Causes and consequences of variation in snow incidence on the high mountains of Tasmania, 1983–2013

Kirkpatrick, J. B.; Núñez, M.; Bridle, K; Parry, Jared; Gibson, Neil

doi:10.1071/bt16179

Cited by 17 publications

(12 citation statements)

References 34 publications

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“…Large‐scale and multiple instances of dieback of the long‐lived T. arbuscula shrubs occurred in south‐east Tasmania between the 1970s and the 2000s, and were linked to increased aridity in the upper marsh, waterlogging in the low marsh, and erosion of marsh edges (Prahalad, Kirkpatrick, & Mount, ). This dieback event is imperceptible given the predicted direction of climate change in coarse annual metrics, but it is consistent with the increasing records of severe stochastic droughts in summer and strengthening winds (Kirkpatrick, Nunez, Bridle, Parry, & Gibson, ). Another factor that could lead to shifts in vegetation in a changing climate is dispersal.…”

Section: Discussionsupporting

confidence: 77%

Saltmarsh conservation through inventory, biogeographic analysis and predictions of change: Case of Tasmania, south‐eastern Australia

Prahalad

Kirkpatrick

2019

Aquatic Conservation

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1. Effective conservation of saltmarshes involves detailed and accurate mapping of their range, area of occupancy and plant community composition as part of region-wide inventories. There is also a need to identify the major mesoscale influences on the distributions of types of saltmarsh, obligate saltmarsh plants and salt pans, and evaluate possible responses to macroclimatic changes.2. Tidal saltmarshes of Tasmania and its offshore islands (coastline of 4,882 km, spanning latitudes 39°40′ to 43°40′S), off south-eastern Australia, were mapped at a high spatial resolution of 1 : 500-1 : 3,000. The distributions of types of saltmarsh, obligate plant taxa and salt pans were related to climatic, geomorphic and land-use variation. The future distribution of climatically controlled species and communities was determined for two climate change scenarios.3. There was 58.6 km 2 of tidal saltmarsh in Tasmania in 61 mesoscale complexes. The complexes were classified into three broad saltmarsh groups, which together offer a more ecologically relevant planning unit for saltmarsh conservation than macroscale bioregions. The small median patch size of 0.2 ha demonstrates the effectiveness of the manual interpretation and mapping with extensive field checking.Mapping of these smaller saltmarshes provides them recognition within the land use planning and approvals process. 4. Climatic, but not geomorphic and land-use, factors have strong effects on the distribution of saltmarsh plant communities, species and salt pans in Tasmania.Mean annual rainfall was most significant in predicting saltmarsh extent, range, plant community composition, salt pans and the three saltmarsh groups. Mean annual daily minimum temperature and saltmarsh area best predicted obligate plant distributions. 5. Projected wetter and drier climatic change by 2100 is not expected to substantially alter macroscale plant community patterns but may reduce the range of the rare herb Wilsonia humilis R.Br. However, stochastic disturbances may continue to play an important role at local scales.

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Section: Discussionsupporting

confidence: 77%

Saltmarsh conservation through inventory, biogeographic analysis and predictions of change: Case of Tasmania, south‐eastern Australia

Prahalad

Kirkpatrick

2019

Aquatic Conservation

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“…Nevertheless, increases in evaporation and atmospheric humidity, as well as reductions in snow amount and snowpack period, are corresponding consequences of climate warming (Jiménez Cisneros et al ., ). Although the spatial patterns of snow are determined by topography and the prevailing wind direction, the temporal patterns of snowmelt are directly linked to temperature change (Friedel, ; Kirkpatrick et al ., ), and snow cover duration in the Alps showed a declining trend during the last decades (Gottfried et al ., ; Cramer et al ., ). Future scenarios predict a continued shift from snow to rain in mountainous regions, which alone could lead to a significant decrease in snow cover duration in central Europe (Steger et al ., ; Jiménez Cisneros et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Climate change leads to accelerated transformation of high‐elevation vegetation in the central Alps

et al. 2018

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Summary High mountain ecosystems and their biota are governed by low‐temperature conditions and thus can be used as indicators for climate warming impacts on natural ecosystems, provided that long‐term data exist.We used data from the largest alpine to nival permanent plot site in the Alps, established in the frame of the Global Observation Research Initiative in Alpine Environments (GLORIA) on Schrankogel in the Tyrolean Alps, Austria, in 1994, and resurveyed in 2004 and 2014.Vascular plant species richness per plot increased over the entire period, albeit to a lesser extent in the second decade, because disappearance events increased markedly in the latter period. Although presence/absence data could only marginally explain range shift dynamics, changes in species cover and plant community composition indicate an accelerating transformation towards a more warmth‐demanding and more drought‐adapted vegetation, which is strongest at the lowest, least rugged subsite.Divergent responses of vertical distribution groups of species suggest that direct warming effects, rather than competitive displacement, are the primary causes of the observed patterns. The continued decrease in cryophilic species could imply that trailing edge dynamics proceed more rapidly than successful colonisation, which would favour a period of accelerated species declines.

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“…There is some evidence that climate forcings (like SAM) have been significantly strengthening winds and waves along Tasmania's west coast since the 1970s (see Hemer 2010a and 2010b; Kirkpatrick et al 2017;Marshall et al 2018;Sharples et al 2020). If climate driven increases in wind speed result in changes to the N and NW wind patterns, then this may have implications for DWR frequency in the Harbour.…”

Section: Changes In Wind Direction)mentioning

confidence: 99%

The influence of mesoscale climate drivers on hypoxia in a fjord-like deep coastal inlet and its potential implications regarding climate change and greenhouse gas production: examining a decade of water quality data

Maxey

Hartstein

Mujahid

et al. 2022

Preprint

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Abstract. Deep coastal inlets are sites of high sedimentation and organic carbon deposition that account for 11 % of the world's organic carbon burial. Australasia's mid to high latitude regions have many such systems. It is important to understand the role of climate forcings in influencing hypoxia and organic matter cycling in these systems, but many such systems, especially in Australasia, remain poorly described. We analysed a decade of in-situ water quality data from Macquarie Harbour, Tasmania, a deep coastal inlet with more than 180,000 tons of organic carbon loading per annum. Monthly dissolved oxygen, total Kjeldhal nitrogen, dissolved organic carbon, and dissolved inorganic nitrogen concentrations were significantly affected by rainfall patterns. Increased rainfall was correlated to higher organic carbon and nitrogen loading, lower oxygen concentrations in deep basins, and greater oxygen concentrations in surface waters. Most notably, the Southern Annular Mode (SAM) significantly influenced oxygen distribution in the system. High river flow (associated with low SAM index values) impedes deep water renewal as the primary mechanism driving basin water hypoxia. Climate forecasting predicted increased winter rainfall and decreased summer rainfall, which may further exacerbate hypoxia in this system. Currently, the Harbour basins experience frequent (up to 36 % of the time) and prolonged (up to 2 years) oxygen-poor conditions with the potential to promote greenhouse gas (CH4, N2O) production. Increased greenhouse gas production will alter the processing of organic matter entering the system. The increased winter rainfall predicted for the area will potentially increase greenhouse gas emissions due to increased spread and duration of hypoxia in the basins. Further understanding of these systems and how they respond to climate change will improve our estimates of future organic matter cycling (burial vs export) and greenhouse gas production.

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Causes and consequences of variation in snow incidence on the high mountains of Tasmania, 1983–2013

Cited by 17 publications

References 34 publications

Saltmarsh conservation through inventory, biogeographic analysis and predictions of change: Case of Tasmania, south‐eastern Australia

Saltmarsh conservation through inventory, biogeographic analysis and predictions of change: Case of Tasmania, south‐eastern Australia

Climate change leads to accelerated transformation of high‐elevation vegetation in the central Alps

The influence of mesoscale climate drivers on hypoxia in a fjord-like deep coastal inlet and its potential implications regarding climate change and greenhouse gas production: examining a decade of water quality data

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