Drivers of precipitation stable oxygen isotope variability in an alpine setting, Snowy Mountains, Australia

Callow, Nik; McGowan, Hamish A.; Warren, Loredana; Speirs, Johanna

doi:10.1002/2013jd020710

Cited by 26 publications

(17 citation statements)

References 42 publications

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“…In a similar way, event precipitation isotope analyses conducted by Callow et al (2014) identified significant synoptic-type variability in the isotopic signature of precipitation in the Snowy Mountains. The results of our study further support the dominance of moisture-source pathways in controlling isotopic variability in this region.…”

Section: Discussionmentioning

confidence: 70%

A Synoptic Classification of Inflow-Generating Precipitation in the Snowy Mountains, Australia

Theobald

McGowan

Speirs

et al. 2015

Journal of Applied Meteorology and Climatology

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Precipitation falling in the Snowy Mountains region of southeastern Australia provides fuel for hydroelectric power generation and environmental flows along major river systems, as well as critical water resources for agricultural irrigation. A synoptic climatology of daily precipitation that triggers a quantifiable increase in streamflow in the headwater catchments of the Snowy Mountains region is presented for the period 1958-2012. Here, previous synoptic-meteorological studies of the region are extended by using a longer-term, year-round precipitation and reanalysis dataset combined with a novel, automated synoptic-classification technique. A three-dimensional representation of synoptic circulation is developed by effectively combining meteorological variables through the depth of the troposphere. Eleven distinct synoptic types are identified, describing key circulation features and moisture pathways that deliver precipitation to the Snowy Mountains. Synoptic types with the highest precipitation totals are commonly associated with moisture pathways originating from the northeast and northwest of Australia. These systems generate the greatest precipitation totals across the westerly and high-elevation areas of the Snowy Mountains, but precipitation is reduced in the eastern-elevation areas in the lee of the mountain ranges. In eastern regions, synoptic types with onshore transport of humid air from the Tasman Sea are the major source of precipitation. Strong seasonality in synoptic types is evident, with frontal and cutoff-low types dominating in winter and inland heat troughs prevailing in summer. Interaction between tropical and extratropical systems is evident in all seasons.

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Section: Discussionmentioning

confidence: 70%

A Synoptic Classification of Inflow-Generating Precipitation in the Snowy Mountains, Australia

Theobald

McGowan

Speirs

et al. 2015

Journal of Applied Meteorology and Climatology

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“…Many studies have investigated the spatial variability in the isotopic composition of precipitation at the mesoscale (100–1,000 km 2 ) and larger scale (up to the regional and continental scale). They typically found a large spatial variability in the isotopic composition of precipitation that could be explained by the orographic effect, the amount effect, sub‐cloud evaporation, moisture recycling, and differences in the vapor source (e.g., Bortolami, Ricci, Susella, & Zuppi, ; Pionke & De Walle, ; Ersek, Mix, & Clark, ; Crawford, Hughes, & Parkes, ; Callow, McGowan, Warren, & Speirs, ; Tekleab, Wenninger, & Uhlenbrook, ; Peng, Chen, Zhan, Lu, & Tong, ; Kong & Pang, ; Giustini, Brilli, & Patera, ; Delavau, Stadnyk, & Holmes, ; Krklec, Domínguez‐Villar, & Lojen, ). Studies on the isotopic composition of precipitation in small catchments (<10 km 2 ) exists as well (e.g., Gou et al, ; Qu et al, ) but very few of these studies report the observed spatial variability (or data).…”

Section: Reported Spatial Variability In the Isotopic Compositionmentioning

confidence: 99%

Spatial variability in the isotopic composition of water in small catchments and its effect on hydrograph separation

Penna

Meerveld

2019

WIREs Water

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Hydrograph separation is a widely applied technique that uses the stable isotopes of water ( 2 H and 18 O) or other tracers to quantify the contribution of different water sources to streamflow. For its successful application it is critical to adequately characterize these sources (end-members). In most small catchment studies, water samples are collected from end-members at one or a few locations that are assumed to be representative for the entire catchment. We tested this assumption by reviewing 148 papers that used the stable isotopes of water to investigate hydrological processes in catchments up to 10 km 2 . We assessed the typical spatial variability in the isotopic composition of different hydrological compartments when they were sampled at five or more locations across a catchment. The median reported spatial variability was largest for snowmelt and soil water, followed by throughfall and shallow groundwater. To determine how this spatial variability might affect isotope-based hydrograph separation results, we used three-component hydrograph separation for two real rainfall-runoff events and a synthetic rainfall-runoff event and adjusted the isotopic composition of the end-members (throughfall, soil water, and shallow groundwater) by the median observed spatial variability. The estimated maximum contributions of the three components differed by up to 26% from the reference scenario. This suggests that caution is needed when interpreting hydrograph separation results if they are based on samples taken at one or only a few locations. Above all, these results show that the assumption of negligible spatial variability may not be valid for small catchments.

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“…The Yarrangobilly limestone is a massive Silurian formation located in the subalpine area of the northern region of Kosciusko National Park, southeastern Australia (Figure ). The region may provide critical data to understand the palaeo‐climate of both southeastern Australia and the Southern Hemisphere, due to the location of the caves complex, which experiences precipitation sourced from southern mid‐latitudes to the tropics (Callow, McGowan, Warren, & Speirs, ; Theobald, McGowan, Speirs, & Callow, ). Despite this, there is very little published research conducted on the speleothems and associated hydrology of this region (see Markowska et al, ; Spate, Jennings, Ingle Smith, & James, ; Webb et al, ).…”

Section: Study Region and Methodsmentioning

confidence: 99%

A multimethod approach to inform epikarst drip discharge modelling: Implications for palaeo‐climate reconstruction

Campbell

Callow

McGrath

et al. 2017

Hydrological Processes

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Resolving the hydrological processes that form speleothems and the palaeo‐climate archives that they contain is difficult. Typical approaches to hydrological investigation are not suited to karst landscapes, geophysics are seldom applied, drip monitoring and modelling have limitations, and ignoring potential hydrological impacts can result in a proxy record that does not reflect the external environment. We aim to understand the processes and controls that have created a palaeo‐climate proxy record preserved in a speleothem (JC001) in the “Grotto of Oddities,” part of the Jersey Cave at the Yarrangobilly Caves, Australia, to infer the likely nature and resolution of this record. Electrical resistivity tomography (ERT), traditional surveying, and drip discharge monitoring (April 2013 to February 2015) were used to investigate the structure and hydrology of the epikarst overlying the Grotto of Oddities. Data collected through these methods were then used to construct a physically informed and parsimonious drip hydrology model. Geophysics showed that changes in hillslope above the Grotto of Oddities are collocated with a region of low resistivity, which forms an epikarstic reservoir acting to supply enhanced discharge to the speleothem. Drip monitoring showed hysteretic behaviour with a distinct threshold response, and a simple drip classification indicated that the speleothem associated with the drip has the potential to record palaeo‐seasonality or an annual–decadal signal. Discharge modelling indicated discharge was comprised of quick and slow flow, and that discharge is probably perennial. These multimethod results together indicate that the speleothem likely represents a palaeo‐climate record of a length and resolution unprecedented for nonglacial areas of the Southern Hemisphere and for Australia in particular and will significantly enhance current knowledge of the climate of southeast Australia. Although ERT methods have previously been applied in the karst landscape, to our knowledge, this represents the first application of these multiple methods in combination as an approach to assess the fidelity of a speleothem, based on an understanding of the hydrological processes for palaeo‐climate reconstruction.

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Drivers of precipitation stable oxygen isotope variability in an alpine setting, Snowy Mountains, Australia

Cited by 26 publications

References 42 publications

A Synoptic Classification of Inflow-Generating Precipitation in the Snowy Mountains, Australia

A Synoptic Classification of Inflow-Generating Precipitation in the Snowy Mountains, Australia

Spatial variability in the isotopic composition of water in small catchments and its effect on hydrograph separation

A multimethod approach to inform epikarst drip discharge modelling: Implications for palaeo‐climate reconstruction

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