Your search keyword '"Butchart N"' showing total 4 results

1. The Effect of Convective Injection of Ice on Stratospheric Water Vapor in a Changing Climate

Author

Smith, JW, Bushell, AC, Butchart, N, Haynes, PH, Maycock, AC, Smith, JW [0000-0002-0079-4045], Bushell, AC [0000-0001-5683-4387], Butchart, N [0000-0002-4993-7262], Haynes, PH [0000-0002-7726-6988], Maycock, AC [0000-0002-6614-1127], and Apollo - University of Cambridge Repository

Subjects

Geophysics, stratospheric water vapor, Lagrangian trajectories, General Earth and Planetary Sciences, Astrophysics::Earth and Planetary Astrophysics, tropical tropopause, climate model, deep convection, Physics::Atmospheric and Oceanic Physics

Abstract

Stratospheric water vapor affects the Earth's radiative balance and stratospheric chemistry, yet its future changes are uncertain and not fully understood. The influence of deep convection on stratospheric water vapor remains subject to debate. This letter presents a detailed process‐based model study of the impact of convective ice sublimation on stratospheric water vapor in response to CO2 forced climate change. The influence of convective injection is found to be limited by the vertical profile of temperature and saturation vapor pressure in the tropical tropopause layer, not by the frequency of occurrence. Lagrangian trajectory analysis shows the relative contributions to stratospheric water vapor from sublimation and large‐scale transport are approximately unchanged when CO2 is increased. The results indicate the role of convective ice injection for stratospheric water vapor in a warmer climate remains constrained by large‐scale temperatures.

Published

2022

2. The impact of stratospheric resolution on the detectability of climate change signals in the free atmosphere

Author

Mitchell, D. M., primary, Stott, P. A., additional, Gray, L. J., additional, Allen, M. R., additional, Lott, F. C., additional, Butchart, N., additional, Hardiman, S. C., additional, and Osprey, S. M., additional

Published

2013

3. Coupled chemistry climate model simulations of stratospheric temperatures and their trends for the recent past

Author

Austin, J., primary, Wilson, R. J., additional, Akiyoshi, H., additional, Bekki, S., additional, Butchart, N., additional, Claud, C., additional, Fomichev, V. I., additional, Forster, P., additional, Garcia, R. R., additional, Gillett, N. P., additional, Keckhut, P., additional, Langematz, U., additional, Manzini, E., additional, Nagashima, T., additional, Randel, W. J., additional, Rozanov, E., additional, Shibata, K., additional, Shine, K. P., additional, Struthers, H., additional, Thompson, D. W. J., additional, Wu, F., additional, and Yoden, S., additional

Published

2009

4. Revisiting the mystery of recent stratospheric temperature trends.

Author

Maycock AC, Randel WJ, Steiner AK, Karpechko AY, Cristy J, Saunders R, Thompson DWJ, Zou CZ, Chrysanthou A, Abraham NL, Akiyoshi H, Archibald AT, Butchart N, Chipperfield M, Dameris M, Deushi M, Dhomse S, Di Genova G, Jöckel P, Kinnison DE, Kirner O, Ladstädter F, Michou M, Morgenstern O, Connor FO, Oman L, Pitari G, Plummer DA, Revell LE, Rozanov E, Stenke A, Visioni D, Yamashita Y, and Zeng G

Abstract

Simulated stratospheric temperatures over the period 1979-2016 in models from the Chemistry-Climate Model Initiative (CCMI) are compared with recently updated and extended satellite observations. The multi-model mean global temperature trends over 1979- 2005 are -0.88 ± 0.23, -0.70 ± 0.16, and -0.50 ± 0.12 K decade -1 for the Stratospheric Sounding Unit (SSU) channels 3 (~40-50 km), 2 (~35-45 km), and 1 (~25-35 km), respectively. These are within the uncertainty bounds of the observed temperature trends from two reprocessed satellite datasets. In the lower stratosphere, the multi-model mean trend in global temperature for the Microwave Sounding Unit channel 4 (~13-22 km) is -0.25 ± 0.12 K decade -1 over 1979-2005, consistent with estimates from three versions of this satellite record. The simulated stratospheric temperature trends in CCMI models over 1979-2005 agree with the previous generation of chemistry-climate models. The models and an extended satellite dataset of SSU with the Advanced Microwave Sounding Unit-A show weaker global stratospheric cooling over 1998-2016 compared to the period of intensive ozone depletion (1979-1997). This is due to the reduction in ozone-induced cooling from the slow-down of ozone trends and the onset of ozone recovery since the late 1990s. In summary, the results show much better consistency between simulated and satellite observed stratospheric temperature trends than was reported by Thompson et al. (2012) for the previous versions of the SSU record and chemistry-climate models. The improved agreement mainly comes from updates to the satellite records; the range of simulated trends is comparable to the previous generation of models.

Published

2018