ENSO response to high-latitude volcanic eruptions in the Northern Hemisphere: The role of the initial conditions

Francesco S. R. Pausata; Christina Karamperidou; Rodrigo Caballero; David S. Battisti

doi:10.1002/2016gl069575

Intra-interglacial climate variability: model simulations of Marine Isotope Stages 1, 5, 11, 13, and 15

Climate of the Past ◽

10.5194/cp-12-677-2016 ◽

2016 ◽

Vol 12 (3) ◽

pp. 677-695 ◽

Cited By ~ 11

Author(s):

Rima Rachmayani ◽

Matthias Prange ◽

Michael Schulz

Keyword(s):

Climate Variability ◽

Surface Temperature ◽

Northern Hemisphere ◽

High Latitude ◽

West African ◽

Boreal Summer ◽

The West ◽

Temperature Anomalies ◽

Astronomical Forcing

Abstract. Using the Community Climate System Model version 3 (CCSM3) including a dynamic global vegetation model, a set of 13 time slice experiments was carried out to study global climate variability between and within the Quaternary interglacials of Marine Isotope Stages (MISs) 1, 5, 11, 13, and 15. The selection of interglacial time slices was based on different aspects of inter- and intra-interglacial variability and associated astronomical forcing. The different effects of obliquity, precession, and greenhouse gas (GHG) forcing on global surface temperature and precipitation fields are illuminated. In most regions seasonal surface temperature anomalies can largely be explained by local insolation anomalies induced by the astronomical forcing. Climate feedbacks, however, may modify the surface temperature response in specific regions, most pronounced in the monsoon domains and the polar oceans. GHG forcing may also play an important role for seasonal temperature anomalies, especially at high latitudes and early Brunhes interglacials (MIS 13 and 15) when GHG concentrations were much lower than during the later interglacials. High- versus low-obliquity climates are generally characterized by strong warming over the Northern Hemisphere extratropics and slight cooling in the tropics during boreal summer. During boreal winter, a moderate cooling over large portions of the Northern Hemisphere continents and a strong warming at high southern latitudes is found. Beside the well-known role of precession, a significant role of obliquity in forcing the West African monsoon is identified. Other regional monsoon systems are less sensitive or not sensitive at all to obliquity variations during interglacials. Moreover, based on two specific time slices (394 and 615 ka), it is explicitly shown that the West African and Indian monsoon systems do not always vary in concert, challenging the concept of a global monsoon system on astronomical timescales. High obliquity can also explain relatively warm Northern Hemisphere high-latitude summer temperatures despite maximum precession around 495 ka (MIS 13). It is hypothesized that this obliquity-induced high-latitude warming may have prevented a glacial inception at that time.

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High-latitude volcanic eruptions in the Norwegian Earth System Model: the effect of different initial conditions and of the ensemble size

Tellus B ◽

10.3402/tellusb.v67.26728 ◽

2015 ◽

Vol 67 (1) ◽

pp. 26728 ◽

Cited By ~ 26

Author(s):

Francesco S. R. Pausata ◽

Alf Grini ◽

Rodrigo Caballero ◽

Abdel Hannachi ◽

Øyvind Seland

Keyword(s):

High Latitude ◽

Initial Conditions ◽

Volcanic Eruptions ◽

Earth System Model ◽

System Model ◽

Earth System ◽

Ensemble Size

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Surface climate responses to explosive volcanic eruptions seen in long European temperature records and mid-to-high latitude tree-ring density around the Northern Hemisphere

Volcanism and the Earth's Atmosphere - Geophysical Monograph Series ◽

10.1029/139gm15 ◽

2003 ◽

pp. 239-254 ◽

Cited By ~ 22

Author(s):

P. D. Jones ◽

A. Moberg ◽

T. J. Osborn ◽

K. R. Briffa

Keyword(s):

Northern Hemisphere ◽

Tree Ring ◽

High Latitude ◽

Volcanic Eruptions ◽

Ring Density ◽

Surface Climate ◽

Explosive Volcanic Eruptions ◽

Temperature Records ◽

Climate Responses

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Climate effects of high-latitude volcanic eruptions: Role of the time of year

Journal of Geophysical Research Atmospheres ◽

10.1029/2010jd014448 ◽

2011 ◽

Vol 116 (D1) ◽

Cited By ~ 58

Author(s):

Ben Kravitz ◽

Alan Robock

Keyword(s):

High Latitude ◽

Volcanic Eruptions ◽

Climate Effects ◽

Time Of Year

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The Role of the Mean State in Meridional Mode Structure and Growth

Journal of Climate ◽

10.1175/jcli-d-15-0542.1 ◽

2016 ◽

Vol 29 (10) ◽

pp. 3907-3921 ◽

Cited By ~ 7

Author(s):

Cristian Martinez-Villalobos ◽

Daniel J. Vimont

Keyword(s):

Northern Hemisphere ◽

Initial Conditions ◽

Coupled Model ◽

Optimal Growth ◽

Optimal Structure ◽

Boreal Spring ◽

Optimal Structures ◽

Meridional Mode ◽

Symmetric Structures

Abstract This study uses a simple linear coupled model to investigate the role of the WES feedback and ITCZ mean states in meridional mode variability. Optimal structures that maximize transient growth are calculated for mean states characteristic of boreal spring and boreal fall in the tropical Atlantic. During boreal spring the leading optimal structure is a zonal mode that propagates westward and does not resemble the observed meridional mode. In contrast, the leading optimal structure during fall is a sea surface temperature (SST) monopole over the Northern Hemisphere (NH) that propagates equatorward and westward and that closely matches meridional mode variability during this season. It is found that the boreal fall optimal growth greatly exceeds growth of the corresponding optimal during boreal spring, despite the observed boreal spring peak in Atlantic meridional mode variance. Sensitivity studies are used to explore the role of Northern or Southern Hemisphere initial conditions, ITCZ width, and ITCZ location in meridional mode growth and structure. It is found that growth is favored (i) for optimal structures that originate in the Northern Hemisphere, especially for boreal fall mean states; (ii) for symmetric mean states, equatorially symmetric structures maximize growth under narrow ITCZ configurations, and antisymmetric structures maximize growth under wider ITCZ configurations; and (iii) for antisymmetric mean states (and realistic ITCZ width), growth is maximized when the ITCZ is located off of the equator. The implications of these findings are discussed.

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Alpha-Effect, Current and Kinetic Helicities for Magnetically Driven Turbulence, and Solar Dynamo

International Astronomical Union Colloquium ◽

10.1017/s0252921100064885 ◽

2000 ◽

Vol 179 ◽

pp. 387-388

Author(s):

Gaetano Belvedere ◽

V. V. Pipin ◽

G. Rüdiger

Keyword(s):

Southern Hemisphere ◽

Northern Hemisphere ◽

Convection Zone ◽

Solar Surface ◽

Momentum Transport ◽

Angular Momentum Transport ◽

Magnetic Buoyancy ◽

Alpha Effect ◽

Current Helicity

Extended AbstractRecent numerical simulations lead to the result that turbulence is much more magnetically driven than believed. In particular the role ofmagnetic buoyancyappears quite important for the generation ofα-effect and angular momentum transport (Brandenburg & Schmitt 1998). We present results obtained for a turbulence field driven by a (given) Lorentz force in a non-stratified but rotating convection zone. The main result confirms the numerical findings of Brandenburg & Schmitt that in the northern hemisphere theα-effect and the kinetic helicityℋkin= 〈u′ · rotu′〉 are positive (and negative in the northern hemisphere), this being just opposite to what occurs for the current helicityℋcurr= 〈j′ ·B′〉, which is negative in the northern hemisphere (and positive in the southern hemisphere). There has been an increasing number of papers presenting observations of current helicity at the solar surface, all showing that it isnegativein the northern hemisphere and positive in the southern hemisphere (see Rüdigeret al. 2000, also for a review).

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Soil Chemical Pollution and Aggressive Pathologies

Revista de Chimie ◽

10.37358/rc.18.8.6515 ◽

2018 ◽

Vol 69 (8) ◽

pp. 2278-2282

Author(s):

Stelian Ioan Morariu ◽

Letitia Doina Duceac ◽

Alina Costina Luca ◽

Florina Popescu ◽

Liliana Pavel ◽

...

Keyword(s):

Health Care Professionals ◽

Scientific Progress ◽

Volcanic Eruptions ◽

Chemical Pollution ◽

Optimal Parameters ◽

Chemical Pollutants ◽

Wide Range ◽

Health Physician ◽

Solid Liquid

Maintaining the soil in optimal parameters is vital for mankind, given its essential role in providing the alimentary base, as well as its extremely slow formation and regeneration (hundreds or thousands of years). The direct and indirect pollution of the soil and especially its chemical pollution represent a corollary of other types of pollution, given that it is produced by solid, liquid and gaseous residues. It may be involved in a wide range of diseases (respiratory, cardiovascular, digestive, renal, haematological, osteoarticular, neurological) of allergic, infectious, degenerative or neoplastic nature, from infancy to the old age. Although there are natural causes of soil pollution (e.g. volcanic eruptions), most pollutants come from human activities, which are the most incriminated in its pollution, degradation and erosion at an accelerated pace. The growing concern of all nations for the adoption of measures to limit the chemical pollution of the soil is partially found so far in viable and effective solutions intended to combat soil contamination and degradation and ensure its restoration. Chemical industrialization leads to technical and scientific progress, but at the same time it can develop related pathologies, which means that the role of the occupational health physician is essential in ensuring prophylaxis and the early detection of occupational diseases. Besides that, the role of the pediatrician is equally precious for the detection of specific diseases caused by chemical pollutants to children, because they will develop into adults with pathological stigma.The chemical pollution of the soil is a major challenge for ecologists, given that it is an important risk factor for many types of afflictions. It requires maximum attention from civil society, health care professionals and government institutions. The specialist in occupational medicine, as well as the pediatrician bear an essential responsibility in both, prevention and treatment.

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Linking gas and particle ejection dynamics to boundary conditions in scaled shock-tube experiments

Bulletin of Volcanology ◽

10.1007/s00445-021-01473-0 ◽

2021 ◽

Vol 83 (8) ◽

Author(s):

Valeria Cigala ◽

Ulrich Kueppers ◽

Juan José Peña Fernández ◽

Donald B. Dingwell

Keyword(s):

Particle Size ◽

Shock Tube ◽

Initial Conditions ◽

Volcanic Eruptions ◽

Tube Length ◽

Experimental Investigations ◽

Clear Correlation ◽

Angular Deviation ◽

Dynamic Nature ◽

Experimental Conditions

AbstractPredicting the onset, style and duration of explosive volcanic eruptions remains a great challenge. While the fundamental underlying processes are thought to be known, a clear correlation between eruptive features observable above Earth’s surface and conditions and properties in the immediate subsurface is far from complete. Furthermore, the highly dynamic nature and inaccessibility of explosive events means that progress in the field investigation of such events remains slow. Scaled experimental investigations represent an opportunity to study individual volcanic processes separately and, despite their highly dynamic nature, to quantify them systematically. Here, impulsively generated vertical gas-particle jets were generated using rapid decompression shock-tube experiments. The angular deviation from the vertical, defined as the “spreading angle”, has been quantified for gas and particles on both sides of the jets at different time steps using high-speed video analysis. The experimental variables investigated are 1) vent geometry, 2) tube length, 3) particle load, 4) particle size, and 5) temperature. Immediately prior to the first above-vent observations, gas expansion accommodates the initial gas overpressure. All experimental jets inevitably start with a particle-free gas phase (gas-only), which is typically clearly visible due to expansion-induced cooling and condensation. We record that the gas spreading angle is directly influenced by 1) vent geometry and 2) the duration of the initial gas-only phase. After some delay, whose length depends on the experimental conditions, the jet incorporates particles becoming a gas-particle jet. Below we quantify how our experimental conditions affect the temporal evolution of these two phases (gas-only and gas-particle) of each jet. As expected, the gas spreading angle is always at least as large as the particle spreading angle. The latter is positively correlated with particle load and negatively correlated with particle size. Such empirical experimentally derived relationships between the observable features of the gas-particle jets and known initial conditions can serve as input for the parameterisation of equivalent observations at active volcanoes, alleviating the circumstances where an a priori knowledge of magma textures and ascent rate, temperature and gas overpressure and/or the geometry of the shallow plumbing system is typically chronically lacking. The generation of experimental parameterisations raises the possibility that detailed field investigations on gas-particle jets at frequently erupting volcanoes might be used for elucidating subsurface parameters and their temporal variability, with all the implications that may have for better defining hazard assessment.

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