Search

Your search keyword '"Di Luca, Alejandro"' showing total 26 results
Start Over "Di Luca, Alejandro" Search Limiters Available in Library Collection Language english
26 results on '"Di Luca, Alejandro"'

6. Spatial spin-up of precipitation in limited-area convection-permitting simulations over North America using the CRCM6/GEM5.0 model.

Author

Roberge, François, Di Luca, Alejandro, Laprise, René, Lucas-Picher, Philippe, and Thériault, Julie

Subjects
*SEASONS, *WINTER
Abstract

A fundamental issue associated with the dynamical downscaling technique using limited-area models is related to the presence of a "spatial spin-up" belt close to the lateral boundaries where small-scale features are only partially developed. Here, we introduce a method to identify the distance from the border that is affected by the spatial spin-up (i.e., the spatial spin-up distance) of the precipitation field in convection-permitting model (CPM) simulations. Using a domain over eastern North America, this new method is applied to several simulations that differ on the nesting approach (single or double nesting) and the 3-D variables used to drive the CPM simulation. Our findings highlight three key points. Firstly, when using a single nesting approach, the spin-up distance from lateral boundaries can extend up to 300 km (around 120 CPM grid points), varying across seasons, boundaries and driving variables. Secondly, the greatest spin-up distances occur in winter at the western and southern boundaries, likely due to strong atmospheric inflow during these seasons. Thirdly, employing a double nesting approach with a comprehensive set of microphysical variables to drive CPM simulations offers clear advantages. The computational gains from reducing spatial spin-up outweigh the costs associated with the more demanding intermediate simulation of the double nesting. These results have practical implications for optimizing CPM simulation configurations, encompassing domain selection and driving strategies. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

10. Spatial spin-up of precipitation in limited-area convection-permitting simulations over North America.

Author

Roberge, François, Di Luca, Alejandro, Laprise, René, Lucas-Picher, Philippe, and Thériault, Julie

Subjects
*SEASONS, *WINTER
Abstract

A fundamental issue associated with the dynamical downscaling technique using limited-area models is related to the presence of a "spatial spin-up" belt close to the lateral boundaries where small-scale features are only partially developed. Here, we introduce a method to identify the distance from the border that is affected by the spatial spin-up (I.e., the spatial spin-up distance) of the precipitation field in convection-permitting model (CPM) simulations. Using a domain over eastern North America, this new method is applied to several simulations that differ on the nesting approach (single or double nesting) and the 3-D variables used to drive the CPM simulation. Our findings highlight three key points. Firstly, when using a single nesting approach, the spin-up distance from lateral boundaries can extend up to 300 km (around 120 CPM grid points), varying across seasons, boundaries, and driving variables. Secondly, the greatest spin-up distances occur in winter at the western and southern boundaries, likely due to strong atmospheric inflow during these seasons. Thirdly, employing a double nesting approach with a comprehensive set of microphysical variables to drive CPM simulations offers clear advantages. The computational gains from reducing spatial spin-up outweigh the costs associated with the more demanding intermediate simulation of the double nesting. These results have practical implications for optimizing CPM simulation configurations, encompassing domain selection and driving strategies. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

11. On the Intercontinental Transferability of Regional Climate Model Response to Severe Forestation.

Author

Asselin, Olivier, Leduc, Martin, Paquin, Dominique, Di Luca, Alejandro, Winger, Katja, Bukovsky, Melissa, Music, Biljana, and Giguère, Michel

Subjects
FORESTS & forestry, ATMOSPHERIC models, BROADLEAF forests, EDDY flux, SPRING
Abstract

The biogeophysical effects of severe forestation are quantified using a new ensemble of regional climate simulations over North America and Europe. Following the protocol outlined for the Land-Use and Climate Across Scales (LUCAS) intercomparison project, two sets of simulations are compared, FOREST and GRASS, which respectively represent worlds where all vegetation is replaced by trees and grasses. Three regional climate models were run over North America. One of them, the Canadian Regional Climate Model (CRCM5), was also run over Europe in an attempt to bridge results with the original LUCAS ensemble, which was confined to Europe. Overall, the CRCM5 response to forestation reveals strong inter-continental similarities, including a pronounced wintertime and springtime warming concentrated over snow-masking evergreen forests. Crucially, these northern evergreen needleleaf forests populate lower, hence sunnier, latitudes in North America than in Europe. Snow masking reduces albedo similarly over both continents, but stronger insolation amplifies the net shortwave radiation and hence warming simulated over North America. In the summertime, CRCM5 produces a mixed response to forestation, with warming over northern needleleaf forests and cooling over southern broadleaf forests. The partitioning of the turbulent heat fluxes plays a major role in determining this response, but it is not robust across models over North America. Implications for the inter-continental transferability of the original LUCAS results are discussed. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

12. Rapid Warming in the Australian Alps from Observation and NARCliM Simulations.

Author

Ji, Fei, Nishant, Nidhi, Evans, Jason P., Di Luca, Alejandro, Di Virgilio, Giovanni, Cheung, Kevin K. W., Tam, Eugene, Beyer, Kathleen, and Riley, Matthew L.

Subjects
SNOW cover, SPATIAL variation, ATMOSPHERIC models, ALBEDO
Abstract

The Australian Alps are the highest mountain range in Australia, which are important for biodiversity, energy generation and winter tourism. Significant increases in temperature in the past decades has had a huge impact on biodiversity and ecosystem in this region. In this study, observed temperature is used to assess how temperature changed over the Australian Alps and surrounding areas. We also use outputs from two generations of NARCliM (NSW and Australian Regional Climate Modelling) to investigate spatial and temporal variation of future changes in temperature and its extremes. The results show temperature increases faster for the Australian Alps than the surrounding areas, with clear spatial and temporal variation. The changes in temperature and its extremes are found to be strongly correlated with changes in albedo, which suggests faster warming in cool season might be dominated by decrease in albedo resulting from future changes in natural snowfall and snowpack. The warming induced reduction in future snow cover in the Australian Alps will have a significant impact on this region. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

13. Seasonality of Continental Extratropical‐Cyclone Wind Speeds Over Northeastern North America.

Author

Chen, Ting‐Chen, Di Luca, Alejandro, Winger, Katja, Laprise, René, and Thériault, Julie M.

Subjects
*WIND speed, *CYCLONES, *AUTUMN, *WINTER storms, *RICHARDSON number, *SURFACE roughness
Abstract

This study investigates the seasonality of near‐surface wind speeds associated with extratropical cyclones (ETCs) over northeastern North America using a global reanalysis data set during 1979–2020. As opposed to most studies that emphasize winter storms, ETCs during the fall exhibit significantly stronger 10‐m winds over this region due to the slightly stronger continental cyclones and significantly weaker low‐level stability during that time of the year. Also, ETCs favor inland lakes and Hudson Bay during the low‐ice‐content fall season, leading to lower surface roughness. Combining these results, we derive simple linear regressions to predict the 10‐m wind speed given three variables: 850‐hPa wind speed, low‐level Richardson number, and surface roughness length. This formula captures the observed seasonality and serves as a valuable tool for cyclone near‐surface wind risk assessment. Plain Language Summary: Extratropical cyclones can bring powerful winds that can cause severe damage to infrastructure. We find that cyclones with severe winds are the most frequent in the fall season over continental northeastern North America. Three reasons are found responsible: stronger continental cyclones, weaker low‐level atmospheric stability, and the lower surface roughness over lakes and Hudson Bay, where cyclones frequently occur in fall. A simple formula that can effectively assess the near‐surface wind speeds associated with cyclones is derived based on these results. Key Points: Extratropical‐cyclone‐associated 10‐m wind speeds are the strongest in the fall season over northeastern North AmericaBesides stronger continental cyclones and 850‐hPa winds, weaker low‐level stability in fall favors stronger 10‐m wind speeds in this regionLinear regression using 850‐hPa wind, Richardson number, and surface roughness well predicts cyclones' 10‐m wind speeds and seasonality [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

14. Climate Response to Severe Forestation: A Regional Climate Model Intercomparison Study.

Author

Asselin, Olivier, Leduc, Martin, Paquin, Dominique, Winger, Katja, Di Luca, Alejandro, Bukovsky, Melissa, Music, Biljana, and Giguère, Michel

Subjects
FORESTS & forestry, ATMOSPHERIC models, BROADLEAF forests, EDDY flux, HEAT flux
Abstract

The biogeophysical effects of severe forestation are quantified using a new ensemble of regional climate simulations over North America and Europe. Following the protocol outlined for the Land-Use and Climate Across Scales (LUCAS) intercomparison project, two sets of simulations are compared, FOREST and GRASS, which respectively represent worlds where all vegetation is replaced by trees and grasses. Three regional climate models were run over North America. One of them, the Canadian Regional Climate Model (CRCM5), was also run over Europe in an attempt to bridge results with the original LUCAS ensemble, which was confined to Europe. Overall, the CRCM5 response to forestation reveals strong inter-continental similarities, including a pronounced wintertime and springtime warming concentrated over snow-masking evergreen forests. Crucially, these northern evergreen needleleaf forests populate lower, hence sunnier latitudes in North America than in Europe. Snow masking reduces albedo similarly over both continents, but stronger insolation amplifies the net shortwave radiation and hence warming simulated over North America. In the summertime, CRCM5 produces a mixed response to forestation, with warming over northern needleleaf forests and cooling over southern broadleaf forests. The partitioning of the turbulent heat fluxes plays a major role in determining this response, but it is not robust across models over North America. Implications for the inter-continental transferability of the original LUCAS results are discussed. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

15. An update of IPCC climate reference regions for subcontinental analysis of climate model data: definition and aggregated datasets.

Author

Iturbide, Maialen, Gutiérrez, José M., Alves, Lincoln M., Bedia, Joaquín, Cerezo-Mota, Ruth, Cimadevilla, Ezequiel, Cofiño, Antonio S., Di Luca, Alejandro, Faria, Sergio Henrique, Gorodetskaya, Irina V., Hauser, Mathias, Herrera, Sixto, Hennessy, Kevin, Hewitt, Helene T., Jones, Richard G., Krakovska, Svitlana, Manzanas, Rodrigo, Martínez-Castro, Daniel, Narisma, Gemma T., and Nurhati, Intan S.

Subjects
ATMOSPHERIC models, DATA modeling, SCATTER diagrams, CLIMATE change, DEFINITIONS
Abstract

Several sets of reference regions have been used in the literature for the regional synthesis of observed and modelled climate and climate change information. A popular example is the series of reference regions used in the Intergovernmental Panel on Climate Change (IPCC) Special Report on Managing the Risks of Extreme Events and Disasters to Advance Climate Adaptation (SREX). The SREX regions were slightly modified for the Fifth Assessment Report of the IPCC and used for reporting subcontinental observed and projected changes over a reduced number (33) of climatologically consistent regions encompassing a representative number of grid boxes. These regions are intended to allow analysis of atmospheric data over broad land or ocean regions and have been used as the basis for several popular spatially aggregated datasets, such as the Seasonal Mean Temperature and Precipitation in IPCC Regions for CMIP5 dataset. We present an updated version of the reference regions for the analysis of new observed and simulated datasets (including CMIP6) which offer an opportunity for refinement due to the higher atmospheric model resolution. As a result, the number of land and ocean regions is increased to 46 and 15, respectively, better representing consistent regional climate features. The paper describes the rationale for the definition of the new regions and analyses their homogeneity. The regions are defined as polygons and are provided as coordinates and a shapefile together with companion R and Python notebooks to illustrate their use in practical problems (e.g. calculating regional averages). We also describe the generation of a new dataset with monthly temperature and precipitation, spatially aggregated in the new regions, currently for CMIP5 and CMIP6, to be extended to other datasets in the future (including observations). The use of these reference regions, dataset and code is illustrated through a worked example using scatter plots to offer guidance on the likely range of future climate change at the scale of the reference regions. The regions, datasets and code (R and Python notebooks) are freely available at the ATLAS GitHub repository: https://github.com/SantanderMetGroup/ATLAS (last access: 24 August 2020), 10.5281/zenodo.3998463 (Iturbide et al., 2020). [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

16. 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
Full Text
View/download PDF

19. Impact of Identification Method on the Inferred Characteristics and Variability of Australian East Coast Lows.

Author

Pepler, Acacia S., Di Luca, Alejandro, Ji, Fei, Alexander, Lisa V., Evans, Jason P., and Sherwood, Steven C.

Subjects
*RAINFALL, *DAMS, *CYCLONES, *COASTS, *SEVERE storms
Abstract

The Australian east coast low (ECL) is both a major cause of damaging severe weather and an important contributor to rainfall and dam inflow along the east coast, and is of interest to a wide range of groups including catchment managers and emergency services. For this reason, several studies in recent years have developed and interrogated databases of east coast lows using a variety of automated cyclone detection methods and identification criteria. This paper retunes each method so that all yield a similar event frequency within the ECL region, to enable a detailed intercomparison of the similarities, differences, and relative advantages of each method. All methods are shown to have substantial skill at identifying ECL events leading to major impacts or explosive development, but the choice of method significantly affects both the seasonal and interannual variation of detected ECL numbers. This must be taken into consideration in studies on trends or variability in ECLs, with a subcategorization of ECL events by synoptic situation of key importance. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

20. Effects of City Expansion on Heat Stress under Climate Change Conditions.

Author

Argüeso, Daniel, Evans, Jason P., Pitman, Andrew J., and Di Luca, Alejandro

Subjects
PHYSIOLOGICAL effects of heat, CLIMATE change, URBAN growth, EXTREME value theory, VAPOR pressure
Abstract

We examine the joint contribution of urban expansion and climate change on heat stress over the Sydney region. A Regional Climate Model was used to downscale present (1990–2009) and future (2040–2059) simulations from a Global Climate Model. The effects of urban surfaces on local temperature and vapor pressure were included. The role of urban expansion in modulating the climate change signal at local scales was investigated using a human heat-stress index combining temperature and vapor pressure. Urban expansion and climate change leads to increased risk of heat-stress conditions in the Sydney region, with substantially more frequent adverse conditions in urban areas. Impacts are particularly obvious in extreme values; daytime heat-stress impacts are more noticeable in the higher percentiles than in the mean values and the impact at night is more obvious in the lower percentiles than in the mean. Urban expansion enhances heat-stress increases due to climate change at night, but partly compensates its effects during the day. These differences are due to a stronger contribution from vapor pressure deficit during the day and from temperature increases during the night induced by urban surfaces. Our results highlight the inappropriateness of assessing human comfort determined using temperature changes alone and point to the likelihood that impacts of climate change assessed using models that lack urban surfaces probably underestimate future changes in terms of human comfort. [ABSTRACT FROM AUTHOR]

Published
2015
Full Text
View/download PDF

21. Thank You to Our 2022 Peer Reviewers.

Author

Rajaram, Harihar, Camargo, Suzana, Cappa, Christopher D., Dombard, Andrew J., Donohue, Kathleen A., Feakins, Sarah, Flesch, Lucy, Giannini, Alessandra, Gu, Yu, Huber, Christian, Ivanov, Valeriy, Karnauskas, Kristopher, Korte, Monika, Lu, Gang, Magnusdottir, Gudrun, Morlighem, Mathieu, Prieto, Germán A., Qiu, Bo, Su, Hui, and Sun, Daoyuan

Subjects
OPEN scholarship, SCIENTIFIC community, ACQUISITION of manuscripts, DATA quality, PEERS, DEMAND forecasting
Abstract

On behalf of the journal, AGU, and the scientific community, the editors of Geophysical Research Letters would like to sincerely thank those who reviewed manuscripts for us in 2022. The hours reading and commenting on manuscripts not only improve the manuscripts, but also increase the scientific rigor of future research in the field. With the advent of AGU's data policy, many reviewers have also helped immensely to evaluate the accessibility and availability of data, and many have provided insightful comments that helped to improve the data presentation and quality. We greatly appreciate the assistance of the reviewers in advancing open science, which is a key objective of AGU's data policy. We particularly appreciate the timely reviews in light of the demands imposed by the rapid review process at Geophysical Research Letters. We received 6,687 submissions in 2022 and 5,247 reviewers contributed to their evaluation by providing 8,720 reviews in total. We deeply appreciate their contributions in these challenging times. Plain Language Summary: Individuals in italics provided three or more reviews for GRL in 2022. Key Points: The editors thank the 2022 peer reviewers [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

22. Thank You to Our 2022 Reviewers.

Author

Caprarelli, Graziella, Altintas, Ilkay, Baratoux, David, Cervato, Cinzia, Diviacco, Paolo, Donea, Alina, Donnellan, Andrea, Gentemann, Chelle, Glaves, Helen M., Jiang, Jonathan H., Jones, Cathleen E., Maute, Astrid, Mills, Franklin P., Pirenne, Benoit, Pryor, Sara C., Tiampo, Kristy, and Xie, Zunyi

Subjects
SPACE sciences, EARTH sciences, PERIODICAL publishing, EXPERTISE
Abstract

Plain Language Summary: The Editors and Staff of Earth and Space Science acknowledge the importance of hundreds of peer reviewers who contributed to the scientific rigor of the papers published in the journal. The Editors wish to publicly recognize the 839 reviewers who gave selflessly of their time and expertise in 2022. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

23. Appreciation of 2017 GRL Peer Reviewers.

Author

Diffenbaugh, Noah, Beal, Lisa, Bayani Cardenas, M., Cobb, Kim, Cory, Rose, Cronin, Meghan, Dombard, Andrew J., Hogg, Andrew, Ilyina, Tatiana, Korte, Monika, Lu, Gang, Magnusdottir, Gudrun, Newman, Andrew V., Opher, Merav, Ritsema, Jeroen, Sprintall, Janet, Stroeve, Julienne, Thornton, Joel A., Williams, Paul D., and Yau, Andrew

Abstract

Thank you to those who reviewed in 2017 for Geophysical Research Letters. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

24. Appreciation of peer reviewers for 2015.

Author

Diffenbaugh, Noah, Beal, Lisa, Cardenas, M. Bayani, Cobb, Kim, Cronin, Meghan, Dombard, Andrew J., Ilyina, Tatiana, Knorr, Wolfgang, Lavraud, Benoit, Newman, Andrew V., Peterson, W.K. (Bill), Ritsema, Jeroen, Stroeve, Julienne, Thornton, Joel A., Wysession, Michael, and Williams, Paul D.

Published
2016
Full Text
View/download PDF

25. Global hotspots for the occurrence of compound events

Author

Jason P. Evans, Hong Xuan Do, Anna M. Ukkola, Andrew J. Pitman, Jakob Zscheischler, Nina Ridder, Margot Bador, Seth Westra, Annette L. Hirsch, and Alejandro Di Luca

Subjects
Climate events, Multivariate statistics, 010504 meteorology & atmospheric sciences, 530 Physics, Science, 0208 environmental biotechnology, General Physics and Astronomy, Weather and climate, 02 engineering and technology, 01 natural sciences, behavioral disciplines and activities, General Biochemistry, Genetics and Molecular Biology, Article, Natural hazard, 0105 earth and related environmental sciences, Multidisciplinary, Natural hazards, food and beverages, General Chemistry, social sciences, Publisher Correction, Hazard, humanities, 020801 environmental engineering, Geography, Western europe, Climate model, Physical geography, Climate sciences
Abstract

Compound events (CEs) are weather and climate events that result from multiple hazards or drivers with the potential to cause severe socio-economic impacts. Compared with isolated hazards, the multiple hazards/drivers associated with CEs can lead to higher economic losses and death tolls. Here, we provide the first analysis of multiple multivariate CEs potentially causing high-impact floods, droughts, and fires. Using observations and reanalysis data during 1980–2014, we analyse 27 hazard pairs and provide the first spatial estimates of their occurrences on the global scale. We identify hotspots of multivariate CEs including many socio-economically important regions such as North America, Russia and western Europe. We analyse the relative importance of different multivariate CEs in six continental regions to highlight CEs posing the highest risk. Our results provide initial guidance to assess the regional risk of CE events and an observationally-based dataset to aid evaluation of climate models for simulating multivariate CEs., Compound climate events such as floods and droughts together can cause severe socio-economic impacts. Here, the authors analyse global hazard pairs from 1980–2014 and find global hotspots for the occurrence of compound events.

Published
2020

Catalog

Books, media, physical & digital resources
See catalog results