Statistical regularization for trend detection: An integrated approach for detecting long-term trends from sparse tropospheric ozone profiles

Chang, Kai‐Lan; Cooper, O. R.; Gaudel, Audrey; Petropavlovskikh, Irina; Thouret, V.

doi:10.5194/acp-2019-959

Cited by 6 publications

(18 citation statements)

References 49 publications

(67 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The statistical framework of trend detection for ozone vertical profile data was described by Chang et al. (2020). An important consideration of trend detection for vertically distributed time series is that the trends should not be isolated to a single narrow pressure level or layer (e.g., a depth of 10 hPa); rather we expect to observe similar trends in the neighboring pressure layers as well.…”

Section: Methodsmentioning

confidence: 99%

“…Therefore, the statistical models are applied to the normalized deviations (ND), however, the seasonal mean and SD on any pressure level can always be transformed back (to the units of ppbv) from those ND. Statistical regularization for trend and anomaly detections: The methodology developed in Chang et al. (2020) can be seen as a seasonal‐trend decomposition (Cleveland et al., 1990) designed for multiple (vertically) correlated time series. The penalized regression splines (Wood, 2006) are applied to decompose the vertical profile time series data according to their seasonal patterns and interannual changes.…”

Section: Methodsmentioning

confidence: 99%

“…Statistical regularization for trend and anomaly detections: The methodology developed in Chang et al. (2020) can be seen as a seasonal‐trend decomposition (Cleveland et al., 1990) designed for multiple (vertically) correlated time series. The penalized regression splines (Wood, 2006) are applied to decompose the vertical profile time series data according to their seasonal patterns and interannual changes.…”

Section: Methodsmentioning

confidence: 99%

“…Based on ∼45,700 ozone profiles above Europe and ∼9,900 profiles above western North America, the result is a refined estimate of the regional‐scale ozone anomalies above Europe and western North America during the COVID‐19 economic downturn, and we also quantify the impact of the 2020 ozone anomalies on the long‐term trends (1994–2020). A clear advantage of this regional‐scale approach to quantifying ozone trends is that it incorporates data from multiple sources for the identification of systematic variations; in contrast, trend detection at individual sites can be a challenge due to low signal‐to‐noise ratios (Chang et al., 2020; Saunois et al., 2012).…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Impact of the COVID‐19 Economic Downturn on Tropospheric Ozone Trends: An Uncertainty Weighted Data Synthesis for Quantifying Regional Anomalies Above Western North America and Europe

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Impact of the COVID‐19 Economic Downturn on Tropospheric Ozone Trends: An Uncertainty Weighted Data Synthesis for Quantifying Regional Anomalies Above Western North America and Europe

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

“…Our predictors include the consecutive day (since 15 October; D ), the hour ( H ), longitude ( Lon ) and the local meteorological parameters of relative humidity ( RH ), temperature ( T ), wind speed ( Ws ), wind direction ( Wd ), and precipitation ( P ) (Equation 2)

E(Y)={\beta }_{0}+{f}_{1}(D)+{f}_{2}(H)+{f}_{3}(Lon)+{f}_{4}(RH)+{f}_{5}(T)+{f}_{6}(Ws)+{f}_{7}(Wd)+{f}_{8}(P)

where the response is based on 1‐min data. To avoid potential overfitting resulting from a large set of predictor variables, a roughness penalty was applied to each functional approximation (so the model will not seek to capture unstructured or noisy variation in the response and the result is more generalizable; Chang et al., 2020), and the model is fitted by the generalized cross validation (GCV) criterion (Wood, 2017).…”

Section: Methodsmentioning

confidence: 99%

A Novel Network‐Based Approach to Determining Measurement Representation Error for Model Evaluation of Aerosol Microphysical Properties

et al. 2022

Self Cite

View full text Add to dashboard Cite

Aerosols are heterogeneously distributed in the atmosphere, influencing weather and climate in numerous ways (Haywood & Boucher, 2000;Lohmann & Feichter, 2005). Decades of research have not effectively reduced the uncertainty in aerosol-cloud radiative effects, inhibiting major improvements in climate model predictions (Bellouin et al., 2020). Model intercomparison projects have demonstrated that models exhibit a wide range of simulated aerosol microphysical properties, as compared with simulated aerosol optical properties (Mann et al., 2014;Myhre et al., 2009) or trace gas constituents, which are fundamental to a model's ability to predict aerosol radiative effects and cloud-nucleating properties. The distribution of accumulation mode aerosol size and abundance have been identified as a key driver in aerosol radiative forcing, particularly in the boundary layer (BL) in the continental US, removed from the influences of marine sulfur emissions and volcanic emissions (Andrews et al., 2006;Carslaw et al., 2013).

show abstract

Regional and Seasonal Trends in Tropical Ozone From SHADOZ Profiles: Reference for Models and Satellite Products

et al. 2021

View full text Add to dashboard Cite

Understanding lowermost stratosphere (LMS) ozone variability is an important topic in the trends and climate assessment communities because of feedbacks among changing temperature, dynamics, and ozone. LMS evaluations are usually based on satellite observations. Free tropospheric (FT) ozone assessments typically rely on profiles from commercial aircraft. Ozonesonde measurements constitute an independent data set encompassing both LMS and FT. We used Southern Hemisphere Additional Ozonesondes (SHADOZ) data (5.8°N-14°S) from 1998 to 2019 in the Goddard Multiple Linear Regression model to analyze monthly mean FT and LMS ozone changes across five well-distributed tropical sites. Our findings: (a) both FT (5-15 km) and LMS (15-20 km) ozone trends show marked seasonal variability. (b) All stations exhibit FT ozone increases in February-May (up to 15%/decade) when the frequency of convectively driven waves have changed. (c) After May, monthly ozone changes are both positive and negative, leading to mean trends of +(1-4)%/decade, depending on station. (d) LMS ozone losses reach (4-9)%/decade midyear, correlating with an increase in TH as derived from SHADOZ radiosonde data. (e) When the upper FT and LMS are defined by tropopause-relative coordinates, the LMS ozone trends all become insignificant. Thus, the 20-year decline in tropical LMS ozone reported in recent satellite-based studies likely signifies a perturbed tropopause rather than chemical depletion. The SHADOZ-derived ozone changes highlight regional and seasonal variability across the tropics and define a new reference for evaluating changes derived from models and satellite products over the 1998-2019 period.Plain Language Summary Understanding free troposphere (FT) and lowermost stratosphere (LMS) ozone trends is important. If FT ozone increases, it will augment global warming. If LMS ozone has declined in the past 20 years it could mean that something is amiss in atmospheric conditions despite successes of the Montreal Protocol to eliminate ozone-depleting chemicals from the stratosphere. This study used high-accuracy, high-resolution (∼150 m) ozone profiles from balloon-borne sondes to determine changes over the tropics. The data come from five sites in the Southern Hemisphere Additional Ozonesondes (SHADOZ) archive covering 1998-2019. A summary of results: (a) both FT (5-15 km) and LMS (15-20 km) ozone trends show marked seasonal variability. (b) All stations exhibit strong positive FT ozone trends in the February-May period but annual means at several stations comparable to the IAGOS record are ≤2%/decade. (c) LMS ozone losses range from (4-9)%/decade midyear and appear to be an artifact of an increasing tropopause height. Therefore, the 20-year decline in tropical LMS ozone published in satellite-based studies may signify a perturbed tropopause, that is, a climate signal. Our SHADOZderived ozone trends are available for models, challenging them to reproduce the regional and seasonal variations we find in recent trends.THOMPSON ET AL.

show abstract

Statistical regularization for trend detection: An integrated approach for detecting long-term trends from sparse tropospheric ozone profiles

Cited by 6 publications

References 49 publications

Impact of the COVID‐19 Economic Downturn on Tropospheric Ozone Trends: An Uncertainty Weighted Data Synthesis for Quantifying Regional Anomalies Above Western North America and Europe

Impact of the COVID‐19 Economic Downturn on Tropospheric Ozone Trends: An Uncertainty Weighted Data Synthesis for Quantifying Regional Anomalies Above Western North America and Europe

A Novel Network‐Based Approach to Determining Measurement Representation Error for Model Evaluation of Aerosol Microphysical Properties

Regional and Seasonal Trends in Tropical Ozone From SHADOZ Profiles: Reference for Models and Satellite Products

Contact Info

Product

Resources

About