Your search keyword '"McRobie FH"' showing total 4 results

1. Author Correction: Holocene El Niño-Southern Oscillation variability reflected in subtropical Australian precipitation.

Author

Barr C, Tibby J, Leng MJ, Tyler JJ, Henderson ACG, Overpeck JT, Simpson GL, Cole JE, Phipps SJ, Marshall JC, McGregor GB, Hua Q, and McRobie FH

Published

2021

2. Holocene El Niño-Southern Oscillation variability reflected in subtropical Australian precipitation.

Author

Barr C, Tibby J, Leng MJ, Tyler JJ, Henderson ACG, Overpeck JT, Simpson GL, Cole JE, Phipps SJ, Marshall JC, McGregor GB, Hua Q, and McRobie FH

Abstract

The La Niña and El Niño phases of the El Niño-Southern Oscillation (ENSO) have major impacts on regional rainfall patterns around the globe, with substantial environmental, societal and economic implications. Long-term perspectives on ENSO behaviour, under changing background conditions, are essential to anticipating how ENSO phases may respond under future climate scenarios. Here, we derive a 7700-year, quantitative precipitation record using carbon isotope ratios from a single species of leaf preserved in lake sediments from subtropical eastern Australia. We find a generally wet (more La Niña-like) mid-Holocene that shifted towards drier and more variable climates after 3200 cal. yr BP, primarily driven by increasing frequency and strength of the El Niño phase. Climate model simulations implicate a progressive orbitally-driven weakening of the Pacific Walker Circulation as contributing to this change. At centennial scales, high rainfall characterised the Little Ice Age (~1450-1850 CE) in subtropical eastern Australia, contrasting with oceanic proxies that suggest El Niño-like conditions prevail during this period. Our data provide a new western Pacific perspective on Holocene ENSO variability and highlight the need to address ENSO reconstruction with a geographically diverse network of sites to characterise how both ENSO, and its impacts, vary in a changing climate.

Published

2019

3. See-saw relationship of the Holocene East Asian-Australian summer monsoon.

Author

Eroglu D, McRobie FH, Ozken I, Stemler T, Wyrwoll KH, Breitenbach SF, Marwan N, and Kurths J

Abstract

The East Asian-Indonesian-Australian summer monsoon (EAIASM) links the Earth's hemispheres and provides a heat source that drives global circulation. At seasonal and inter-seasonal timescales, the summer monsoon of one hemisphere is linked via outflows from the winter monsoon of the opposing hemisphere. Long-term phase relationships between the East Asian summer monsoon (EASM) and the Indonesian-Australian summer monsoon (IASM) are poorly understood, raising questions of long-term adjustments to future greenhouse-triggered climate change and whether these changes could 'lock in' possible IASM and EASM phase relationships in a region dependent on monsoonal rainfall. Here we show that a newly developed nonlinear time series analysis technique allows confident identification of strong versus weak monsoon phases at millennial to sub-centennial timescales. We find a see-saw relationship over the last 9,000 years-with strong and weak monsoons opposingly phased and triggered by solar variations. Our results provide insights into centennial- to millennial-scale relationships within the wider EAIASM regime.

Published

2016

4. A spatial-temporal rainfall generator for urban drainage design.

Author

McRobie FH, Wang LP, Onof C, and Kenney S

Subjects

Environmental Monitoring, Models, Theoretical, Drainage, Rain, Water Movements

Abstract

The work presented here is a contribution to the Thames Water project of improving the Counters Creek catchment sewerage system in London. An increase in the number of floods affecting basements in the area has indicated the need for improvements to the system. The cost of such improvements could be very high, and as such it is important to determine whether the traditional approach of applying 30-year spatially uniform design storms results in substantial overestimation. The first step in this is to generate simulations of spatially distributed rainfall events, from which 30-year storms can be extracted. Storms are modelled as clusters of Gaussian rainfall cells, extending the earlier Willems method to radar rainfall data. The parameters describing the cells and their motion are sampled from probability distributions derived from parameter estimates gained from 45 historical storm events within the catchment for the period 2000-2011. This spatial-temporal stochastic rainfall generator produces a two-dimensional time series of simulated storm events, from which events of given return period can be identified.

Published

2013