20th-Century doubling in dust archived in an Antarctic Peninsula ice core parallels climate change and desertification in South America

McConnell, Joseph R.; Aristarain, Alberto J.; Banta, J. Ryan; Edwards, Ross; Simões, Jefferson Cárdia

doi:10.1073/pnas.0607657104

Cited by 237 publications

(208 citation statements)

References 44 publications

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“…Eruptions of this magnitude are potentially recorded in Argentine shelf sediments, and are periodic contributors to the Antarctic and Southern Ocean dust budget [McConnell et al, 2007]. Comparison with Patagonian dust (Figure 6), for which Andean volcanic ash of the more common andesitic composition forms an important component [Gaiero et al, 2007], shows that rarer rhyolitic ash, such as that from Chaitén, is a minor dust component.…”

Section: Ash Chemistry and Potential Impactsmentioning

confidence: 99%

Fallout and distribution of volcanic ash over Argentina following the May 2008 explosive eruption of Chaitén, Chile

et al. 2009

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[1] The major explosive eruption of Chaitén volcano, Chile, in May 2008 provided a rare opportunity to track the long-range dispersal and deposition of fine volcanic ash. The eruption followed $10,000 years of quiescence, was the largest explosive eruption globally since Hudson, Chile, in 1991, and was the first explosive rhyolitic eruption since Novarupta, Alaska, in 1912. Field examination of distal ashfall indicates that $1.6 Â 10 11 kg of ash (dense rock equivalent volume of $0.07 km 3 ) was deposited over $2 Â 10 5 km 2 of Argentina during the first week of eruption. The minimum eruption magnitude, estimated from the mass of the tephra deposit, is 4.2. Several discrete ashfall units are identifiable from their distribution and grain size characteristics, with more energetic phases showing a bimodal size distribution and evidence of cloud aggregation processes. Ash chemistry was uniform throughout the early stages of eruption and is consistent with magma storage prior to eruption at depths of 3-6 km. Deposition of ash over a continental region allowed the tracking of eruption development and demonstrates the potential complexity of tephra dispersal from a single eruption, which in this case comprised several phases over a week-long period of intense activity.

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Section: Ash Chemistry and Potential Impactsmentioning

confidence: 99%

Fallout and distribution of volcanic ash over Argentina following the May 2008 explosive eruption of Chaitén, Chile

et al. 2009

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“…While this process has occurred historically, the increasing area of arid lands and the utilization of these lands by expanding human populations have increased dust loads (4)(5)(6). For example, during settlement of the western U.S., the intensification of human activities such as agriculture, grazing, and resource exploration in semiarid landscapes led to 500% greater dust deposition in the adjacent mountains (7).…”

mentioning

confidence: 99%

Biological consequences of earlier snowmelt from desert dust deposition in alpine landscapes

Steltzer

Landry

Painter

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Dust deposition to mountain snow cover, which has increased since the late 19 th century, accelerates the rate of snowmelt by increasing the solar radiation absorbed by the snowpack. Snowmelt occurs earlier, but is decoupled from seasonal warming. Climate warming advances the timing of snowmelt and early season phenological events (e.g., the onset of greening and flowering); however, earlier snowmelt without warmer temperatures may have a different effect on phenology. Here, we report the results of a set of snowmelt manipulations in which radiationabsorbing fabric and the addition and removal of dust from the surface of the snowpack advanced or delayed snowmelt in the alpine tundra. These changes in the timing of snowmelt were superimposed on a system where the timing of snowmelt varies with topography and has been affected by increased dust loading. At the community level, phenology exhibited a threshold response to the timing of snowmelt. Greening and flowering were delayed before seasonal warming, after which there was a linear relationship between the date of snowmelt and the timing of phenological events. Consequently, the effects of earlier snowmelt on phenology differed in relation to topography, which resulted in increasing synchronicity in phenology across the alpine landscape with increasingly earlier snowmelt. The consequences of earlier snowmelt from increased dust deposition differ from climate warming and include delayed phenology, leading to synchronized growth and flowering across the landscape and the opportunity for altered species interactions, landscape-scale gene flow via pollination, and nutrient cycling.climate warming ͉ phenology ͉ plant life history ͉ synchronization ͉ threshold T he transfer of dust from arid and semiarid lands to snowcovered landscapes takes place around the world (1-3). While this process has occurred historically, the increasing area of arid lands and the utilization of these lands by expanding human populations have increased dust loads (4-6). For example, during settlement of the western U.S., the intensification of human activities such as agriculture, grazing, and resource exploration in semiarid landscapes led to 500% greater dust deposition in the adjacent mountains (7). Furthermore, dust deposition in many regions could increase as a result of the increasing extent of arid lands and greater human activity in these areas (8). Dust deposited in winter and spring decreases the albedo of the snow surface at the time it is deposited and again, when the buried dust layers reemerge during spring snowmelt. Through this change in surface energy exchange, dust can advance the timing of snowmelt by more than a month (9).Seasonal snow cover has a substantial effect on ecosystem function where freezing temperatures over winter facilitate the formation and retention of a snowpack (10-12). It protects and sustains plant and soil communities by moderating temperatures during winter and later by supplying a source of water to fuel plant growth at the start of the growing seas...

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“…A separate study of dust concentrations from a northern Antarctic Peninsula ice core (McConnell et al, 2007) suggests dust concentrations starting to rise around 1900, coincident with Patagonian warming. However, this increase occurs ∼60 years before any such rise in the NAMI proxy.…”

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confidence: 99%

An ice‐core proxy for northerly air mass incursions into West Antarctica

Dixon

Mayewski

Goodwin

et al. 2011

Intl Journal of Climatology

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ABSTRACT:A 200-year proxy for northerly air mass incursions (NAMI) into central and western West Antarctica is developed from the examination of 19 shallow (21-150 m deep) Antarctic ice-core non-sea-salt (nss) Ca 2+ concentration records. The NAMI proxy reveals a significant rise in recent decades. This rise is unprecedented for at least the past 200 years and is coincident with anthropogenically driven changes in other large-scale Southern Hemisphere (SH) environmental phenomena such as greenhouse gas (GHG) induced warming, ozone depletion, and the associated intensification of the SH westerlies. The Hysplit trajectory model is used to examine air mass transport pathways into West Antarctica. Empirical orthogonal function analysis, in combination with trajectory results, suggests that atmospheric circulation is the dominant factor affecting nssCa 2+ concentrations throughout central and western West Antarctica. Ozone recovery will likely weaken the spring-summer SH westerlies in the future. Consequently, Antarctica could lose one of its best defences against SH GHG warming.

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20th-Century doubling in dust archived in an Antarctic Peninsula ice core parallels climate change and desertification in South America

Cited by 237 publications

References 44 publications

Fallout and distribution of volcanic ash over Argentina following the May 2008 explosive eruption of Chaitén, Chile

Fallout and distribution of volcanic ash over Argentina following the May 2008 explosive eruption of Chaitén, Chile

Biological consequences of earlier snowmelt from desert dust deposition in alpine landscapes

An ice‐core proxy for northerly air mass incursions into West Antarctica

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