Your search keyword '"Run-Lie Shia"' showing total 75 results

1. Nitrogen Fixation at Paleo‐Mars in an Icy Atmosphere

Author

Danica Adams, Armin Kleinböhl, King‐Fai Li, Franklin P. Mills, Run‐Lie Shia, Robin Wordsworth, and Yuk L. Yung

Subjects

mars, nitrogen fixation, photochemistry, nitrite, MSL, nitrate, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Recent findings of NO near Gale Crater on Mars have been explained by two pathways: formation of nitric acid (HNO3) in a warm climate or formation of peroxynitric acid (HO2NO2) in a cool climate. Here, we put forth two hitherto unexplored pathways: (a) deposition of nitric/peroxynitric acid onto ice particles in a cold atmosphere, which settle quickly onto Mars' surface and (b) solar energetic particle‐induced production of nitric/peroxynitric acid. The deposition rates are enhanced and NO production is more efficient under the higher atmospheric pressures typical of Mars' ancient atmosphere. Depending on the unknown rate at which nitric/peroxynitric acid is lost from the surface, the new pathways could result in larger NO‐levels than those detected by the Mars Science Laboratory. We predict a 2:1 ratio of nitrite:nitrate would have deposited in cool surface climates with an icy atmosphere, whereas orders of magnitude more nitrate than nitrite is expected from warm surface climates.

Published

2024

2. Effect of the Quasi‐Biennial Oscillation on Carbon Monoxide in the Stratosphere

Author

Yuk L. Yung, Junyang Long, Jonathan H. Jiang, Siteng Fan, Xun Jiang, and Run‐Lie Shia

Subjects

Quasi‐biennial Oscillation, Microwave Limb Sounder CO, Chemistry Transport Model, Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract The interannual variability of tropical carbon monoxide from the Microwave Limb Sounder over 2004–2018 period is dominated by the quasi‐biennial oscillation (QBO). We simulate the carbon monoxide variability over this period using the 2‐D Caltech/JPL chemistry‐transport model. The chemistry‐transport model includes the photochemical sources and sinks and transport driven by a stream function and eddy diffusivity derived from the assimilated winds of National Centers for Environmental Prediction Reanalysis 2. The results show good agreement between model and Microwave Limb Sounder observations. We also investigate the anomalous period 2015–2016, when the QBO winds deviated significantly from their climatological values. The model simulations could capture the QBO features in agreement with observations for the anomalous period.

Published

2019

3. Assessing accuracy and precision for space‐based measurements of carbon dioxide: An associated statistical methodology revisited

Author

Zhan Su, Yuk L. Yung, Run‐Lie Shia, and Charles E. Miller

Subjects

statistical methodology, space‐based measurement, Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract Analyzing retrieval accuracy and precision is an important element of space‐based CO2 retrievals. However, this error analysis is sometimes challenging to perform rigorously because of the subtlety of Multivariate Statistics. To help address this issue, we revisit some fundamentals of Multivariate Statistics that help reveal the statistical essence of the associated error analysis. We show that the related statistical methodology is useful for revealing the intrinsic discrepancy and relation between the retrieval error for a nonzero‐variate CO2 state and that for a zero‐variate one. Our study suggests that the two scenarios essentially yield the same‐magnitude accuracy, while the latter scenario yields a better precision than the former. We also use this methodology to obtain a rigorous framework systematically and explore a broadly used approximate framework for analyzing CO2 retrieval errors. The approximate framework introduces errors due to an essential, but often forgotten, fact that a priori climatology in reality is never equal to the true state. Due to the nature of the problem considered, realistic numerical simulations that produce synthetic spectra may be more appropriate than remote sensing data for our specific exploration. As highlighted in our retrieval simulations, utilizing the approximate framework may not be universally satisfactory in assessing the accuracy and precision of Xco2 retrievals (with errors up to 0.17–0.28 ppm and 1.4–1.7 ppm, respectively, at SNR = 400). In situ measurements of CO2 are needed to further our understanding of this issue and related implications.

Published

2017

4. Atmospheric Methane Emissions Correlate With Natural Gas Consumption From Residential and Commercial Sectors in Los Angeles

Author

Liyin He, Zhao‐Cheng Zeng, Thomas J. Pongetti, Clare Wong, Jianming Liang, Kevin R. Gurney, Sally Newman, Vineet Yadav, Kristal Verhulst, Charles E. Miller, Riley Duren, Christian Frankenberg, Paul O. Wennberg, Run‐Lie Shia, Yuk L. Yung, and Stanley P. Sander

Published

2019

5. XCO2 retrieval error over deserts near critical surface albedo

Author

Qiong Zhang, Run‐Lie Shia, Stanley P. Sander, and Yuk L. Yung

Published

2016

6. Accounting for aerosol scattering in the CLARS retrieval of column averaged CO2 mixing ratios

Author

Qiong Zhang, Vijay Natraj, King‐Fai Li, Run‐Lie Shia, Dejian Fu, Thomas J. Pongetti, Stanley P. Sander, Coleen M. Roehl, and Yuk L. Yung

Published

2015

7. Atmospheric Methane Emissions Correlate With Natural Gas Consumption From Residential and Commercial Sectors in Los Angeles

Author

Christian Frankenberg, Riley M. Duren, Kevin R. Gurney, Clare Wong, Run-Lie Shia, Sally Newman, Charles E. Miller, Vineet Yadav, Paul O. Wennberg, Thomas J. Pongetti, Stanley P. Sander, Liyin He, Jianming Liang, Yuk L. Yung, Zhao-Cheng Zeng, and K. R. Verhulst

Subjects

Pollutant, Methane emissions, 010504 meteorology & atmospheric sciences, Atmospheric methane, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Atmosphere, Geophysics, Natural gas consumption, Greenhouse gas, General Earth and Planetary Sciences, Environmental science, Spatial variability, 0105 earth and related environmental sciences

Abstract

Legislation in the State of California mandates reductions in emissions of short‐lived climate pollutants of 40% from 2013 levels by 2030 for CH_4. Identification of the sector(s) responsible for these emissions and their temporal and spatial variability is a key step in achieving these goals. Here, we determine the emissions of CH_4 in Los Angeles from 2011–2017 using a mountaintop remote sensing mapping spectrometer. We show that the pattern of CH_4 emissions contains both seasonal and nonseasonal contributions. We find that the seasonal component peaks in the winter and is correlated (R^2 = 0.58) with utility natural gas consumption from the residential and commercial sectors and not from the industrial and gas‐fired power plant sectors. The nonseasonal component is (22.9 ± 1.4) Gg CH_4/month. If the seasonal correlation is causal, about (1.4 ± 0.1)% of the commercial and residential natural gas consumption in Los Angeles is released into the atmosphere.

Published

2019

8. A Spectral Data Compression (SDCOMP) Radiative Transfer Model for High-Spectral-Resolution Radiation Simulations

Author

Fuzhong Weng, Yuk L. Yung, Vijay Natraj, Run-Lie Shia, Chao Liu, Bin Yao, Tianhao Le, and Pushkar Kopparla

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Weather and climate, 02 engineering and technology, Radiation, 01 natural sciences, Atmospheric radiative transfer codes, Compression (functional analysis), Radiative transfer, Environmental science, Satellite, Spectral resolution, Spectral data, Physics::Atmospheric and Oceanic Physics, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing

Abstract

With the increasing use of satellite and ground-based high-spectral-resolution (HSR) measurements for weather and climate applications, accurate and efficient radiative transfer (RT) models have become essential for accurate atmospheric retrievals, for instrument calibration, and to provide benchmark RT solutions. This study develops a spectral data compression (SDCOMP) RT model to simulate HSR radiances in both solar and infrared spectral regions. The SDCOMP approach “compresses” the spectral data in the optical property and radiance domains, utilizing principal component analysis (PCA) twice to alleviate the computational burden. First, an optical-property-based PCA is performed for a given atmospheric scenario (atmospheric, trace gas, and aerosol profiles) to simulate relatively low-spectral-resolution radiances at a small number of representative wavelengths. Second, by using precalculated principal components from an accurate radiance dataset computed for a large number of atmospheric scenarios, a radiance-based PCA is carried out to extend the low-spectral-resolution results to desired HSR results at all wavelengths. This procedure ensures both that individual monochromatic RT calculations are efficiently performed and that the number of such computations is optimized. SDCOMP is approximately three orders of magnitude faster than numerically exact RT calculations. The resulting monochromatic radiance has relative errors less than 0.2% in the solar region and brightness temperature differences less than 0.1 K for over 95% of the cases in the infrared region. The efficiency and accuracy of SDCOMP not only make it useful for analysis of HSR measurements, but also hint at the potential for utilizing this model to perform RT simulations in mesoscale numerical weather and general circulation models.

Published

2020

9. Estimating nitrous oxide (N2O) emissions for the Los Angeles Megacity using mountaintop remote sensing observations

Author

Zhao-Cheng Zeng, Stanley P. Sander, Geoffrey Roest, Olivia Addington, Run-Lie Shia, Liyin He, Kevin R. Gurney, Thomas J. Pongetti, Yuk L. Yung, and Jianming Liang

Subjects

010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Soil Science, Geology, 02 engineering and technology, Nitrous oxide, Radiative forcing, Structural basin, 01 natural sciences, Ozone depletion, 020801 environmental engineering, chemistry.chemical_compound, Megacity, chemistry, Remote sensing (archaeology), Greenhouse gas, Environmental science, Computers in Earth Sciences, Seasonal cycle, 0105 earth and related environmental sciences, Remote sensing

Abstract

Nitrous oxide (N2O) is an important greenhouse gas contributing both to global radiative forcing and ozone depletion. Though N2O emissions are largely derived from agricultural activities, urban sources of N2O also contribute significantly to anthropogenic emissions, but are not well understood and difficult to quantify. This study employs a top-down approach to derive urban N2O emissions for the Los Angeles megacity using a unique dataset from a mountaintop remote sensing instrument, which has been observing greenhouse gas mixing ratios in LA since 2011. CLARS-FTS observations yield a weighted mean of 15.0 ± 0.1 ppb excess XN2O above background in the LA basin from 2013 to 2019. Time series of XN2Oxs show a seasonal cycle with a peak-to-peak amplitude of 5.6 ± 2.5 ppb, where greater XN2Oxs values are observed during the winter/spring and minima occur in late summer/early fall. A tracer-tracer ratio method is applied using XN2Oxs and XCO2,xs observations to estimate top-down N2O emissions for the LA basin during 2013–2018. Estimated monthly emissions range from 6 to 19 Gg N2O per month and exhibit a similar seasonal cycle to that observed in XN2Oxs. Estimated annual emissions fall within the range 124–144 Gg per year for the years 2014–2018. These top-down annual estimates are roughly 3 times the official statewide bottom-up inventory for the same time period, but consistent considering uncertainties with other top-down estimates for the LA basin. The discrepancy between top-down emission estimates and the statewide bottom-up inventory highlights the difficulty in constraining N2O emissions, especially for an urban environment.

Published

2021

10. PCA-based radiative transfer: Improvements to aerosol scheme, vertical layering and spectral binning

Author

Yuk L. Yung, Pushkar Kopparla, Peter Somkuti, David Crisp, Run-Lie Shia, Vijay Natraj, Robert Spurr, and Drew Limpasuvan

Subjects

Radiation, 010504 meteorology & atmospheric sciences, Spectral bands, 01 natural sciences, Atomic and Molecular Physics, and Optics, Spectral line, Aerosol, 010309 optics, 0103 physical sciences, Principal component analysis, Radiative transfer, Environmental science, Layering, Shortwave, Spectroscopy, Order of magnitude, 0105 earth and related environmental sciences, Remote sensing

Abstract

The Principal Component Analysis (PCA)-based fast radiative transfer method has been shown to have at least an order of magnitude increase in computational speed while maintaining an overall accuracy of 0.01% (compared to line-by-line calculations) over narrow and broad spectral bands. In this paper, we describe several improvements made to the method and provide a discussion of the method’s performance over a diverse set of atmospheric profiles and land surface types. We also test the model over uniform pressure level profiles. The method is now capable of providing atmospheric spectra with residuals under 0.1%, calculated with respect to the continuum, throughout the shortwave region between 0.3−3μm at high resolution, which is substantial improvement over errors reported in earlier work. Future directions for applications and further optimization are examined.

Published

2017

11. The photochemistry of Pluto's atmosphere as illuminated by New Horizons

Author

Siteng Fan, Mao-Chang Liang, Peter Gao, Harold A. Weaver, Leslie A. Young, Kimberly Ennico, Michael L. Wong, Catherine B. Olkin, Joshua A. Kammer, Run-Lie Shia, Michael E. Summers, Yuk L. Yung, G. Randall Gladstone, and S. Alan Stern

Subjects

chemistry.chemical_classification, New horizons, 010504 meteorology & atmospheric sciences, Trace Amounts, Chemistry, Vapor pressure, Condensation, Astronomy and Astrophysics, Photochemistry, 01 natural sciences, Atmosphere, Pluto, Hydrocarbon, Space and Planetary Science, 0103 physical sciences, Mixing ratio, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

New Horizons has granted us an unprecedented glimpse at the structure and composition of Pluto's atmosphere, which is comprised mostly of N_2 with trace amounts of CH_4, CO, and the photochemical products thereof. Through photochemistry, higher-order hydrocarbons are generated, coagulating into aerosols and resulting in global haze layers. Here we present a state-of-the-art photochemical model for Pluto's atmosphere to explain the abundance profiles of CH_4, C_2H_2, C_2H_4, and C_2H_6, the total column density of HCN, and to predict the abundance profiles of oxygen-bearing species. The CH_4 profile can be best matched by taking a constant-with-altitude eddy diffusion coefficient K_(zz) profile of 1 × 10^3 cm^2 s^(–1) and a fixed CH_4 surface mixing ratio of 4 × 10^(–3). Condensation is key to fitting the C_2 hydrocarbon profiles. We find that C_2H_4 must have a much lower saturation vapor pressure than predicted by extrapolations of laboratory measurements to Pluto temperatures. We also find best-fit values for the sticking coefficients of C_2H_2, C_2H_4, C_2H_6, and HCN. The top three precipitating species are C_2H_2, C_2H_4, and C_2H_6, with precipitation rates of 179, 95, and 62 g cm^(–2) s^(–1), respectively.

Published

2017

12. Assessing accuracy and precision for space‐based measurements of carbon dioxide: An associated statistical methodology revisited

Author

Yuk L. Yung, Charles E. Miller, Run-Lie Shia, and Zhan Su

Subjects

Multivariate statistics, Accuracy and precision, 010504 meteorology & atmospheric sciences, Relation (database), lcsh:Astronomy, Computer science, 0211 other engineering and technologies, 02 engineering and technology, Environmental Science (miscellaneous), Space (mathematics), computer.software_genre, 01 natural sciences, lcsh:QB1-991, Error analysis, statistical methodology, Statistics, space‐based measurement, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, lcsh:QE1-996.5, lcsh:Geology, General Earth and Planetary Sciences, A priori and a posteriori, Data mining, Element (category theory), computer

Abstract

Analyzing retrieval accuracy and precision is an important element of space‐based CO2 retrievals. However, this error analysis is sometimes challenging to perform rigorously because of the subtlety of Multivariate Statistics. To help address this issue, we revisit some fundamentals of Multivariate Statistics that help reveal the statistical essence of the associated error analysis. We show that the related statistical methodology is useful for revealing the intrinsic discrepancy and relation between the retrieval error for a nonzero‐variate CO2 state and that for a zero‐variate one. Our study suggests that the two scenarios essentially yield the same‐magnitude accuracy, while the latter scenario yields a better precision than the former. We also use this methodology to obtain a rigorous framework systematically and explore a broadly used approximate framework for analyzing CO2 retrieval errors. The approximate framework introduces errors due to an essential, but often forgotten, fact that a priori climatology in reality is never equal to the true state. Due to the nature of the problem considered, realistic numerical simulations that produce synthetic spectra may be more appropriate than remote sensing data for our specific exploration. As highlighted in our retrieval simulations, utilizing the approximate framework may not be universally satisfactory in assessing the accuracy and precision of Xco2 retrievals (with errors up to 0.17–0.28 ppm and 1.4–1.7 ppm, respectively, at SNR = 400). In situ measurements of CO2 are needed to further our understanding of this issue and related implications.

Published

2017

13. Aerosol scattering effects on water vapor retrievals over the Los Angeles Basin

Author

Qiong Zhang, Jack S. Margolis, Dejian Fu, Zhao-Cheng Zeng, Paul O. Wennberg, Run-Lie Shia, Vijay Natraj, Yuk L. Yung, Thomas J. Pongetti, K. W. Wong, Sally Newman, and Stanley P. Sander

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Aerosol scattering, Scattering, Near-infrared spectroscopy, 01 natural sciences, lcsh:QC1-999, Aerosol, 010309 optics, lcsh:Chemistry, Wavelength, lcsh:QD1-999, 0103 physical sciences, Radiative transfer, Environmental science, Absorption (electromagnetic radiation), Water vapor, lcsh:Physics, 0105 earth and related environmental sciences, Remote sensing

Abstract

In this study, we propose a novel approach to describe the scattering effects of atmospheric aerosols in a complex urban environment using water vapor (H2O) slant column measurements in the near infrared. This approach is demonstrated using measurements from the California Laboratory for Atmospheric Remote Sensing Fourier Transform Spectrometer on the top of Mt. Wilson, California, and a two-stream-exact single scattering (2S-ESS) radiative transfer (RT) model. From the spectral measurements, we retrieve H2O slant column density (SCD) using 15 different absorption bands between 4000 and 8000 cm−1. Due to the wavelength dependence of aerosol scattering, large variations in H2O SCD retrievals are observed as a function of wavelength. Moreover, the variations are found to be correlated with aerosol optical depths (AODs) measured at the AERONET-Caltech station. Simulation results from the RT model reproduce this correlation and show that the aerosol scattering effect is the primary contributor to the variations in the wavelength dependence of the H2O SCD retrievals. A significant linear correlation is also found between variations in H2O SCD retrievals from different bands and corresponding AOD data; this correlation is associated with the asymmetry parameter, which is a first-order measure of the aerosol scattering phase function. The evidence from both measurements and simulations suggests that wavelength-dependent aerosol scattering effects can be derived using H2O retrievals from multiple bands. This understanding of aerosol scattering effects on H2O retrievals suggests a promising way to quantify the effect of aerosol scattering on greenhouse gas retrievals and could potentially contribute towards reducing biases in greenhouse gas retrievals from space.

Published

2017

14. Effect of the Quasi-biennial Oscillation on Carbon Monoxide in the Stratosphere

Author

Jonathan H. Jiang, Siteng Fan, Junyang Long, Xun Jiang, Yuk L. Yung, and Run-Lie Shia

Subjects

Quasi-biennial oscillation, 010504 meteorology & atmospheric sciences, lcsh:Astronomy, Oscillation, Quasi‐biennial Oscillation, lcsh:QE1-996.5, Microwave Limb Sounder CO, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Eddy diffusion, lcsh:QB1-991, lcsh:Geology, Microwave Limb Sounder, chemistry.chemical_compound, chemistry, Stream function, General Earth and Planetary Sciences, Environmental science, Chemistry Transport Model, Stratosphere, 0105 earth and related environmental sciences, Carbon monoxide

Abstract

The interannual variability of tropical carbon monoxide from the Microwave Limb Sounder over 2004–2018 period is dominated by the quasi‐biennial oscillation (QBO). We simulate the carbon monoxide variability over this period using the 2‐D Caltech/JPL chemistry‐transport model. The chemistry‐transport model includes the photochemical sources and sinks and transport driven by a stream function and eddy diffusivity derived from the assimilated winds of National Centers for Environmental Prediction Reanalysis 2. The results show good agreement between model and Microwave Limb Sounder observations. We also investigate the anomalous period 2015–2016, when the QBO winds deviated significantly from their climatological values. The model simulations could capture the QBO features in agreement with observations for the anomalous period.

Published

2019

15. A fast and accurate PCA based radiative transfer model: Extension to the broadband shortwave region

Author

David Crisp, Pushkar Kopparla, Robert Spurr, Vijay Natraj, Yuk L. Yung, and Run-Lie Shia

Subjects

Physics, Radiation, 010504 meteorology & atmospheric sciences, Spectral bands, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010309 optics, Root mean square, Atmospheric radiative transfer codes, 0103 physical sciences, Principal component analysis, Radiative transfer, Absorption (electromagnetic radiation), Shortwave, Spectroscopy, Order of magnitude, 0105 earth and related environmental sciences, Remote sensing

Abstract

Accurate radiative transfer (RT) calculations are necessary for many earth-atmosphere applications, from remote sensing retrieval to climate modeling. A Principal Component Analysis (PCA)-based spectral binning method has been shown to provide an order of magnitude increase in computational speed while maintaining an overall accuracy of 0.01% (compared to line-by-line calculations) over narrow spectral bands. In this paper, we have extended the PCA method for RT calculations over the entire shortwave region of the spectrum from 0.3 to 3 microns. The region is divided into 33 spectral fields covering all major gas absorption regimes. We find that the RT performance runtimes are shorter by factors between 10-100, while root mean square errors are of order 0.01%.

Published

2016

16. Information‐rich spectral channels for simulated retrievals of partial column‐averaged methane

Author

King-Fai Li, Yuk L. Yung, Xi Xi, Run-Lie Shia, Zhan Su, Vijay Natraj, and Charles E. Miller

Subjects

010504 meteorology & atmospheric sciences, Information analysis, Environmental Science (miscellaneous), 01 natural sciences, Column (database), Methane, 010309 optics, chemistry.chemical_compound, chemistry, Remote sensing (archaeology), 0103 physical sciences, General Earth and Planetary Sciences, Environmental science, 0105 earth and related environmental sciences, Remote sensing

Abstract

Space‐based remote sensing of the column‐averaged methane dry air mole fraction (XCH_4) has greatly increased our understanding of the spatiotemporal patterns in the global methane cycle. The potential to retrieve multiple pieces of vertical profile information would further improve the quantification of CH_4 across space‐time scales. We conduct information analysis for channel selection and evaluate the prospects of retrieving multiple pieces of information as well as total column CH_4 from both ground‐based and space‐based near‐infrared remote sensing spectra. We analyze the degrees of freedom of signal (DOF) in the CH_4 absorption bands near 2.3 μm and 1.6 μm and select ∼1% of the channels that contain >95% of the information about the CH_4 profile. The DOF is around 4 for fine ground‐based spectra (resolution = 0.01 cm^(−1)) and 3 for coarse space‐based spectra (resolution = 0.20 cm^(−1)) based on channel selection and a signal‐to‐noise ratio (SNR) of 300. The DOF varies from 2.2 to 3.2 when SNR is between 100 and 300, and spectral resolution is 0.20 cm^(−1). Simulated retrieval tests in clear‐sky conditions using the selected channels reveal that the retrieved partial column‐averaged CH_4 values are not sensitive to the a priori profiles and can reflect local enhancements of CH_4 in different partial air columns. Both the total and partial column‐averaged retrieval errors in all tests are within 1% of the true state. These simulated tests highlight the possibility to retrieve up to three to four pieces of information about the vertical distribution of CH_4 in reality.

Published

2016

17. Tracking the atmospheric pulse of a North American megacity from a mountaintop remote sensing observatory

Author

Yun Li, Fang-Ying Gong, Run-Lie Shia, Yuan Wang, Yuk L. Yung, Thomas J. Pongetti, Vijay Natraj, Sally Newman, Zhao-Cheng Zeng, and Stanley P. Sander

Subjects

010504 meteorology & atmospheric sciences, Planetary boundary layer, 0208 environmental biotechnology, Soil Science, Geology, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Troposphere, Atmosphere, Diurnal cycle, Observatory, Weather Research and Forecasting Model, Mixing ratio, Geostationary orbit, Computers in Earth Sciences, 0105 earth and related environmental sciences, Remote sensing

Abstract

Atmospheric carbon monoxide (CO) is an effective tracer for monitoring atmospheric transport processes and for detecting pollution sources of anthropogenic origin. However, very few observation systems exist that are capable of providing measurements with high spatial and temporal resolution to identify hotspots for emission control purposes. Here we introduce a mountain-top remote sensing observatory, the California Laboratory for Atmospheric Remote Sensing (CLARS), for mapping the enhancement of CO column-averaged mixing ratio (XCO) over the Los Angeles (LA) megacity. Compared to conventional observation network, CLARS is unique in the following ways: (1) it mimics a geostationary satellite observatory for LA with approximately hourly- and kilometer-scale mapping capability; (2) the free tropospheric background atmosphere is simultaneously measured; and (3) the measurements are highly sensitive to anthropogenic emissions due to the long light path along the planetary boundary layer (PBL). The CO slant column density and XCO are retrieved from reflected sunlight measurements in the 2.3 μm CO band and the 1.27 μm oxygen (O2) band. Data filtering and corrections for aerosol scattering and geometric effects are then implemented to derive the XCO enhancement, which is the XCO excess in the PBL compared to the background value. In the LA megacity, the XCO enhancement shows a distinctive diurnal cycle primarily driven by changes in anthropogenic emissions and sea-breeze circulation. Such diurnal patterns can be reproduced by the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem). The enhancement also shows a significant weekly cycle resulting from the weekly pattern in anthropogenic CO emissions. On average, the XCO enhancements on Sunday and Saturday are 16.1% and 4.4%, respectively, lower than weekday values. The weekly XCO enhancement patterns also show high correlation with traffic counts. A seasonal pattern of XCO enhancement with high (low) spatial contrast in summer (winter), resulting from changing sea-breeze circulation, can be observed. These diurnal, weekly, and seasonal patterns of XCO enhancement serve as tracers of the atmospheric pulse of the LA megacity. The CLARS observatory can serve as a testbed for future geostationary missions to track anthropogenic emissions in cities.

Published

2020

18. Remote sensing of angular scattering effect of aerosols in a North American megacity

Author

Run-Lie Shia, Feng Xu, Stanley P. Sander, Zhao-Cheng Zeng, Qiong Zhang, Vijay Natraj, Thomas J. Pongetti, and Yuk L. Yung

Subjects

010504 meteorology & atmospheric sciences, Scattering, 0208 environmental biotechnology, FOS: Physical sciences, Soil Science, Geology, 02 engineering and technology, Radiative forcing, Radiation, 01 natural sciences, 020801 environmental engineering, Aerosol, Trace gas, Atmosphere, Physics - Atmospheric and Oceanic Physics, Boundary layer, Atmospheric and Oceanic Physics (physics.ao-ph), Range (statistics), Environmental science, Computers in Earth Sciences, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Remote sensing

Abstract

The angle-dependent scattering effect of aerosols in the atmosphere can be used to infer their compositions, which in turn is important to understand their impacts of human health and Earth climate. The aerosol phase function, which characterizes the angular signature of scattering, has been continuously monitored from ground-based and space-borne observations. However, the range of scattering angles these instruments can sample is very limited. There is a dearth of research on the remote sensing of aerosol angular scattering effect at a city scale that analyzes diurnal variability and includes a wide range of scattering angles. Here, we quantify the aerosol angular scattering effect using measurements from a mountain-top remote sensing instrument: the California Laboratory for Atmospheric Remote Sensing Fourier Transform Spectrometer (CLARS-FTS). CLARS-FTS is located on top of the Mt. Wilson (1.67km above sea level) overlooking the Los Angeles (LA) megacity and receives reflected sunlight from targeted surface reflection points. The observational geometries of CLARS-FTS provide a wide range of scattering angles, from about 20 degrees (forward) to about 140 degrees (backward). The O2 ratio, which is the ratio of retrieved O2 Slant Column Density (SCD) to geometric O2 SCD, quantifies the aerosol transmission with a value of 1.0 represent aerosol-free and with a value closer to 0.0 represents stronger aerosol loadings. The aerosol transmission quantified by the O2 ratio from CLARS measurements provides an effective indicator of the aerosol scattering effect., Comment: 29 pages; 4 figures

Published

2020

19. Constraining Aerosol Vertical Profile in the Boundary Layer Using Hyperspectral Measurements of Oxygen Absorption

Author

Vijay Natraj, Stanley P. Sander, Zhao-Cheng Zeng, Run-Lie Shia, Thomas J. Pongetti, Geoffrey C. Toon, Feng Xu, Yuk L. Yung, and Eric A. Kort

Subjects

010504 meteorology & atmospheric sciences, Urban climatology, Fourier transform spectrometers, Hyperspectral imaging, 01 natural sciences, Aerosol, 010309 optics, Boundary layer, Geophysics, Lidar, 0103 physical sciences, Oxygen absorption, General Earth and Planetary Sciences, Environmental science, Satellite, 0105 earth and related environmental sciences, Remote sensing

Abstract

This study attempts to infer aerosol vertical structure in the urban boundary layer using passive hyperspectral measurements. A spectral sorting technique is developed to retrieve total aerosol optical depth (AOD) and effective aerosol layer height (ALH) from hyperspectral measurements in the 1.27‐μm oxygen absorption band by the mountaintop Fourier Transform Spectrometer at the California Laboratory for Atmospheric Remote Sensing instrument (1,673 m above sea level) overlooking the LA basin. Comparison to AOD measurements from Aerosol Robotic Network and aerosol backscatter profile measurements from a Mini MicroPulse Lidar shows agreement, with coefficients of determination (r^2) of 0.74 for AOD and 0.57 for effective ALH. On average, the AOD retrieval has an error of 24.9% and root‐mean‐square error of 0.013, while the effective ALH retrieval has an error of 7.8% and root‐mean‐square error of 67.01 m. The proposed method can potentially be applied to existing and future satellite missions with hyperspectral oxygen measurements to constrain aerosol vertical distribution on a global scale.

Published

2018

20. Simulated retrievals for the remote sensing of CO2, CH4, CO, and H2O from geostationary orbit

Author

Run-Lie Shia, Vijay Natraj, Qiong Zhang, X. Xi, M. Luo, Yuk L. Yung, Sally Newman, and Stanley P. Sander

Subjects

Atmospheric Science, Error analysis, Radiative transfer, Fourier transform spectrometers, Geostationary orbit, Environmental science, Spectral line, Remote sensing

Abstract

The Geostationary Fourier Transform Spectrometer (GeoFTS) is designed to measure high-resolution spectra of reflected sunlight in three near-infrared bands centered around 0.76, 1.6, and 2.3 μm and to deliver simultaneous retrievals of column-averaged dry air mole fractions of CO2, CH4, CO, and H2O (denoted XCO2, XCH4, XCO, and XH2O, respectively) at different times of day over North America. In this study, we perform radiative transfer simulations over both clear-sky and all-sky scenes expected to be observed by GeoFTS and estimate the prospective performance of retrievals based on results from Bayesian error analysis and characterization. We find that, for simulated clear-sky retrievals, the average retrieval errors and single-measurement precisions are < 0.2% for XCO2, XCH4, and XH2O, and < 2% for XCO, when the a priori values have a bias of 3% and an uncertainty of 3%. In addition, an increase in the amount of aerosols and ice clouds leads to a notable increase in the retrieval errors and slight worsening of the retrieval precisions. Furthermore, retrieval precision is a strong function of signal-to-noise ratio and spectral resolution. This simulation study can help guide decisions on the design of the GeoFTS observing system, which can result in cost-effective measurement strategies while achieving satisfactory levels of retrieval precisions. The simultaneous retrievals at different times of day will be important for more accurate estimation of carbon sources and sinks on fine spatiotemporal scales and for studies to better understand the close coupling between the carbon and water cycles.

Published

2015

21. Accounting for aerosol scattering in the CLARS retrieval of column averaged CO2mixing ratios

Author

Coleen M. Roehl, King-Fai Li, Run-Lie Shia, Dejian Fu, Yuk L. Yung, Thomas J. Pongetti, Vijay Natraj, Qiong Zhang, and Stanley P. Sander

Subjects

Atmospheric Science, Scattering, Atmospheric sciences, Aerosol, Boundary layer, Geophysics, Atmospheric radiative transfer codes, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), Mixing ratio, Environmental science, Spectral resolution, Absorption (electromagnetic radiation), Total Carbon Column Observing Network

Abstract

The California Laboratory for Atmospheric Remote Sensing Fourier transform spectrometer (CLARS‐FTS) deployed at Mount Wilson, California, has been measuring column abundances of greenhouse gases in the Los Angeles (LA) basin in the near‐infrared spectral region since August 2011. CLARS‐FTS measures reflected sunlight and has high sensitivity to absorption and scattering in the boundary layer. In this study, we estimate the retrieval biases caused by aerosol scattering and present a fast and accurate approach to correct for the bias in the CLARS column averaged CO2 mixing ratio product, X_(CO2). The high spectral resolution of 0.06 cm^(−1) is exploited to reveal the physical mechanism for the bias. We employ a numerical radiative transfer model to simulate the impact of neglecting aerosol scattering on the CO_2 and O_2 slant column densities operationally retrieved from CLARS‐FTS measurements. These simulations show that the CLARS‐FTS operational retrieval algorithm likely underestimates CO_2 and O_2 abundances over the LA basin in scenes with moderate aerosol loading. The bias in the CO_2 and O_2 abundances due to neglecting aerosol scattering cannot be canceled by ratioing each other in the derivation of the operational product of X_(CO2). We propose a new method for approximately correcting the aerosol‐induced bias. Results for CLARS X_(CO2) are compared to direct‐Sun X_(CO2) retrievals from a nearby Total Carbon Column Observing Network (TCCON) station. The bias‐correction approach significantly improves the correlation between the X_(CO2) retrieved from CLARS and TCCON, demonstrating that this approach can increase the yield of useful data from CLARS‐FTS in the presence of moderate aerosol loading.

Published

2015

22. A non-monotonic eddy diffusivity profile of Titan's atmosphere revealed by Cassini observations

Author

Joshua A. Kammer, Run-Lie Shia, Xi Zhang, Yuk L. Yung, Cheng Li, and Mao-Chang Liang

Subjects

Reaction rate, symbols.namesake, Haze, Space and Planetary Science, Planet, symbols, Astronomy and Astrophysics, Atmosphere of Titan, Titan (rocket family), Atmospheric sciences, Stratosphere, Aerosol, Eddy diffusion

Abstract

Recent measurements from the limb-view soundings of Cassini/CIRS and the stellar occultations from Cassini/UVIS revealed the complete vertical profiles of minor species (e.g., C_2H_2 and C_2H_4) from 100 to 1000 km in the atmosphere of Titan. In this study, we developed an inversion technique to retrieve the eddy diffusion profile using C_2H_2 as a tracer species. The retrieved eddy profile features a low eddy diffusion zone near the altitude of the detached haze layer (~550 km), which could be a consequence of stabilization through aerosol heating. Photochemical modeling results using the retrieved eddy profile are in better agreement with the Cassini measurements than previous models. The underestimation of C_2H_4 in the stratosphere has been a long-standing problem in planetary photochemical modeling, and the new eddy diffusion profile does not solve this problem. In order to match the observations, we suggest a new expression for the rate coefficient of the key reaction, H + C_2H_4 + M⟶C_2H_5 + M. The new reaction rate coefficient is estimated to be ~10 times lower than that used by Moses et al. (2005)'s model, and should be validated in the laboratory and tested against the hydrocarbon chemistry of giant planets.

Published

2014

23. Constraints on the microphysics of Pluto's photochemical haze from New Horizons observations

Author

Peter Gao, Leslie A. Young, S. Alan Stern, Michael L. Wong, Mao-Chang Liang, Yuk L. Yung, Harold A. Weaver, G. Randall Gladstone, Catherine B. Olkin, Kimberly Ennico, Michael E. Summers, Joshua A. Kammer, Run-Lie Shia, and Siteng Fan

Subjects

Mass flux, Earth and Planetary Astrophysics (astro-ph.EP), Haze, 010504 meteorology & atmospheric sciences, Microphysics, FOS: Physical sciences, Astronomy and Astrophysics, Photochemistry, 01 natural sciences, Aerosol, Atmosphere, Pluto, symbols.namesake, Space and Planetary Science, 0103 physical sciences, Physics::Space Physics, symbols, Astrophysics::Earth and Planetary Astrophysics, Rayleigh scattering, Titan (rocket family), 010303 astronomy & astrophysics, Astrophysics - Earth and Planetary Astrophysics, 0105 earth and related environmental sciences

Abstract

The New Horizons flyby of Pluto confirmed the existence of hazes in its atmosphere. Observations of a large high- to low- phase brightness ratio, combined with the blue color of the haze, suggest that the haze particles are fractal aggregates, analogous to the photochemical hazes on Titan. Therefore, studying the Pluto hazes can shed light on the similarities and differences between the Pluto and Titan atmospheres. We model the haze distribution using the Community Aerosol and Radiation Model for Atmospheres assuming that the distribution is shaped by sedimentation and coagulation of particles originating from photochemistry. Hazes composed of both purely spherical and purely fractal aggregate particles are considered. Agreement between model results and occultation observations is obtained with aggregate particles when the downward flux of photochemical products is equal to the column-integrated methane destruction rate ~1.2 $\times$ 10$^{-14}$ g cm$^{-2}$ s$^{-1}$, while for spherical particles the mass flux must be 2-3 times greater. This flux is nearly identical to the haze production flux of Titan previously obtained by comparing microphysical model results to Cassini observations. The aggregate particle radius is sensitive to particle charging, and a particle charge to radius ratio of 30 e-/{\mu}m is necessary to produce ~0.1-0.2 {\mu}m aggregates near Pluto's surface, in accordance with forward scattering measurements. Such a particle charge to radius ratio is 2-4 times higher than those previously obtained for Titan. Hazes composed of spheres with the same particle charge to radius ratio have particles that are 4 times smaller. These results further suggest that the haze particles are fractal aggregates. We also consider the effect of condensation of HCN, and C$_{2}$-hydrocarbons on the haze particles, which may play an important role in shaping their distributions., Comment: 30 pages, 6 figures. Accepted for publication in Icarus

Published

2017

24. Profiling tropospheric CO2 using Aura TES and TCCON instruments

Author

Yuk L. Yung, S. C. Wofsy, James B. Abshire, Meemong Lee, B. J. Connor, Le Kuai, Christian Frankenberg, John Worden, Sébastien C. Biraud, Vijay Natraj, Debra Wunch, Run-Lie Shia, Susan S. Kulawik, Kevin W. Bowman, Charles E. Miller, and Coleen M. Roehl

Subjects

Troposphere, Atmospheric Science, Accuracy and precision, Tropospheric Emission Spectrometer, Thermal infrared, Global distribution, Environmental science, Measurement uncertainty, Atmospheric sciences, Total Carbon Column Observing Network, Standard deviation

Abstract

Monitoring the global distribution and long-term variations of CO2 sources and sinks is required for characterizing the global carbon budget. Total column measurements are useful for estimating regional-scale fluxes; however, model transport remains a significant error source, particularly for quantifying local sources and sinks. To improve the capability of estimating regional fluxes, we estimate lower tropospheric CO2 concentrations from ground-based near-infrared (NIR) measurements with space-based thermal infrared (TIR) measurements. The NIR measurements are obtained from the Total Carbon Column Observing Network (TCCON) of solar measurements, which provide an estimate of the total CO2 column amount. Estimates of tropospheric CO2 that are co-located with TCCON are obtained by assimilating Tropospheric Emission Spectrometer (TES) free tropospheric CO2 estimates into the GEOS-Chem model. We find that quantifying lower tropospheric CO2 by subtracting free tropospheric CO2 estimates from total column estimates is a linear problem, because the calculated random uncertainties in total column and lower tropospheric estimates are consistent with actual uncertainties as compared to aircraft data. For the total column estimates, the random uncertainty is about 0.55 ppm with a bias of −5.66 ppm, consistent with previously published results. After accounting for the total column bias, the bias in the lower tropospheric CO2 estimates is 0.26 ppm with a precision (one standard deviation) of 1.02 ppm. This precision is sufficient for capturing the winter to summer variability of approximately 12 ppm in the lower troposphere; double the variability of the total column. This work shows that a combination of NIR and TIR measurements can profile CO2 with the precision and accuracy needed to quantify lower tropospheric CO2 variability.

Published

2013

25. Investigating Wavelength-Dependent Aerosol Optical Properties Using Water Vapor Slant Column Retrievals from CLARS over the Los Angeles Basin

Author

K. W. Wong, Dejian Fu, Qiong Zhang, Sally Newman, Stanley P. Sander, Zhao-Cheng Zeng, Paul O. Wennberg, Thomas J. Pongetti, Yuk L. Yung, Jack S. Margolis, and Run-Lie Shia

Subjects

Wavelength, Structural basin, Atmospheric sciences, Column (database), Geology, Water vapor, Aerosol

Abstract

In this study, we propose a novel approach to constrain the optical properties of atmospheric aerosol in a complex urban environment using water vapor (H2O) slant column measurements in the near infrared. This approach is demonstrated using measurements from the California Laboratory for Atmospheric Remote Sensing Fourier Transform Spectrometer (CLARS-FTS) on the top of Mt. Wilson, California, and a two-stream-exact single scattering (2S-ESS) radiative transfer (RT) model. From the spectral measurements, we retrieve H2O slant column density (SCD) using 15 different absorption bands between 4000 and 8000 cm−1. Due to the wavelength dependence of aerosol scattering, large variations in H2O SCD retrievals are observed as a function of wavelength. Moreover, the variations are found to be correlated with aerosol optical depths (AOD) measured at the AERONET-Caltech station. Simulation results from the RT model reproduce this correlation and show that the aerosol scattering is the primary contributor to the variations in the wavelength dependence of the H2O SCD retrievals. The evidence from both measurements and simulations suggest that wavelength-dependent aerosol optical properties can be constrained using H2O retrievals from multiple bands.

Published

2016

26. Vertically constrained CO2 retrievals from TCCON measurements

Author

Brian J. Connor, Run-Lie Shia, Yuk L. Yung, Charles E. Miller, Debra Wunch, and Le Kuai

Subjects

Radiation, Absorption spectroscopy, Solar zenith angle, Information analysis, Atmospheric sciences, Atomic and Molecular Physics, and Optics, Spectral line, Troposphere, Absorption band, Mixing ratio, Environmental science, Total Carbon Column Observing Network, Spectroscopy, Remote sensing

Abstract

Partial column-averaged carbon dioxide (CO_2) mixing ratio in three tropospheric layers has been retrieved from Total Carbon Column Observing Network (TCCON) spectra in the 1.6 μm CO_2 absorption band. Information analysis suggests that a measurement with ∼60 absorption lines provides three or more pieces of independent information, depending on the signal-to-noise ratio and solar zenith angle. This has been confirmed by retrievals based on synthetic data. Realistic retrievals for both total and partial column-averaged CO_2 over Park Falls, Wisconsin on July 12, 15, and August 14, 2004, agree with aircraft measurements. Furthermore, the retrieved total column averages are always underestimated by less than 1%. The results above provide a basis for CO_2 profile retrievals using ground-based observations in the near-infrared region.

Published

2012

27. El Niño–Southern Oscillation in Tropical and Midlatitude Column Ozone

Author

Yuk L. Yung, Steven Pawson, Baijun Tian, Xun Jiang, Jingqian Wang, Mao-Chang Liang, and Run Lie Shia

Subjects

Atmospheric Science, Ozone, Dobson unit, Forcing (mathematics), Atmospheric sciences, Solar cycle, Sea surface temperature, chemistry.chemical_compound, chemistry, Middle latitudes, Climatology, Environmental science, Climate model, Tropopause

Abstract

The impacts of El Niño–Southern Oscillation (ENSO) on the tropical total column ozone, the tropical tropopause pressure, and the 3.5-yr ozone signal in the midlatitude total column ozone were examined using the Goddard Earth Observing System Chemistry–Climate Model (GEOS CCM). Observed monthly mean sea surface temperature and sea ice between 1951 and 2004 were used as boundary conditions for the model. Since the model includes no solar cycle, quasi-biennial oscillation, or volcanic forcing, the ENSO signal was found to dominate the tropical total column ozone variability. Principal component analysis was applied to the detrended, deseasonalized, and low-pass filtered model outputs. The first mode of model total column ozone captured 63.8% of the total variance. The spatial pattern of this mode was similar to that in Total Ozone Mapping Spectrometer (TOMS) observations. There was also a clear ENSO signal in the tropical tropopause pressure in the GEOS CCM, which is related to the ENSO signal in the total column ozone. The regression coefficient between the model total column ozone and the model tropopause pressure was 0.71 Dobson units (DU) hPa−1. The GEOS CCM was also used to investigate a possible mechanism for the 3.5-yr signal observed in the midlatitude total column ozone. The 3.5-yr signal in the GEOS CCM column ozone is similar to that in the observations, which suggests that a model with realistic ENSO can reproduce the 3.5-yr signal. Hence, it is likely that the 3.5-yr signal was caused by ENSO.

Published

2011

28. Channel selection using information content analysis: A case study of CO2 retrieval from near infrared measurements

Author

Charles E. Miller, Vijay Natraj, Le Kuai, Run-Lie Shia, and Yuk L. Yung

Subjects

Radiation, Materials science, Observatory, Near-infrared spectroscopy, Thermal infrared remote sensing, Information analysis, Absorption (electromagnetic radiation), Spectroscopy, Atomic and Molecular Physics, and Optics, Retrieval algorithm, Communication channel, Remote sensing

Abstract

A major challenge in retrieving CO_2 concentrations from thermal infrared remote sensing comes from the fact that measurements in the 4.3 and 15 μm absorption bands (AIRS or TES) are sensitive to both temperature and CO_2 variations. This complicates the selection of absorption channels with maximum CO_2 concentration information content. In contrast, retrievals using near infrared (NIR) CO_2 absorption bands are relatively insensitive to temperature and are most sensitive to changes of CO_2 near the surface, where the sources and sinks are located. The Orbiting Carbon Observatory (OCO) was built to measure reflected sunlight in three NIR spectral regions (the 0.76 μm O_2 A-band and two CO_2 bands at 1.61 and 2.06 μm). In an effort to significantly increase the speed of accurate CO_2 retrieval algorithms for OCO, we performed an information content analysis to identify the 20 best channels from each CO_2 spectral region to use in OCO retrievals. Retrievals using these 40 channels provide as much as 75% of the total CO_2 information content compared to retrievals using all 1016 channels in each spectral region. The CO_2 retrievals using our selected channels have a precision better than 0.1 ppm. This technique can be applied to the retrieval of other geophysical variables (e.g., temperature or CH_4), or modified for other instruments, such as AIRS or TES.

Published

2010

29. On the use of principal component analysis to speed up radiative transfer calculations

Author

Vijay Natraj, Run-Lie Shia, and Yuk L. Yung

Subjects

Physics, Radiation, Atmospheric radiative transfer codes, Single-scattering albedo, Principal component analysis, Near-infrared spectroscopy, Radiative transfer, Monochromatic color, Spectral resolution, Spectroscopy, Atomic and Molecular Physics, and Optics, Optical depth, Remote sensing

Abstract

Radiative transfer is computationally expensive. However, it is essential to many applications, in particular remote sensing retrievals. Principal component analysis of the optical depth and single scattering albedo profiles has been proposed as a possible method to help ease the computational burden. Here we show how the technique could be applied to a practical problem of CO_2 retrievals from high spectral resolution measurements of reflected sunlight in three near infrared bands. We obtain a speed improvement of more than 50 fold (compared to monochromatic computations), while reproducing the radiances to better than 0.1% accuracy.

Published

2010

30. Infinite sum of the product of exponential and logarithmic functions, its analytic continuation, and application

Author

Run-Lie Shia, Cameron Taketa, Yuk L. Yung, and Ross Cheung

Subjects

Series (mathematics), Applied Mathematics, Analytic continuation, Function (mathematics), Divergent series, Riemann zeta function, Ramanujan's sum, Exponential integral, Combinatorics, symbols.namesake, Digamma function, symbols, Discrete Mathematics and Combinatorics, Mathematics

Abstract

We show that the function S_(1)(x) = ∑_(k=1)^∞ e^(-2πkx) log k can be expressed as the sum of a simple function and an infinite series, whose coefficients are related to the Riemann zeta function. Analytic continuation to the imaginary argument S_(1)(ix) = K_0(x) is made. For x = p/q where p and q are integers with p < q, closed finite sum expressions for K_0(p/q) and K_1(p/q) are derived. The latter results enable us to evaluate Ramanujan's function ψ(x) = ∑_(k=1)^∞ [(logk)/k - (log(k+x))/(k+x)] for x = -2/3, -3/4, and -5/6, confirming what Ramanujan claimed but did not explicitly reveal in his Notebooks. The interpretation of a pair of apparently inscrutable divergent series in the notebooks is discussed. They reveal hitherto unsuspected connections between Ramanujan's ψ(x), K_0(x), K_1(x), and the classical formulas of Gauss and Kummer for the digamma function

Published

2010

31. Nonstationary Synchronization of Equatorial QBO with SAO in Observations and a Model

Author

Le Kuai, Run-Lie Shia, Ka-Kit Tung, Xun Jiang, and Yuk L. Yung

Subjects

Quasi-biennial oscillation, Atmospheric Science, Stratopause, Climatology, Southern oscillation, Forcing (mathematics), Atmospheric sciences, Stratosphere, Geology, Synchronization

Abstract

It has often been suggested that the period of the quasi-biennial oscillation (QBO) has a tendency to synchronize with the semiannual oscillation (SAO). Apparently the synchronization is better the higher up the observation extends. Using 45 yr of the 40-yr European Centre for Medium-Range Weather Forecasts (ECMWF) Re-Analysis (ERA-40) data of the equatorial stratosphere up to the stratopause, the authors confirm that this synchronization is not just a tendency but a robust phenomenon in the upper stratosphere. A QBO period starts when a westerly SAO (w-SAO) descends from the stratopause to 7 hPa and initiates the westerly phase of the QBO (w-QBO) below. It ends when another w-SAO, a few SAO periods later, descends again to 7 hPa to initiate the next w-QBO. The fact that it is the westerly but not the easterly SAO (e-SAO) that initiates the QBO is also explained by the general easterly bias of the angular momentum in the equatorial stratosphere so that the e-SAO does not create a zero-wind line, unlike the w-SAO. The currently observed average QBO period of 28 months, which is not an integer multiple of SAO periods, is a result of intermittent jumps of the QBO period from four SAO to five SAO periods. The same behavior is also found in the Two and a Half Dimensional Interactive Isentropic Research (THINAIR) model. It is found that the nonstationary behavior in both the observation and model is caused not by the 11-yr solar-cycle forcing but by the incompatibility of the QBO’s natural period (determined by its wave forcing) and the “quantized” period determined by the SAO. The wave forcing parameter for the QBO period in the current climate probably lies between four SAO and five SAO periods. If the wave forcing for the QBO is tuned so that its natural period is compatible with the SAO period above (e.g., at 24 or 30 months), nonstationary behavior disappears.

Published

2009

32. Interannual Variability and Trends of Extratropical Ozone. Part II: Southern Hemisphere

Author

Xun Jiang, Steven Pawson, Charles D. Camp, J. Eric Nielsen, Run-Lie Shia, Ting Liao, Varavut Limpasuvan, and Yuk L. Yung

Subjects

Atmospheric Science

Abstract

A principal component analysis (PCA) is applied to the Southern Hemisphere (SH) total column ozone following the method established for analyzing the data in the Northern Hemisphere (NH) in a companion paper. The interannual variability (IAV) of extratropical O3 in the SH is characterized by four main modes, which account for 75% of the total variance. The first two leading modes are approximately zonally symmetric and relate to the Southern Hemisphere annular mode and the quasi-biennial oscillation. The third and fourth modes exhibit wavenumber-1 structures. Contrary to the Northern Hemisphere, the third and fourth modes are not related to stationary waves. Similar results are obtained for the 30–100-hPa geopotential thickness. The decreasing O3 trend in the SH is captured in the first mode. The largest trend is at the South Pole, with value ∼−2 Dobson Units (DU) yr−1. Both the spatial pattern and trends in the column ozone are captured by the Goddard Earth Observation System chemistry–climate model (GEOS-CCM) in the SH.

Published

2008

33. Retrieval of ozone profile from ground-based measurements with polarization: A synthetic study

Author

Yuk L. Yung, Stanley P. Sander, Run-Lie Shia, Robert Spurr, Xin Guo, Vijay Natraj, and Daniel Feldman

Subjects

Physics, Radiation, Optimal estimation, Scattering, Polarization (waves), Information theory, Atomic and Molecular Physics, and Optics, symbols.namesake, chemistry.chemical_compound, chemistry, symbols, Stokes parameters, Tropospheric ozone, Rayleigh scattering, Spectral resolution, Physics::Atmospheric and Oceanic Physics, Spectroscopy, Remote sensing

Abstract

We perform a retrieval based on optimal estimation theory to retrieve the vertical distribution of ozone from simulated spectra in the Huggins bands. The model atmosphere includes scattering by aerosol as well as Rayleigh scattering. The virtual instrument is ground-based and zenith-viewing. Using this algorithm, we show that it is possible to retrieve the ozone profile provided that the spectral resolution is at least 0.2 nm and the signal to noise ratio greater than 500. Our synthetic retrievals suggest that if we are able to measure the Stokes parameters Q, U and V with accuracy comparable to that of the intensity, the information contained in the measurements, and therefore the inversion, will improve. Furthermore, we find that the measurement of the full Stokes vector from the ground-based instrument will especially enhance the retrieval of tropospheric ozone. Utilizing concepts from information theory, our arguments are confirmed by increases in the degrees of freedom and the Shannon information content in the simulated measurements.

Published

2007

34. Application of principal component analysis to high spectral resolution radiative transfer: A case study of the band

Author

Jack S. Margolis, Vijay Natraj, Xianglei Huang, Yuk L. Yung, Run Lie Shia, and Xun Jiang

Subjects

Physics, Radiation, business.industry, Scattering, Computation, Atomic and Molecular Physics, and Optics, Atmospheric radiative transfer codes, Optics, Transmission (telecommunications), Principal component analysis, Radiative transfer, Spectral resolution, business, Spectroscopy, Order of magnitude

Abstract

Radiative transfer computation is the rate-limiting step in most high spectral resolution remote sensing retrieval applications. While several techniques have been proposed to speed up radiative transfer calculations, they all suffer from accuracy considerations. We propose a new method, based on a principal component analysis of the optical properties of the system, that addresses these concerns. Taking atmospheric transmission in the O_2A band as a test case, we reproduced the reflectance spectrum at the top of the atmosphere (TOA), obtained using the multiple scattering code DISORT, with an accuracy of 0.3%, while achieving an order of magnitude improvement in speed.

Published

2005

35. Contributions of global and regional sources to mercury deposition in New York State

Author

Krish Vijayaraghavan, Run Lie Shia, Kristen Lohman, and Christian Seigneur

Subjects

Canada, Asia, Chemical transport model, Meteorology, Health, Toxicology and Mutagenesis, New York, Air pollution, Industrial Waste, chemistry.chemical_element, Atmospheric model, Toxicology, Atmospheric sciences, medicine.disease_cause, medicine, Computer Simulation, Air Pollutants, Mercury, General Medicine, Pollution, United States, Mercury (element), Aerosol, Europe, Models, Chemical, chemistry, Atmospheric chemistry, Model simulation, Environmental science, Mercury deposition

Abstract

A modeling system that includes a global chemical transport model (CTM) and a nested continental CTM (TEAM) was used to simulate the atmospheric transport, transformations and deposition of mercury (Hg). Three scenarios were used: (1) a nominal scenario, (2) a scenario conducive to local deposition and (3) a scenario conducive to long-range transport. Deposition fluxes of Hg were analyzed at three receptor locations in New York State. For the nominal scenario, the anthropogenic emission sources (including re-emission of deposited Hg) in New York State, the rest of the contiguous United States, Asia, Europe, and Canada contributed 11–21, 25–49, 13–19, 5–7, and 2–5%, respectively to total Hg deposition at these three receptors. Natural sources contributed 16–24%. The results from the local deposition and long-range transport scenarios varied only slightly from these results. However, there are still uncertainties in our understanding of the atmospheric chemistry of Hg that are likely to affect these estimates of local, regional and global contributions. Comparison of model simulation results with data from the Mercury Deposition Network suggests that local and regional contributions may currently be overestimated.

Published

2003

36. On the effect of spatial resolution on atmospheric mercury modeling

Author

Krish Vijayaraghavan, Leonard Levin, Prakash Karamchandani, Run-Lie Shia, Kristen Lohman, and Christian Seigneur

Subjects

Air Movements, MERCURE, Air Pollutants, Environmental Engineering, Coefficient of determination, Meteorology, Rain, Air pollution, Atmospheric mercury, chemistry.chemical_element, Mercury, Models, Theoretical, Atmospheric sciences, medicine.disease_cause, Pollution, United States, Mercury (element), chemistry, medicine, Environmental Chemistry, Environmental science, Poor correlation, Waste Management and Disposal, Image resolution, Forecasting

Abstract

Mathematical modeling of the atmospheric fate and transport of mercury (Hg) was conducted using three nested domains covering global, continental and regional scales with horizontal resolutions of approximately 1000, 100 and 20 km, respectively. Comparisons of modeling results with wet deposition fluxes show a coefficient of determination (r(2)) of 0.45 for the continental simulation and 0.14 for the continental/regional simulation. The poor correlation obtained in the regional simulation results to a large extent from the fact that the model predicts an increasing gradient in Hg wet deposition from Minnesota to Pennsylvania, which is not observed in the monitoring network. The use of a finer spatial resolution (20 km) improves model performance in Minnesota and Wisconsin (upwind of major Hg emission sources) but degrades model performance in Pennsylvania (downwind of major Hg emission sources). We suggest the hypothesis that some key Hg chemical transformations are likely missing in current models of atmospheric Hg.

Published

2003

37. New insights into martian atmospheric chemistry

Author

Run-Lie Shia, H. Nair, C. S. Boxe, Joseph S. Francisco, Alfonso Saiz-Lopez, Mao-Chang Liang, and Yuk L. Yung

Subjects

Reaction mechanism, Photodissociation, Quantum yield, Astronomy and Astrophysics, Mars Exploration Program, Atmosphere of Mars, Atmospheric sciences, Atmosphere, chemistry.chemical_compound, chemistry, Space and Planetary Science, Atmospheric chemistry, Physical chemistry, Carbon monoxide

Abstract

HOx radicals are produced in the martian atmosphere by the photolysis of water vapor and subsequently participate in catalytic cycles that recycle carbon dioxide (CO2) from its photolysis product carbon monoxide (CO), providing a qualitative explanation for the stability of its atmosphere. Balancing CO2 production and loss based on our current understanding of martian gas-phase chemistry has, however, proven to be difficult. The photolysis of O3 produces O(1D), while oxidation of CO produces HOCO radicals, a new member of the HOx family. The O(1D) quantum yield has recently been updated, which quantifies nonzero quantum yields in the Huggins bands. In Earth's atmosphere HOCO is considered to be unimportant since it is quickly removed by abundant oxygen molecules. The smaller amount of O2 in the Mars' atmosphere causes HOCO's lifetime to be longer in Mars' atmosphere than Earth's (3×10-5s to 1.2days from Mars's surface to 240km, respectively). Limited kinetic data on reactions involving HOCO prevented consideration of its reactions directly in atmospheric models. Therefore, the impact of HOCO reactions on martian chemistry is currently unknown. Here, we incorporate new literature rate constants for HOCO chemistry and an updated representation of the O(1D) quantum yield in the Caltech/JPL 1-D photochemical model for Mars' atmosphere. Our simulations exemplify perturbations to NOy, HOx, and COx species, ranging from 5% to 50%. The modified O(1D) quantum yield and new HOCO chemistry cause a 10% decrease and a 50% increase in OH and H2O2 total column abundances, respectively. At low altitudes, HOCO production contributes 5% towards CO2 production. Given recent experimentally-obtained branching ratios for the oxidation of CO, HOCO may contribute up to 70% toward the production of NOy, where HOx and NOy species are enhanced up to a factor 3, which has implications for rethinking the fundamental understanding of NOy, HOx, and CO/CO2 cycling on Mars. Two new reaction mechanisms for converting CO to CO2 using HOCO reactions are proposed, which reveal that H2O2 is more intimately coupled to COx chemistry. Our simulations are in good agreement with satellite/spacecraft measurements of CO and H2O2 on Mars. © 2014.

Published

2014

38. Multiscale modeling of the atmospheric fate and transport of mercury

Author

Prakash Karamchandani, Kristen Lohman, Krish Vijayaraghavan, Run-Lie Shia, and Christian Seigneur

Subjects

MERCURE, Atmospheric Science, Coefficient of determination, Chemical transport model, Meteorology, Air pollution, Soil Science, chemistry.chemical_element, Aquatic Science, Oceanography, medicine.disease_cause, Atmospheric sciences, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), medicine, Earth-Surface Processes, Water Science and Technology, Ecology, Computer simulation, Paleontology, Forestry, Multiscale modeling, Mercury (element), Geophysics, chemistry, Space and Planetary Science, Atmospheric chemistry, Environmental science

Abstract

A numerical simulation of the atmospheric fate and transport of mercury (Hg) was conducted using a multiscale approach. Two different spatial scales were used to simulate (1) the global cycling of atmospheric Hg and (2) the atmospheric deposition of Hg in potentially sensitive areas. The global simulation was conducted using an updated version of our global Hg chemical transport model (CTM). The imbedded continental simulation was conducted using an updated version of the regional/continental CTM, TEAM. Simulations were conducted using 1998 meteorology and 1998/1999 emission inventories. Model simulation results show improved performance compared to earlier simulations. For example, the global simulation shows background concentrations of Hg species, interhemispheric gradients, and vertical gradients that are consistent with available measurements. The comparison of simulated Hg wet deposition fluxes with data from the Mercury Deposition Network in the United States shows a coefficient of determination (r2) of 0.75, little bias (−3%), and an average gross error of 21%. The major remaining sources of uncertainties, which include speciation of Hg emissions, Hg atmospheric chemistry, and dry and wet deposition processes for Hg species, are discussed.

Published

2001

39. Global simulation of atmospheric mercury concentrations and deposition fluxes

Author

Malcolm K. W. Ko, Nien Dak Sze, Christian Seigneur, Run-Lie Shia, and Prasad Pai

Subjects

MERCURE, Atmospheric Science, Soil Science, chemistry.chemical_element, Mineralogy, Aquatic Science, Oceanography, Chemical reaction, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), medicine, Earth-Surface Processes, Water Science and Technology, Aqueous solution, Ecology, Aqueous two-phase system, Paleontology, Forestry, Seasonality, Particulates, medicine.disease, Mercury (element), Geophysics, Deposition (aerosol physics), chemistry, Space and Planetary Science, Environmental chemistry

Abstract

Results from a numerical model of the global emissions, transport, chemistry, and deposition of mercury (Hg) in the atmosphere are presented. Hg (in the form of Hg(O) and Hg(II)) is emitted into the atmosphere from natural and anthropogenic sources (estimated to be 4000 and 2100 Mg/ yr, respectively). It is distributed between gaseous, aqueous and particulate phases. Removal of Hg from the atmosphere occurs via dry deposition and wet deposition, which are calculated by the model to be 3300 and 2800 Mg/ yr, respectively. Deposition on land surfaces accounts for 47% of total global deposition. The simulated Hg ambient surface concentrations and deposition fluxes to the Earth's surface are consistent with available observations. Observed spatial and seasonal trends are reproduced by the model, although larger spatial variations are observed in Hg(O) surface concentrations than are predicted by the model. The calculated atmospheric residence time of Hg is -1.7 years. Chemical transformations between Hg(O) and HG(II) have a strong influence on Hg deposition patterns because HG(II) is removed faster than Hg(O). Oxidation of Hg(O) to HG(II) occurs primarily in the gas phase, whereas HG(II) reduction to Hg(O) occurs solely in the aqueous phase. Our model results indicated that in the absence of the aqueous reactions the atmospheric residence time of Hg is reduced to 1.2 from 1.7 years and the Hg surface concentration is -25% lower because of the absence of the HG(II) reduction pathway. This result suggests that aqueous chemistry is an essential component of the atmospheric cycling of Hg.

Published

1999

40. Atmospheric lifetime and global warming potential of HFC-245fa

Author

Malcolm K. W. Ko, Nien Dak Sze, Hillel Magid, Run-Lie Shia, and Robert G. Bray

Subjects

Atmospheric Science, Ecology, Global warming, Paleontology, Soil Science, Climate change, Forestry, Scale height, Aquatic Science, Radiative forcing, Oceanography, Jet propulsion, chemistry.chemical_compound, Geophysics, Reaction rate constant, chemistry, Space and Planetary Science, Geochemistry and Petrology, Climatology, Carbon dioxide, Earth and Planetary Sciences (miscellaneous), Environmental science, Stratosphere, Earth-Surface Processes, Water Science and Technology

Abstract

We describe the method used to compute the global warming potential of hydrofluorocarbon (HFC) 245fa (CHF2CH2CF3). The Atmospheric and Environmental Research (AER) two-dimensional (latitude-height) chemistry-transport model was used to calculate the atmospheric lifetime and atmospheric scale height of HFC-245fa. Assuming that reaction with OH is the only removal mechanism, the recommended rate constant from Jet Propulsion Laboratory [1997] (6.1 × 10−13 exp (−1330/T) cm3 s−1) implies a lifetime of 7.6 years and an average atmospheric scale height of 35 km in the stratosphere. Using the IR absorption cross sections for HFC-245fa and CFC-11 determined in the laboratory, the AER one-dimensional radiative-convective model was used to calculate the radiative forcing. The value for HFC-245fa is 1.14 times larger than that for CFC-11 on a mass basis and 1.11 larger on a per molecule basis. The global warming potentials for HFC-245fa (relative to carbon dioxide) are 2400, 760, and 240 (based on the values for absolute global warming potential for carbon dioxide reported by Intergovernmental Panel on Climate Change [1996]) at integration time horizons of 20, 100, and 500 years, respectively.

Published

1999

41. Transport between the tropical and midlatitude lower stratosphere: Implications for ozone response to high-speed civil transport emissions

Author

Malcolm K. W. Ko, Courtney J. Scott, Jose M. Rodriguez, Run-Lie Shia, and D. K. Weisenstein

Subjects

Atmospheric Science, Ozone, Turbulent diffusion, Ecology, Airflow, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Eddy diffusion, Atmosphere, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Climatology, Middle latitudes, Earth and Planetary Sciences (miscellaneous), Tropopause, Stratosphere, Earth-Surface Processes, Water Science and Technology

Abstract

Several recent studies have quantified the air exchange rate between the tropics and midlatitudes in the lower stratosphere using airborne and satellite measurements of chemical species. It is found that the midlatitude air is mixed into the tropical lower stratosphere with a replacement timescale of 13.5 months (with 20% uncertainty) for the region from the tropopause to 21 km and at least 18 months for the region of 20-28 km. These estimates are used to adjust the horizontal eddy diffusion coefficients, K(sub yy), in a two-dimensional chemistry transport model. The value of K(sub yy) previously used to simulate the subtropical barrier, 0.03 x 10(exp 6)sq m/s, generates an exchange time of about 4 years, and the model without subtropical barrier (K(sub yy) = 0.3 x 10(exp 6)sq m/s) has an exchange time of 5 months. Adjusting the K(sub yy) to 0.13 x 10(exp 6) sq m/s from the tropopause to 21 km and 0.07 x 10(exp 6)sq m/s above 21 km produces the exchange timescales which match the estimates deduced from the measurements. The subtropical barrier prevents the engine emissions of the high-speed civil transport (HSCT) aircraft from being transported into the tropics and subsequently lifted into the upper atmosphere or mixed into the southern hemisphere. The model results show that the calculated ozone response to HSCT aircraft emissions using the K(sub yy), adjusted to observed mixing rates is substantially smaller than that simulated without the subtropical barrier.

Published

1998

42. An Estimation of the Climatic Effects of Stratospheric Ozone Losses during the 1980s

Author

Run-Lie Shia, Gyula Molnar, Yajaing Yang, Shuntai Zhou, Malcolm K. W. Ko, and Robert M. MacKay

Subjects

Atmospheric Science, Ozone, Radiative forcing, Atmospheric sciences, Ozone depletion, chemistry.chemical_compound, chemistry, Greenhouse gas, Climatology, Ozone layer, Climate sensitivity, Environmental science, Climate model, Stratosphere

Abstract

In order to study the potential climatic effects of the ozone hole more directly and to assess the validity of previous lower resolution model results, the latest high spatial resolution version of the Atmospheric and Environmental Research, Inc., seasonal radiative dynamical climate model is used to simulate the climatic effects of ozone changes relative to the other greenhouse gases. The steady-state climatic effect of a sustained decrease in lower stratospheric ozone, similar in magnitude to the observed 1979-90 decrease, is estimated by comparing three steady-state climate simulations: 1) 1979 greenhouse gas concentrations and 1979 ozone, II) 1990 greenhouse gas concentrations with 1979 ozone, and III) 1990 greenhouse gas concentrations with 1990 ozone. The simulated increase in surface air temperature resulting from nonozone greenhouse gases is 0.272 K. When changes in lower stratospheric ozone are included, the greenhouse warming is 0.165 K, which is approximately 39% lower than when ozone is fixed at the 1979 concentrations. Ozone perturbations at high latitudes result in a cooling of the surface-troposphere system that is greater (by a factor of 2.8) than that estimated from the change in radiative forcing resulting from ozone depiction and the model's 2 x CO, climate sensitivity. The results suggest that changes in meridional heat transport from low to high latitudes combined with the decrease in the infrared opacity of the lower stratosphere are very important in determining the steady-state response to high latitude ozone losses. The 39% compensation in greenhouse warming resulting from lower stratospheric ozone losses is also larger than the 28% compensation simulated previously by the lower resolution model. The higher resolution model is able to resolve the high latitude features of the assumed ozone perturbation, which are important in determining the overall climate sensitivity to these perturbations.

Published

1997

43. Potential Environmental Impact of a Hydrogen Economy on the Stratosphere

Author

Yuk L. Yung, Mark Allen, Tracey K. Tromp, John M. Eiler, and Run-Lie Shia

Subjects

Multidisciplinary, Ozone, Meteorology, business.industry, Hydrogen molecule, Atmospheric sciences, chemistry.chemical_compound, chemistry, Hydrogen fuel, Hydrogen economy, Tropospheric chemistry, Environmental science, Environmental impact assessment, business, Stratosphere, Water vapor

Abstract

The widespread use of hydrogen fuel cells could have hitherto unknown environmental impacts due to unintended emissions of molecular hydrogen, including an increase in the abundance of water vapor in the stratosphere (plausibly by as much as ∼1 part per million by volume). This would cause stratospheric cooling, enhancement of the heterogeneous chemistry that destroys ozone, an increase in noctilucent clouds, and changes in tropospheric chemistry and atmosphere-biosphere interactions.

Published

2003

44. Cross-tropopause transport of excess14C in a two-dimensional model

Author

V. Rao Kotamarthi, Malcolm K. W. Ko, Min Zou, and Run-Lie Shia

Subjects

Atmospheric Science, Ecology, Reactive nitrogen, Paleontology, Soil Science, Flux, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Ozone depletion, Eddy diffusion, chemistry.chemical_compound, Geophysics, chemistry, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Environmental science, Nitrogen oxide, Diffusion (business), Tropopause, Stratosphere, Earth-Surface Processes, Water Science and Technology

Abstract

The processed excess 14C data are used to calibrate the cross-tropopause transport in a two-dimensional model. The model results are used to diagnose the mechanisms responsible for cross-tropopause transport in the model and the sensitivity of the transport rate to the changes in the transport parameter. Although the total flux across the tropopause is dominated by the eddy diffusion flux along the isentropic surface due to the large values assigned to the diffusion coefficient Kyy at the boundary, the cross-tropopause transport is more sensitive to changes in the circulation. Nitrogen oxides emitted by engines of high-speed civil transport could cause ozone depletion in the lower stratosphere. The expected depletion is proportional to the amount of oxides of nitrogen retained in the stratosphere. For a typical fleet, lowering the tropopause height by 1.2 km can cause a 14–22% increase in the amount of reactive nitrogen retained in the stratosphere. Thus it is necessary to have a fine enough vertical resolution near the tropopause in the two-dimensional model for determining the stratospheric residence time of the engine emissions deposited near the tropopause.

Published

1993

45. Modulation of the Period of the Quasi-Biennial Oscillation by the Solar Cycle

Author

Yuk L. Yung, Xun Jiang, Le Kuai, Ka-Kit Tung, and Run-Lie Shia

Subjects

Quasi-biennial oscillation, Atmospheric Science, Oscillation, Climatology, Modulation (music), Range (statistics), Environmental science, Forcing (mathematics), Atmospheric sciences, Stratosphere, Solar cycle, Aerosol

Abstract

The authors examine the mechanism of solar cycle modulation of the Quasi-Biennial Oscillation (QBO) period using the Two-and-a-Half-Dimensional Interactive Isentropic Research (THINAIR) model. Previous model results (using 2D and 3D models of varying complexity) have not convincingly established the proposed link of longer QBO periods during solar minima. Observational evidence for such a modulation is also controversial because it is only found during the period from the 1960s to the early 1990s, which is contaminated by volcanic aerosols. In the model, 200- and 400-yr runs without volcano influence can be obtained, long enough to establish some statistical robustness. Both in model and observed data, there is a strong synchronization of the QBO period with integer multiples of the semiannual oscillation (SAO) in the upper stratosphere. Under the current level of wave forcing, the period of the QBO jumps from one multiple of SAO to another and back so that it averages to 28 months, never settling down to a constant period. The “decadal” variability in the QBO period takes the form of “quantum” jumps; these, however, do not appear to follow the level of the solar flux in either the observation or the model using realistic quasi-periodic solar cycle (SC) forcing. To understand the solar modulation of the QBO period, the authors perform model runs with a range of perpetual solar forcing, either lower or higher than the current level. At the current level of solar forcing, the model QBO period consists of a distribution of four and five SAO periods, similar to the observed distribution. This distribution changes as solar forcing changes. For lower (higher) solar forcing, the distribution shifts to more (less) four SAO periods than five SAO periods. The record-averaged QBO period increases with the solar forcing. However, because this effect is rather weak and is detectable only with exaggerated forcing, the authors suggest that the previous result of the anticorrelation of the QBO period with the SC seen in short observational records reflects only a chance behavior of the QBO period, which naturally jumps in a nonstationary manner even if the solar forcing is held constant, and the correlation can change as the record gets longer.

Published

2009

46. Evidence for carbonyl sulfide (OCS) conversion to CO in the lower atmosphere of Venus

Author

Bruno Bézard, Mao-Chang Liang, Run-Lie Shia, Emmanuel Marcq, Yuk L. Yung, Xun Jiang, Christopher C. Lee, Division of Geological and Planetary Sciences [Pasadena], California Institute of Technology (CALTECH), Research Center for Environmental Changes [Taipei], Academia Sinica, Institute of Astronomy [Taiwan] (IANCU), National Central University [Taiwan] (NCU), Department of Earth and Atmospheric Sciences [Houston], University of Houston, Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA (UMR_8109)), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Soil Science, Model parameters, Venus, Aquatic Science, Oceanography, Atmospheric sciences, 01 natural sciences, Atmosphere of Venus, chemistry.chemical_compound, Geochemistry and Petrology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology, Carbonyl sulfide, Thermal equilibrium, Ecology, biology, Paleontology, Forestry, biology.organism_classification, Geophysics, chemistry, 13. Climate action, Space and Planetary Science, [SDU]Sciences of the Universe [physics], General Circulation Model, Environmental science

Abstract

International audience; The chemical regimes in the atmosphere of Venus vary from photochemistry in the middle atmosphere to thermal equilibrium chemistry in the lower atmosphere and the surface. Many chemical cycles have been proposed, but few details about these cycles are fully verified by comparison between observations and modeling. Recent high-quality data of carbonyl sulfide (OCS) and CO from ground-based and Venus Express observations provide a unique opportunity to test our understanding of chemistry and transport in the lower atmosphere of Venus. The spatial distributions of OCS and CO in the atmosphere reflect a sensitive balance between chemistry and transport. On the basis of our updated photochemical model and winds from Lee et al.'s (2007) general circulation model, we study the chemistry and transport in a simplified two-dimensional chemistry-transport model. OCS is produced by heterogeneous reactions on the surface; the middle atmosphere is a net sink for OCS. The combination of data and modeling provides strong evidence for the loss of OCS by conversion to CO. The detailed chemical mechanism is currently unknown, although a number of speculations have been proposed. The sensitivity of the distributions of OCS and CO to model parameters is reported.

Published

2009

47. Simulation of upper tropospheric CO2from chemistry and transport models

Author

Moustafa T. Chahine, Mao-Chang Liang, Qinbin Li, Luke L. Chen, Yuk L. Yung, Run-Lie Shia, Xun Jiang, and Edward T. Olsen

Subjects

Mass flux, Convection, Atmospheric Science, Global and Planetary Change, Northern Hemisphere, Atmospheric sciences, Jet propulsion, Troposphere, Amplitude, Middle latitudes, Climatology, Environmental Chemistry, Southern Hemisphere, General Environmental Science

Abstract

The California Institute of Technology/Jet Propulsion Laboratory two-dimensional (2-D), three-dimensional (3-D) GEOS-Chem, and 3-D MOZART-2 chemistry and transport models (CTMs), driven respectively by NCEP2, GEOS-4, and NCEP1 reanalysis data, have been used to simulate upper tropospheric CO2 from 2000 to 2004. Model results of CO2 mixing ratios agree well with monthly mean aircraft observations at altitudes between 8 and 13 km (Matsueda et al., 2002) in the tropics. The upper tropospheric CO2 seasonal cycle phases are well captured by the CTMs. Model results have smaller seasonal cycle amplitudes in the Southern Hemisphere compared with those in the Northern Hemisphere, which are consistent with the aircraft data. Some discrepancies are evident between the model and aircraft data in the midlatitudes, where models tend to underestimate the amplitude of CO2 seasonal cycle. Comparison of the simulated vertical profiles of CO2 between the different models reveals that the convection in the 3-D models is likely too weak in boreal winter and spring. Model sensitivity studies suggest that convection mass flux is important for the correct simulation of upper tropospheric CO2.

Published

2008

48. Interannual Variability and Trends of Extratropical Ozone. Part I: Northern Hemisphere

Author

Ting Liao, J. Eric Nielsen, Steven Pawson, Run-Lie Shia, Xun Jiang, Varavut Limpasuvan, Yuk L. Yung, and Charles D. Camp

Subjects

Quasi-biennial oscillation, Atmospheric Science, Atmospheric circulation, Polar vortex, Dobson unit, Climatology, Trend surface analysis, Northern Hemisphere, Extratropical cyclone, Environmental science, Atmospheric sciences, Antarctic oscillation, Caltech Library Services

Abstract

The authors apply principal component analysis (PCA) to the extratropical total column ozone from the combined merged ozone data product and the European Centre for Medium-Range Weather Forecasts assimilated ozone from January 1979 to August 2002. The interannual variability (IAV) of extratropical O3 in the Northern Hemisphere (NH) is characterized by four main modes. Attributable to dominant dynamical effects, these four modes account for nearly 60% of the total ozone variance in the NH. The patterns of variability are distinctly different from those derived for total O3 in the tropics. To relate the derived patterns of O3 to atmospheric dynamics, similar decompositions are performed for the 30–100-hPa geopotential thickness. The results reveal intimate connections between the IAV of total ozone and the atmospheric circulation. The first two leading modes are nearly zonally symmetric and represent the connections to the annular modes and the quasi-biennial oscillation. The other two modes exhibit in-quadrature, wavenumber-1 structures that, when combined, describe the displacement of the polar vortices in response to planetary waves. In the NH, the extrema of these combined modes have preferred locations that suggest fixed topographical and land–sea thermal forcing of the involved planetary waves. Similar spatial patterns and trends in extratropical column ozone are simulated by the Goddard Earth Observation System chemistry–climate model (GEOS-CCM). The decreasing O3 trend is captured in the first mode. The largest trend occurs at the North Pole, with values ∼−1 Dobson Unit (DU) yr−1. There is almost no trend in tropical O3. The trends derived from PCA are confirmed using a completely independent method, empirical mode decomposition, for zonally averaged O3 data. The O3 trend is also captured by mode 1 in the GEOS-CCM, but the decrease is substantially larger than that in the real atmosphere.

Published

2008

49. On the information content of the thermal infrared cooling rate profile from satellite instrument measurements

Author

Kuo-Nan Liou, Run-Lie Shia, Yuk L. Yung, and Daniel Feldman

Subjects

Atmospheric Science, Gaussian, Instrumentation, Soil Science, Aquatic Science, Oceanography, Spectral line, symbols.namesake, Signal-to-noise ratio, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Earth-Surface Processes, Water Science and Technology, Remote sensing, Propagation of uncertainty, Ecology, Covariance matrix, Paleontology, Forestry, Covariance, Computational physics, Geophysics, Space and Planetary Science, symbols, Environmental science, Caltech Library Services, Water vapor

Abstract

This work investigates how remote sensing of the quantities required to calculate clear-sky cooling rate profiles propagates into cooling rate profile knowledge. The formulation of a cooling rate profile error budget is presented for clear-sky scenes given temperature, water vapor, and ozone profile uncertainty. Using linear propagation of error analysis, an expression for the cooling rate profile covariance matrix is given. Some of the features of the cooling rate covariance matrix are discussed, and it is found that nonzero error correlations in the temperature, water vapor, and ozone retrieval profiles must be considered to produce an unbiased estimate of cooling rate profile variance and the covariance structure. To that end, the exclusion of the details of this error correlation leads to an underestimation of the cooling rate profile uncertainty. This work then examines the assumptions made in the course of deriving the expression for the cooling rate covariance matrix by using ERA-40 Reanalysis data. It is established that the assumptions of linear error propagation and Gaussian statistics are generally tenable. Next, the information content of thermal infrared spectra with respect to clear-sky cooling rate profiles is investigated. Several formerly- and currently-operational spectrometers are compared with different spectral coverage, resolution, signal-to-noise ratio. Among these, IASI is found to have the ability to provide the greatest amount of information on the cooling rate profile. Also, it may be scientifically useful to develop far-infrared missions in terms of cooling rate profile analysis.

Published

2008

50. Influence of Doubled CO2 on Ozone via Changes in the Brewer–Dobson Circulation

Author

Yuk L. Yung, Xun Jiang, Dennis L. Hartmann, Scott J. Eichelberger, and Run-Lie Shia

Subjects

Atmospheric Science, chemistry.chemical_compound, Ozone, chemistry, Atmospheric circulation, Dobson unit, Climatology, Northern Hemisphere, Atmospheric model, Southern Hemisphere, Brewer-Dobson circulation, Caltech Library Services, Latitude

Abstract

In this short note, the effect of enhanced circulation due to doubling CO2 on ozone is investigated. The difference of Brewer–Dobson circulation (BDC) between the doubled CO2 and control run from an idealized atmospheric general circulation model is added to the BDC climatology derived from National Centers for Environmental Prediction—Department of Energy Reanalysis 2 (NCEP2) from 1979 to 2002. Then it is used to drive the California Institute of Technology/Jet Propulsion Laboratory (Caltech/JPL) two-dimensional chemistry and transport model. The results reveal that the total ozone increases by 7 and 3.5 Dobson units (DU) in the high latitudes of the Northern and Southern Hemispheres, respectively, and decreases by 4 DU in the Tropics as a result of the increase in BDC associated with doubled CO2. If the change of eddy mixing coefficients after doubling CO2 is also considered, the total ozone will increase by 6.5 and 3 DU in the high latitudes of the Northern and Southern Hemispheres after combining both effects from the change in BDC and eddy mixing coefficients.

Published

2007