CO 2 flux in the LA domain).Citation: Kort, E. A., W. M. Angevine, R. Duren, and C. E. Miller (2013), Surface observations for monitoring urban fossil fuel CO 2 emissions: Minimum site location requirements for the Los Angeles megacity,

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“…Numerous types of sites have been used to measure atmospheric CO 2 , such as: surface observatories (Idso et al, 2001;Newman et al, 2008;Ramonet et al, 2010;Rice and Bostrom, 2011;Pérez et al, 2012), balloon soundings (Bischof et al, 1980;Li et al, 2014), aircraft measurements (Bischof et al, 1980;Lloyd et al, 2002;Machida et al, 2002;Sidorov et al, 2002;Gurk et al, 2008;Shashkov et al, 2011;Sun and De Wekker, 2011;Sweeney et al, 2015), tall towers (Bakwin et al, 1995;Haszpra et al, 2005;Haszpra et al, 2012), and mountain-top observatories (Goldman, 1974;Thoning et al, 1989;Sturm et al, 2005;De Wekker et al, 2009;Ramonet et al, 2010;Brooks et al, 2012). Even though there are numerous methodologies for the measurement of CO 2 and data on atmospheric CO 2 concentrations have been available since the late 1950s, atmospheric chemistry models still have difficulty estimating CO 2 concentrations in conditions other than in a well-mixed planetary boundary layer (Haszpra et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Carbon Dioxide in the Free Troposphere and Boundary Layer at the Mt. Bachelor Observatory

McClure

Jaffe

Gao

2016

Aerosol Air Qual. Res.

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We use data for 2012-2014 from the Mt. Bachelor Observatory (MBO) in central Oregon to understand variations in carbon dioxide (CO 2 ) in the free troposphere (FT) and boundary layer (BL). The goals of this analysis are to identify and examine CO 2 in FT and BL air, events due to wildfires, the role of transport patterns, and the variation of CO 2 seasonally. For all seasons, we found that FT air has higher average CO 2 mixing ratios compared to BL air. FT air was most often seen during the night and early morning at MBO (20-8 PST) while BL air was most often observed during the afternoon and evening (12-20 PST). Winter and spring showed the highest mixing ratios of CO 2 while summer and fall showed the lowest mixing ratios. The maximum diurnal change in CO 2 was found during spring and summer. HYSPLIT backtrajectories and a cluster analysis of those trajectories were initiated for spring months. Based on this analysis, the spring clusters with the highest ozone and lowest water vapor mixing ratios were associated with the highest mixing ratios of CO 2 . Four case studies of CO 2 variations are presented: a long-range transport event observed at MBO and three wildfire events. In one large fire event, CO 2 showed a large enhancement and was well correlated with CO. In another fire event, CO 2 was observed to decrease, suggesting that depletion in BL air by surface uptake can counteract the enhancements from wildfire emissions.

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Changes in mixing ratio and isotopic composition of CO₂ in urban air from the Los Angeles basin, California, between 1972 and 2003

Cited by 61 publications

References 74 publications

Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Surface observations for monitoring urban fossil fuel CO₂ emissions: Minimum site location requirements for the Los Angeles megacity

Carbon Dioxide in the Free Troposphere and Boundary Layer at the Mt. Bachelor Observatory

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Changes in mixing ratio and isotopic composition of CO2 in urban air from the Los Angeles basin, California, between 1972 and 2003

Cited by 61 publications

References 74 publications

Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Mixing ratio and carbon isotopic composition investigation of atmospheric CO 2 in Beijing, China

Surface observations for monitoring urban fossil fuel CO2 emissions: Minimum site location requirements for the Los Angeles megacity

Carbon Dioxide in the Free Troposphere and Boundary Layer at the Mt. Bachelor Observatory

Contact Info

Product

Resources

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Changes in mixing ratio and isotopic composition of CO₂ in urban air from the Los Angeles basin, California, between 1972 and 2003

Surface observations for monitoring urban fossil fuel CO₂ emissions: Minimum site location requirements for the Los Angeles megacity