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1. Tropical upper-tropospheric trends in ozone and carbon monoxide (2005–2020): observational and model results

   https://doi.org/10.5194/acp-25-597-2025  

   Froidevaux, Lucien; Kinnison, Douglas E; Gaubert, Benjamin; Schwartz, Michael J; Livesey, Nathaniel J; Read, William G; Bardeen, Charles G; Ziemke, Jerry R; Fuller, Ryan A (January 2025, Atmospheric Chemistry and Physics)

   Abstract. We analyze tropical ozone (O3) and carbon monoxide (CO) distributions in the upper troposphere (UT) for 2005–2020 using Aura Microwave Limb Sounder (MLS) observations and simulations from the Whole Atmosphere Community Climate Model (WACCM) and two variants of the Community Atmosphere Model with Chemistry (CAM-chem), with each variant using different anthropogenic CO emissions. Trends and variability diagnostics are obtained from multiple linear regression. The MLS zonal mean O3 UT trend for 20° S–20° N is +0.39 ± 0.28 % yr−1; the WACCM and CAM-chem simulations yield similar trends, although the WACCM result is somewhat smaller. Our analyses of gridded MLS data yield positive O3 trends (up to 1.4 % yr−1) over Indonesia and east of that region, as well as over Africa and the Atlantic. These positive mapped O3 trends are generally captured by the simulations but in a more muted way. We find broad similarities (and some differences) between mapped MLS UT O3 trends and corresponding mapped trends of tropospheric column ozone. The MLS zonal mean CO UT trend for 20° S–20° N is −0.25 ± 0.30 % yr−1, while the corresponding CAM-chem trend is 0.0 ± 0.14 % yr−1 when anthropogenic emissions are taken from the Community Emissions Data System (CEDS) version 2. The CAM-chem simulation driven by CAMS-GLOB-ANTv5 emissions yields a tropical mean CO UT trend of 0.22 ± 0.19 % yr−1, in contrast to the slightly negative MLS CO trend. Previously published analyses of total column CO data have shown negative trends. Our tropical composition trend results contribute to continuing international assessments of tropospheric evolution. 

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2. OH, HO ₂ , and RO ₂ radical chemistry in a rural forest environment: measurements, model comparisons, and evidence of a missing radical sink

   https://doi.org/10.5194/acp-23-10287-2023  

   Bottorff, Brandon; Lew, Michelle M.; Woo, Youngjun; Rickly, Pamela; Rollings, Matthew D.; Deming, Benjamin; Anderson, Daniel C.; Wood, Ezra; Alwe, Hariprasad D.; Millet, Dylan B.; et al (September 2024, Atmospheric Chemistry and Physics)

   Abstract. The hydroxyl (OH), hydroperoxy (HO2), and organic peroxy (RO2)radicals play important roles in atmospheric chemistry. In the presence ofnitrogen oxides (NOx), reactions between OH and volatile organiccompounds (VOCs) can initiate a radical propagation cycle that leads to theproduction of ozone and secondary organic aerosols. Previous measurements ofthese radicals under low-NOx conditions in forested environmentscharacterized by emissions of biogenic VOCs, including isoprene andmonoterpenes, have shown discrepancies with modeled concentrations. During the summer of 2016, OH, HO2, and RO2 radical concentrationswere measured as part of the Program for Research on Oxidants:Photochemistry, Emissions, and Transport – Atmospheric Measurements ofOxidants in Summer (PROPHET-AMOS) campaign in a midlatitude deciduousbroadleaf forest. Measurements of OH and HO2 were made by laser-inducedfluorescence–fluorescence assay by gas expansion (LIF-FAGE) techniques,and total peroxy radical (XO2) mixing ratios were measured by the Ethane CHemical AMPlifier (ECHAMP) instrument. Supporting measurements ofphotolysis frequencies, VOCs, NOx, O3, and meteorological datawere used to constrain a zero-dimensional box model utilizing either theRegional Atmospheric Chemical Mechanism (RACM2) or the Master ChemicalMechanism (MCM). Model simulations tested the influence of HOxregeneration reactions within the isoprene oxidation scheme from the LeuvenIsoprene Mechanism (LIM1). On average, the LIM1 models overestimated daytimemaximum measurements by approximately 40 % for OH, 65 % for HO2,and more than a factor of 2 for XO2. Modeled XO2 mixing ratioswere also significantly higher than measured at night. Addition of RO2 + RO2 accretion reactions for terpene-derived RO2 radicals tothe model can partially explain the discrepancy between measurements andmodeled peroxy radical concentrations at night but cannot explain thedaytime discrepancies when OH reactivity is dominated by isoprene. Themodels also overestimated measured concentrations of isoprene-derivedhydroxyhydroperoxides (ISOPOOH) by a factor of 10 during the daytime,consistent with the model overestimation of peroxy radical concentrations.Constraining the model to the measured concentration of peroxy radicalsimproves the agreement with the measured ISOPOOH concentrations, suggestingthat the measured radical concentrations are more consistent with themeasured ISOPOOH concentrations. These results suggest that the models maybe missing an important daytime radical sink and could be overestimating therate of ozone and secondary product formation in this forest. 

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3. A Comparative Study of Ionospheric Day‐To‐Day Variability Over Wuhan Based on Ionosonde Measurements and Model Simulations

   https://doi.org/10.1029/2020JA028589  

   Zhou, Xu; Yue, Xinan; Liu, Han‐Li; Lu, Xian; Wu, Haonan; Zhao, Xiukuan; He, Jianhui (March 2021, Journal of Geophysical Research: Space Physics)

   Abstract Ionospheric day‐to‐day variability is essential for understanding the space environment, while it is still challenging to properly quantify and forecast. In the present work, the day‐to‐day variability of F2 layer peak electron densities (NmF2) is examined from both observational and modeling perspectives. Ionosonde data over Wuhan station (30.5°N, 114.5°E; 19.3°N magnetic latitude) are compared with simulations from the specific dynamics Whole Atmosphere Community Climate Model with thermosphere and ionosphere eXtension (SD‐WACCM‐X) and the Thermosphere‐Ionosphere‐Electrodynamics General Circulation Model (TIEGCM) in 2009 and 2012. Both SD‐WACCM‐X and TIEGCM are driven by the realistic 3 h geomagnetic index and daily solar input, and the former includes self‐consistently solved physics and chemistry in the lower atmosphere. The correlation coefficient between observations and SD‐WACCM‐X simulations is much larger than that of the TIEGCM simulations, especially during dusk in 2009 and nighttime in 2012. Both the observed and SD‐WACCM‐X simulated day‐to‐day variability of NmF2 reveal a similar day‐night dependence in 2012 that increases large during the nighttime and decreases during the daytime, and shows favorable consistency of daytime variability in 2009. Both the observations and SD‐WACCM‐X simulations also display semiannual variations in nighttime NmF2 variability, although the month with maximum variability is slightly different. However, TIEGCM does not reproduce the day‐night dependence or the semiannual variations well. The results emphasize the necessity for realistic lower atmospheric perturbations to characterize ionospheric day‐to‐day variability. This work also provides a validation of the SD‐WACCM‐X in terms of ionospheric day‐to‐day variability. 

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4. Impact of the Polar Vortex on Sub‐Seasonal O/N ₂ Variability in the Lower Thermosphere Using GOLD and WACCM‐X

   https://doi.org/10.1029/2024JA032724  

   Martinez, Benjamin_C; Lu, Xian; Pedatella, Nicholas_M; Wu, Haonan; Oberheide, Jens (June 2024, Journal of Geophysical Research: Space Physics)

   Abstract We provide observational evidence that the stability of the stratospheric Polar vortex (PV) is a significant driver of sub‐seasonal variability in the thermosphere during geomagnetically quiet times when the PV is anomalously strong or weak. We find strong positive correlations between the Northern Annular Mode (NAM) index and subseasonal (10–90 days) Global Observations of the Limb and Disk (GOLD) O/N₂perturbations at low to mid‐northern latitudes, with a largest value of +0.55 at ∼30.0°N when anomalously strong or weak (NAM >2.5 or < −2.1) vortex times are considered. Strong agreement for O/N₂variability and O/N₂‐NAM correlations is found between GOLD observations and the Whole Atmosphere Community Climate Model with thermosphere‐ionosphere eXtension (WACCM‐X) simulations, which is then used to delineate the global distribution of O/N₂‐NAM correlations. We find negative correlations between subseasonal variability in WACCM‐X O/N₂and NAM at high northern and southern latitudes (as large as −0.54 at ∼60.0°S during anomalous vortex times). These correlations suggest that PV driven upwelling at low latitudes is accompanied by corresponding downwelling at high latitudes in the lower thermosphere (∼80–120 km), which is confirmed using calculations of residual mean meridional circulation from WACCM‐X. 

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5. Comparison of two photolytic calibration methods for nitrous acid

   https://doi.org/10.5194/amt-15-5455-2022  

   Lindsay, Andrew J.; Wood, Ezra C. (January 2022, Atmospheric Measurement Techniques)

   Abstract. Nitrous acid (HONO) plays an important role in troposphericoxidation chemistry as it is a precursor to the hydroxyl radical (OH).Measurements of HONO have been difficult historically due to instrumentinterferences and difficulties in sampling and calibration. The traditionalcalibration method involves generation of HONO by reacting hydrogen chloridevapor with sodium nitrite followed by quantification by various methods(e.g., conversion of HONO to nitric oxide (NO) followed by chemiluminescencedetection). Alternatively, HONO can be generated photolytically in thegas phase by reacting NO with OH radicals generated by H2O photolysis.In this work, we describe and compare two photolytic HONO calibrationmethods that were used to calibrate an iodide adduct chemical ionizationmass spectrometer (CIMS). Both methods are based on the water vaporphotolysis method commonly used for OH and HO2 (known collectively asHOx) calibrations. The first method is an adaptation of the common chemicalactinometry HOx calibration method, in which HONO is calculated based onquantified values for [O3], [H2O], and [O2] and the absorptioncross sections for H2O and O2 at 184.9 nm. In the second, novelmethod HONO is prepared in mostly N2 ([O2]=0.040 %) and issimply quantified by measuring the NO2 formed by the reaction of NOwith HO2 generated by H2O photolysis. Both calibration methodswere used to prepare a wide range of HONO mixing ratios between∼400 and 8000 pptv. The uncertainty of the chemicalactinometric calibration is 27 % (2σ) and independent of HONOconcentration. The uncertainty of the NO2 proxy calibration isconcentration-dependent, limited by the uncertainty of the NO2measurements. The NO2 proxy calibration uncertainties (2σ)presented here range from 4.5 % to 24.4 % (at [HONO] =8000 pptv and[HONO] =630 pptv, respectively) with a 10 % uncertainty associatedwith a mixing ratio of ∼1600 pptv, typical of valuesobserved in urban areas at night. We also describe the potential applicationof the NO2 proxy method to calibrating HOx instruments (e.g., LIF,CIMS) at uncertainties below 15 % (2σ). 

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