Greenhouse gas effects on the solar cycle response of water vapour and noctilucent clouds

Vellalassery, Ashique; Baumgarten, Gerd; Grygalashvyly, M.; Lübken, Franz‐Josef

doi:10.5194/angeo-2023-3

Cited by 2 publications

(2 citation statements)

References 31 publications

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“…We realize that temperature changes are considered to be more important for NLC in other models, which, however, do not include microphysical processes (see, e.g., Hervig et al., 2015). In previous studies we have presented various comparisons of results from LIMA and MIMAS with ground based and satellite borne observations and found excellent agreement (see, e.g., Lübken et al., 2021; Vellalassery et al., 2023; Schmidt et al., 2018, and references therein). In Figure 1 we show the temporal behavior of methane concentration in the troposphere used in MIMAS.…”

Section: Modelmentioning

confidence: 60%

Absorption of Solar Radiation by Noctilucent Clouds in a Changing Climate

Lübken,

Baumgarten,

Grygalashvyly

et al. 2024

Geophysical Research Letters

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The expected increase in climate change related methane emissions will result in an increase in middle atmospheric water vapor abundance. This will in turn amplify the brightness of noctilucent clouds (NLC). To examine how NLC will impact the absorption of solar radiation, we utilized both an atmospheric background model and a microphysical model spanning the period from 1950 to 2100. At a latitude of 69 ± 3°N, UV absorption at λ = 126 nm is projected to rise from ∼3% to ∼7%. In specific regions, the absorption may spike to approximately 30% by the year 2100. In the visible spectrum, we observe an absorption increase from 0.0030% in 1950 to 0.020% by 2100. Local absorption reach up to 0.35% by the year 2100. These trends are similar at 79 ± 3°N, but are smaller at 58 ± 3°N. Future average absorptions are comparable to solar cycle fluctuations, but local increases are significantly more pronounced. The ice mass contained in NLC is projected to surge from 677 to 1871 tons between 1950 and 2100.

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Section: Modelmentioning

confidence: 60%

Absorption of Solar Radiation by Noctilucent Clouds in a Changing Climate

Lübken,

Baumgarten,

Grygalashvyly

et al. 2024

Geophysical Research Letters

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“…The first one shows a significant (≥ 95%) anti-correlation between the westward peak and Lyman-α during the time length of 1990 to 2004, while the latter is not significant. Recently, Vellalassery et al (2023) showed how the missing solar cycle is correlated with the increase in H 2 O in the mesosphere at polar latitudes and the attenuation of Lyman-α as a consequence.…”

Section: Solar Cycle Dependencementioning

confidence: 99%

Long-term studies of the summer wind in the mesosphere and lower thermosphere at middle and high latitudes

Jaen

Renkwitz

Liu

et al. 2023

Preprint

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Abstract. Continuous wind measurements using partial reflection radars and specular meteor radars have been carried out for nearly two decades (2004–2022) at middle and high latitudes over Germany (∼54° N) and northern Norway (∼69° N), respectively. They provide crucial data for understanding the long-term behavior of winds in the mesosphere and lower thermosphere. Our investigation mainly focuses on the summer season, characterized by the absence of intense planetary wave activity and relatively stable stratospheric conditions. This work presents the long-term behavior, variability and trends of the maximum velocity of the summer eastward, westward and southward winds. In addition, the geomagnetic influence on the summer zonal and meridional wind is explored at middle and high latitudes. The results show that a westward summer maximum is located around 75 km with velocities of 35–54 m/s, while the eastward wind maximum is observed at ∼97 km with amplitudes of 25–40 m/s. A weaker southward wind peak is found around 86 km ranging from 9–16 m/s. The findings indicate significant trends at middle latitudes in the westward summer maxima with increasing winds over the past decades, while the southward winds show a decreasing trend. On the other hand, only the eastward wind in July has a decreasing trend at high latitudes. Evidence of oscillations around 2–3, 4 and 6 years modulate the maximum velocity of the summer winds. Particularly a periodicity between 10.2–11.3 years found in the westward component is more significant at middle latitudes than at high latitudes, possibly due to solar radiation. Furthermore, stronger geomagnetic activity at high latitudes causes an increase in eastward wind velocity, whereas the opposite effect is observed in zonal jets at middle latitudes. The meridional component appears disturbed during high geomagnetic activity, with a notable decrease in the northward wind strength below approximately 80~km at both latitudes.

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Greenhouse gas effects on the solar cycle response of water vapour and noctilucent clouds

Cited by 2 publications

References 31 publications

Absorption of Solar Radiation by Noctilucent Clouds in a Changing Climate

Absorption of Solar Radiation by Noctilucent Clouds in a Changing Climate

Long-term studies of the summer wind in the mesosphere and lower thermosphere at middle and high latitudes

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