Lightning assimilation in the WRF model (Version 4.1.1): technique updates and assessment of the applications from regional to hemispheric scales

Kang, Daiwen; Heath, Nicholas; Gilliam, Robert C.; Spero, Tanya L.; Pleim, Jonathan

doi:10.5194/gmd-15-8561-2022

Cited by 3 publications

(1 citation statement)

References 42 publications

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“…The modeling domain contains a total of 459 × 299 × 35 (4,803,435) grid-cells. Meteorological fields were generated using the Weather Research and Forecasting (WRFv4.3.3, [ 27 ]) model with the RRTMG (Rapid Radiative Transfer Model for GCMs) for long-and short-wave radiation [ 28 ], Kain-Fritsch scheme [ 29 ] with lightning assimilation [ 30 – 31 ] for convective parameterization, Morrison microphysics scheme [ 32 ], Pleim-Xiu land surface model [ 33 – 34 ] and the Asymmetric Convective Model version 2 (ACM2; [ 35 – 36 ]) for planetary boundary layer (PBL) scheme. Four-dimensional data assimilation (FDDA) using “analysis nudging” was applied to continuously nudge wind, temperature and water vapor mixing ratio above the PBL [ 37 ] toward the NAM 12-km analysis every three hours.…”

Section: Methodsmentioning

confidence: 99%

Examining the Impact of Dimethyl Sulfide Emissions on Atmospheric Sulfate over the Continental U.S.

et al. 2023

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We examined the impact of dimethylsulfide (DMS) emissions on sulfate concentrations over the continental U.S. by using the Community Multiscale Air Quality (CMAQ) model version 5.4 and performing annual simulations without and with DMS emissions for 2018. DMS emissions enhance sulfate not only over seawater but also over land, although to a lesser extent. On an annual basis, the inclusion of DMS emissions increase sulfate concentrations by 36% over seawater and 9% over land. The largest impacts over land occur in California, Oregon, Washington, and Florida, where the annual mean sulfate concentrations increase by ~25%. The increase in sulfate causes a decrease in nitrate concentration due to limited ammonia concentration, especially over seawater, and an increase in ammonium concentration with a net effect of increased inorganic particles. The largest sulfate enhancement occurs near the surface (over seawater), and the enhancement decreases with altitude, diminishing to 10–20% at an altitude of ~5 km. Seasonally, the largest enhancement in sulfate over seawater occurs in summer, and the lowest in winter. In contrast, the largest enhancements over land occur in spring and fall due to higher wind speeds that can transport more sulfate from seawater into land.

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Section: Methodsmentioning

confidence: 99%

Examining the Impact of Dimethyl Sulfide Emissions on Atmospheric Sulfate over the Continental U.S.

et al. 2023

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Utility of Geostationary Lightning Mapper-derived lightning NO emission estimates in air quality modeling studies

Cheng,

Pour-Biazar,

et al. 2024

Atmos. Chem. Phys.

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Abstract. Lightning is one of the primary natural sources of nitric oxide (NO), and the influence of lightning-induced NO (LNO) emission on air quality has been investigated in the past few decades. In the current study an LNO emissions model, which derives LNO emission estimates from satellite-observed lightning optical energy, is introduced. The estimated LNO emission is employed in an air quality modeling system to investigate the potential influence of LNO on tropospheric ozone. Results show that lightning produced 0.174 Tg N of nitrogen oxides (NOx = NO + NO2) over the contiguous US (CONUS) domain between June and September 2019, which accounts for 11.4 % of the total NOx emission. In August 2019, LNO emission increased ozone concentration within the troposphere by an average of 1 %–2 % (or 0.3–1.5 ppbv), depending on the altitude; the enhancement is maximum at ∼ 4 km above ground level and minimum near the surface. The southeastern US has the most significant ground-level ozone increase, with up to 1 ppbv (or 2 % of the mean observed value) difference for the maximum daily 8 h average (MDA8) ozone. These numbers are near the lower bound of the uncertainty range given in previous studies. The decreasing trend in anthropogenic NOx emissions over the past 2 decades increases the relative contribution of LNO emissions to total NOx emissions, suggesting that the LNO production rate used in this study may need to be increased. Corrections for the sensor flash detection efficiency may also be helpful. Moreover, the episodic impact of LNO on tropospheric ozone can be considerable. Performing backward trajectory analyses revealed two main reasons for significant ozone increases: long-distance chemical transport and lightning activity in the upwind direction shortly before the event.

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Features of Thunderstorm Activity in the Nizhny Novgorod Region: Observations and Analysis

Шаталина,

Сарафанов,

Шлюгаев

2024

XXX Юбилейный Международный Симпозиум Оптика Атмосферы И Океана. Физика Атмосферы

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В докладе представлены результаты наблюдений многопунктовой грозопеленгационной системы (ГПС) NNLDN (Nizhny Novgorod Lightning Detection Network), разработанной в ИПФ РАН и регистрирующей электромагнитное излучение молний ближних и дальних гроз в диапазоне 10-100 кГц. Сопоставлены результаты наблюдений молниевой активности системой NNLDN с региональным покрытием (100-300 км) и глобальной системой WWLLN. Представлено качественное совпадение карт грозоопасности за 2022 год. Изучена многолетняя статистика гроз в исследуемом регионе за 2015-2023 гг., а также отдельные наиболее интенсивные события. Выявлены основные региональные особенности грозовой активности в пределах Нижегородской области. The report presents the results of observations from a multi-point lightning direction finding system (LDFS) NNLDN (Nizhny Novgorod Lightning Detection Network), developed at IAP RAS and recording electromagnetic radiation from near and distant thunderstorms in the frequency range of 10-100 kHz. The results of lightning activity observations by the NNLDN system with regional coverage (100-300 km) are compared with the global WWLLN system. A qualitative match of thunderstorm risk maps for 2022 is presented. Multi-year statistics of thunderstorms in the studied region for the years 2015-2023 have been analyzed, as well as specific most intense events. The main regional features of thunderstorm activity within the Nizhny Novgorod region have been identified.

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Lightning assimilation in the WRF model (Version 4.1.1): technique updates and assessment of the applications from regional to hemispheric scales

Cited by 3 publications

References 42 publications

Examining the Impact of Dimethyl Sulfide Emissions on Atmospheric Sulfate over the Continental U.S.

Examining the Impact of Dimethyl Sulfide Emissions on Atmospheric Sulfate over the Continental U.S.

Utility of Geostationary Lightning Mapper-derived lightning NO emission estimates in air quality modeling studies

Features of Thunderstorm Activity in the Nizhny Novgorod Region: Observations and Analysis

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