Your search keyword '"Pitman, A. J"' showing total 11 results

1. Reply to “Comments on ‘Global Regional Comparison of Daily 2-m and 1000-hPa Maximum and Minimum Temperatures in Three Global Reanalyses’”

Author

Pitman, A. J. and Perkins, S.

Published

2012

2. Decomposing Temperature Extremes Errors in CMIP5 and CMIP6 Models.

Author

Di Luca, Alejandro, Pitman, Andrew J., and de Elía, Ramón

Subjects

*TEMPERATURE, *ATMOSPHERIC models

Abstract

We quantify the skill of Coupled Model Intercomparison Project Phase 5 (CMIP5) and CMIP6 models to represent daily temperature extremes. We find CMIP models systematically exaggerate the magnitude of daily temperature anomalies for both cold and hot extremes. We assess the contribution to a daily temperature extreme from four terms: the long‐term mean annual cycle, the diurnal cycle, synoptic variability, and seasonal variability for both cold and hot extremes. These four terms are combined, and the overall performance of individual climate models assessed. This identifies those models that can simulate temperature extremes well and simulate them well for the right reasons. The new error metric shows that increases in horizontal resolution usually lead to a better performance particularly for the coarser resolution models. The CMIP6 improvements relative to CMIP5 are systematic across most land regions and are only partially explained by the increase in horizontal resolution, and other differences must therefore help explain the higher CMIP6 skill. Key Points: CMIP5 and CMIP6 models exaggerate the magnitude of daily temperature anomalies for hot days and cold nights extremesHigher‐resolution models improve the simulation of temperature extremes largely due to better simulation of synoptic scalesCMIP6 outperforms the simulation of temperature extremes compared to CMIP5 beyond the benefits given by the higher resolution [ABSTRACT FROM AUTHOR]

Published

2020

3. How representative are FLUXNET measurements of surface fluxes during temperature extremes?

Author

van der Horst, Sophie V. J., Pitman, Andrew J., De Kauwe, Martin G., Ukkola, Anna, Abramowitz, Gab, and Isaac, Peter

Subjects

LATENT heat, TEMPERATURE distribution, HEAT flux, SOCIAL exchange, TEMPERATURE, COLD regions, LOW temperatures

Abstract

In response to a warming climate, temperature extremes are changing in many regions of the world. Therefore, understanding how the fluxes of sensible heat, latent heat and net ecosystem exchange respond and contribute to these changes is important. We examined 216 sites from the open access Tier 1 FLUXNET2015 and free fair-use La Thuile data sets, focussing only on observed (non-gap-filled) data periods. We examined the availability of sensible heat, latent heat and net ecosystem exchange observations coincident in time with measured temperature for all temperatures, and separately for the upper and lower tail of the temperature distribution, and expressed this availability as a measurement ratio. We showed that the measurement ratios for both sensible and latent heat fluxes are generally lower (0.79 and 0.73 respectively) than for temperature measurements, and the measurement ratio of net ecosystem exchange measurements are appreciably lower (0.42). However, sites do exist with a high proportion of measured sensible and latent heat fluxes, mostly over the United States, Europe and Australia. Few sites have a high proportion of measured fluxes at the lower tail of the temperature distribution over very cold regions (e.g. Alaska, Russia) or at the upper tail in many warm regions (e.g. Central America and the majority of the Mediterranean region), and many of the world's coldest and hottest regions are not represented in the freely available FLUXNET data at all (e.g. India, the Gulf States, Greenland and Antarctica). However, some sites do provide measured fluxes at extreme temperatures, suggesting an opportunity for the FLUXNET community to share strategies to increase measurement availability at the tails of the temperature distribution. We also highlight a wide discrepancy between the measurement ratios across FLUXNET sites that is not related to the actual temperature or rainfall regimes at the site, which we cannot explain. Our analysis provides guidance to help select eddy covariance sites for researchers interested in understanding and/or modelling responses to temperature extremes. [ABSTRACT FROM AUTHOR]

Published

2019

4. Influence of antecedent soil moisture conditions on the synoptic meteorology of the Black Saturday bushfire event in southeast Australia.

Author

Kala, Jatin, Evans, Jason P., and Pitman, Andy J.

Subjects

SOIL moisture, SYNOPTIC meteorology, BLACK Saturday wildfires, Victoria, Australia, 2009, TEMPERATURE

Abstract

The dynamics and large-scale drivers of heat wave (HW) events in Australia are well documented. However, the influence of soil moisture in modulating HWs is largely unexplored. We focus here on a recent significant HW event in southeast Australia that preceded the Black Saturday bushfires (3-7 February 2009). During this period, the southeast of Australia experienced unprecedented warm conditions, which, in conjunction with high fuel load and mesoscale weather conditions, led to devastating bushfires. We examine how different initial soil moisture conditions with lead times of 5, 10, and 15 days prior to the event would have altered its overall dynamics at the continental scale. We show that at short lead times (5 days), the influence of perturbing soil moisture is mostly linear. Decreasing (increasing) soil moisture increases (decreases) maximum temperatures, associated with an intensification of the upper-level anticyclone. The effect of increasing soil moisture is more nonlinear than decreasing soil moisture with increasing lead time; namely, increasing soil moisture can also lead to an increase in maximum temperature over some parts of the domain, rather than a decrease everywhere. At lead times of up to 15 days, the imposed perturbation in soil moisture, mostly confined to the Tropics, is essentially lost such that the impact on maximum temperatures on the day of the event cannot be related to the sign of the imposed perturbation in soil moisture. Our results highlight the importance of accurate soil moisture estimates in capturing the intensity and spatial extent of HW events in southeast Australia, but only at relatively short lead times. [ABSTRACT FROM AUTHOR]

Published

2015

5. Intraseasonal versus Interannual Measures of Land-Atmosphere Coupling Strength in a Global Climate Model: GLACE-1 versus GLACE-CMIP5 Experiments in ACCESS1.3b.

Author

Lorenz, Ruth, Pitman, Andrew J., Hirsch, Annette L., and Srbinovsky, Jhan

Subjects

*LAND-atmosphere interactions, *ATMOSPHERIC models, *CLIMATE change, *COMPARATIVE studies

Abstract

Land-atmosphere coupling can strongly affect climate and climate extremes. Estimates of land-atmosphere coupling vary considerably between climate models, between different measures used to define coupling, and between the present and the future. The Australian Community Climate and Earth-System Simulator, version 1.3b (ACCESS1.3b), is used to derive and examine previously used measures of coupling strength. These include the GLACE-1 coupling measure derived on seasonal time scales; a similar measure defined using multiyear simulations; and four other measures of different complexity and data requirements, including measures that can be derived from standard model runs and observations. The ACCESS1.3b land-atmosphere coupling strength is comparable to other climate models. The coupling strength in the Southern Hemisphere summer is larger compared to the Northern Hemisphere summer and is dominated by a strong signal in the tropics and subtropics. The land-atmosphere coupling measures agree on the location of very strong land-atmosphere coupling but show differences in the spatial extent of these regions. However, the investigated measures show disagreement in weaker coupled regions, and some regions are only identified by a single measure as strongly coupled. In future projections the soil moisture trend is crucial in generating regions of strong land-atmosphere coupling, and the results suggest an expansion of coupling 'hot spots.' It is concluded that great care needs to be taken in using different measures of coupling strength and shown that several measures that can be easily derived lead to inconsistent conclusions with more computationally expensive measures designed to measure coupling strength. [ABSTRACT FROM AUTHOR]

Published

2015

6. Tree-ring derived Little Ice Age temperature trends from the central British Columbia Coast Mountains, Canada

Author

Pitman, Kara J. and Smith, Dan J.

Subjects

*TREE-rings, *LITTLE Ice Age, *TEMPERATURE, *MOUNTAINS, *COARSE woody debris, *DENDROCLIMATOLOGY, *MASS budget (Geophysics)

Abstract

Abstract: Most glaciers in the British Columbia Coast Mountains reached their maximum Holocene extent during the Little Ice Age. Early- and late-Little Ice Age intervals of expansion and retreat fluctuations describe a mass-balance response to changing climates. Although existing dendroclimatic records provide insights into these climatic fluctuations over the last 400yr, their short durations prohibit evaluation of early-Little Ice Age climate variability. To extend the duration of these records, submerged coarse woody debris salvaged from a high-elevation lake was cross-dated to living chronologies. The resulting chronology provides the opportunity to reconstruct a regional June–July air-temperature anomaly record extending from AD1225 to 2010. The reconstruction shows that the intervals AD1350–1420, 1475–1550, 1625–1700 and 1830–1940 characterized distinct periods of below-average June–July temperature followed by periods of above-average temperature. Our reconstruction provides the first annually resolved insights into high-elevation climates spanning the Little Ice Age in this region and indicates that Little Ice Age moraine stabilization corresponds to persistent intervals of warmer-than-average temperatures. We conclude that coarse woody debris submerged in high-elevation lakes has considerable potential for developing lengthy proxy climate records, and we recommend that researchers focus attention on this largely ignored paleoclimatic archive. [Copyright &y& Elsevier]

Published

2012

7. Ranking the AR4 climate models over the Murray-Darling Basin using simulated maximum temperature, minimum temperature and precipitation.

Author

Maxino, C. C., McAvaney, B. J., Pitman, A. J., and Perkins, S. E.

Subjects

CLIMATOLOGY, EXAMPLE, TEMPERATURE, CLIMATE change, EVALUATION, GEOLOGICAL basins, METEOROLOGICAL precipitation, FORECASTING

Abstract

The article focuses on ranking the AR4 climate models over the Murray-Darling Basin using simulated maximum temperature, minimum temperature and precipitation. It states that assessment is taken on the capacity of models submitted for Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report (AR4), to simulate maximum and minimum temperatures and precipitation the Murray-Darling Basin in Australia. The team use daily data from AR4 to calculate the mean of three quantities, but also derive probability density functions (PDFs) for each variable. It notes that to demonstrate skill in simulating the daily derived PDFs is more challenging than simulating the mean.

Published

2008

8. Exploring the Sensitivity of the Australian Climate to Regional Land-Cover-Change Scenarios under Increasing CO2 Concentrations and Warmer Temperatures.

Author

Narisma, G. T. and Pitman, A. J.

Subjects

*CLIMATE change, *REFORESTATION, *CLIMATOLOGY, *TEMPERATURE, *GLOBAL warming

Abstract

The potential role of the impacts of land-cover changes (LCCs) in the Australian climate is investigated within the context of increasing CO2 concentrations and temperature. Specifically, it is explored if possible scenarios for LCC can moderate or amplify CO2-induced changes in climate over Australia. The January climate of Australia is simulated under three different land-cover-change scenarios using a high-resolution regional climate model. The land-cover-change scenarios include a steady-state land cover that is equivalent to current land cover, a low-reforestation scenario that recovers approximately 25% of the trees replaced by grasslands within the last 200 yr, and a high-reforestation scenario that recovers at least 75% of the deforested regions. The model was driven by boundary conditions taken from transitory climate simulations from a general circulation model that included two climate scenarios based on two projected scenarios of CO2 concentration increase. The results show that reforestation has the potential to reduce the projected increase in Australian temperatures in 2050 and 2100 by as much as 40% and 20%, respectively. This cooling effect, however, is highly localized and occurs only in regions of reforestation. The results therefore hint that the potential of reforestation to moderate the impact of global warming may be significantly limited by the spatial scale of reforestation. In terms of deforestation, results show that any future land clearing can exacerbate the projected warming in certain regions of Australia. Carbon-related variables are also analyzed and results show that changes in net CO2 flux may be influenced more by soil respiration than by photosynthesis. The results herein encourage studies on the inclusion of land-cover-change scenarios in future climate change projection simulations of the Australian climate. [ABSTRACT FROM AUTHOR]

Published

2006

9. The contribution of the land surface energy balance complexity to differences in means, variances and extremes using the AMIP-II methodology.

Author

Bagnoud, N., Pitman, A. J., McAvaney, B. J., and Holbrook, N. J.

Subjects

*SURFACE energy, *PROPERTIES of matter, *METEOROLOGICAL precipitation, *TEMPERATURE, *ANALYSIS of variance, *BIOENERGETICS

Abstract

This paper explores the relationship between the complexity of the land surface energy balance parameterization and the simulation of means, variances and extremes in a climate model. We used the BMRC climate model combined with the protocol of AMIP-II to perform six ensemble simulations for each of four levels of surface energy balance complexity. Our results were then compared with other AMIP-II results in terms of the mean, variance and extremes of temperatures and precipitation. In terms of the zonally-averaged mean and the maximum temperatures and precipitation, the surface energy balance complexity did not systematically affect the BMRC climate model results. The zonal minimum temperature was affected by the inclusion of tiling and/or a temporally variable canopy conductance. We found no evidence that surface energy balance complexity affected the globally- or zonally-averaged variances. Some quite large differences were identified in the probability density functions of maximum (10 K) and minimum (4 K) temperature caused by surface tiling and/or the inclusion of a time-varying canopy conductance. With these included, the model simulated a higher probability of cooler minima and warmer maxima and therefore a different diurnal temperature range. Adding interception of precipitation led to an increase in the likelihood of more extreme precipitation. Thus, provided interception, surface tiling and a time-variable stomatal conductance are included in a land surface model, the impact of other uncertainties in the parameterization of the surface energy balance are unlikely to limit the use of climate models for simulating changes in the extremes. Most published results indicating changes to precipitation and temperature extremes due to increasing carbon dioxide are therefore unlikely to be significantly limited by uncertainty in how to parameterize the surface energy balance. Given that the variations in surface energy balance complexity included in our experiments approximates the range included in the AMIP-II models, we conclude that it this is unlikely to explain the differences found between the AMIP-II simulations. This does not mean that AMIP-II differences are not caused to a significant degree by differences in their respective LSMs, rather it limits the potential role of the land surface to non-surface energy balance components, or components (such as carbon) that are not considered here. [ABSTRACT FROM AUTHOR]

Published

2005

10. Factors that shape seed mass evolution.

Author

Moles, Angela T., Ackerly, David D., Webb, Campbell O., Tweddlell, John C., Dickie, John B., Pitman, Andy J., and Westoby, Mark

Subjects

PLANT evolution, SEEDS, SPECIES, LATITUDE, TEMPERATURE, PLANT growth

Abstract

We used correlated divergence analysis to determine which factors have been most closely associated with changes in seed mass during seed plant evolution. We found that divergences in seed mass have been more consistently associated with divergences in growth form than with divergences in any other variable. This finding is consistent with the strong relationship between seed mass and growth form across present-day species and with the available data from the paleobotanical literature. Divergences in seed mass have also been associated with divergences in latitude, net primary productivity, temperature, precipitation, and leaf area index. However, these environmental variables had much less explanatory power than did plant traits such as seed dispersal syndrome and plant growth form. [ABSTRACT FROM AUTHOR]

Published

2005

11. PREDICTION OF NEAREST SAFE DISTANCES FOR THERMAL RADIATION OF NUCLEAR WEAPONS

Author

Pitman, Jr, J

Published

1966