Current and Future Climate Extremes Over Latin America and Caribbean: Assessing Earth System Models from High Resolution Model Intercomparison Project (HighResMIP)

Ávila-Díaz, Alvaro; Torres, Roger Rodrigues; Zuluaga, Cristian Felipe; Cerón, Wilmar Loaiza; Oliveira, Lais Rosa; Benezoli, Victor Hugo; Rivera, Irma Ayes; Marengo, José A.; Wilson, Aaron B.; Medeiros, Felipe Jeferson de

doi:10.1007/s41748-022-00337-7

Cited by 15 publications

(7 citation statements)

References 153 publications

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“…The expected values of the hydrothermal index, HTC, for this region are between 1 and 1.5 mm·°C −1 , which are ideal for growing grapevines. On the contrary, in Baja California precipitation could slightly increase during the GS, consistent with other model results (Cavazos & Arriaga‐Ramírez, 2012), while there could be a minimal decrease in winter, but with high variation due to atmospheric rivers (Gershunov et al, 2019), extreme events (Avila‐Diaz et al, 2022), and changes in natural oscillations, such as El Niño–Southern Oscillation (IPCC, 2021). The Mexican HP region is also affected by ENSO variations during the summer and winter (e.g., Vega‐Camarena et al, 2023).…”

Section: Discussionsupporting

confidence: 85%

Impact of climate change in Mexican winegrape regions

Castillo,

Cavazos,

Pavia

2023

Intl Journal of Climatology

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We analysed the current climate of seven winegrowing regions of Mexico and their possible changes during the 21st century. Various bioclimatic indices were calculated with observations and simulations over a wide domain that covers Mexico and the south and southwest United States. We used two regional climate models (RegCM4.7 and RCA4) for historical (1981–2010), near future (NF: 2021–2050) and far future (FF: 2070–2099) periods under two greenhouse gas emissions scenarios (RCP2.6 and RCP8.5). Both models reproduced the main characteristics of the Mediterranean and semiarid climates typical of the winegrape regions with some biases. Despite the errors, the models suggest similar future changes during the growing season (GS: April–October) in winegrape regions. Increases in temperature (~1.2°C) are expected in the NF, which could produce an early start from the growth (mid‐March) season to the harvest. More significant changes are expected in the FF under the RCP8.5 scenario; temperature during April–October may increase ~4°C, and growing degree‐days (GDD) and minimum temperature could also increase (~700 and 4.5°C, respectively), especially in the northern Mexican high plateau, substantially reducing the suitable areas for viticulture. In Baja California (BC) the suitable years for viticulture may decline by 30%–50%, suggesting an increase in the interannual uncertainty. Moreover, in BC and California the number of cool nights (Tmin < 12°C) could be reduced during the current harvest season (September) affecting winegrape acidity and flavour. Therefore, the viticulture sector and the wine industry may need to implement early adaptation/mitigation measures to overcome these possible changes and winegrape phenology shifts.

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Section: Discussionsupporting

confidence: 85%

Impact of climate change in Mexican winegrape regions

Castillo,

Cavazos,

Pavia

2023

Intl Journal of Climatology

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“…These risks are typically called technological disasters, such as dam failures, atomic reactor leaks, and water pollution due to industrial discharge (Andrade L. et al, 2021). Other "produced" risks include anthropogenic changes in climatic conditions, which can ultimately lead to the increased occurrence and intensification of disasters, such as floods, droughts, and landslides (Quintão et al, 2017;Avila-Diaz et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

“…A third axis encompasses studies that link climate data (usually measured in a continuous resolution, based on raster data) with disaster and population data (mostly discrete in their measurement and availability). The major challenge facing these studies is how to link climate data, which follow an Earth systems logic, with population data that are captured and measured in artificial administrative units (Avila-Diaz et al, 2022). Two major challenges manifest themselves in the form of spatial resolution (raster vs. polygonal/point discrete data) and temporal resolution (how long the data must be monitored to detect changes).…”

Section: Discussionmentioning

confidence: 99%

“…For example, Andrade L. et al (2021) sampled climate data points from the Climdex Project, available in a 0.25 • × 0.25 • resolution, to discretize information on climate extremes at the mesoregional level. These discretized data points, encompassing a time series The interaction between homogenous climatic zones and socioeconomic contexts helps identify climate vulnerability hotspots (Menezes et al, 2018;Avila-Diaz et al, 2022). Vulnerability reduction depends on the ability of each society to improve protective mechanisms (adaptive capacity), which include private insurance (contractual insurance policies, selfprotection, information seeking, home improvement) and public technologies (such as extreme weather alerts from official climate agencies).…”

Section: Discussionmentioning

confidence: 99%

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Profiling sociodemographic attributes and extreme precipitation events as mediators of climate-induced disasters in municipalities in the state of Minas Gerais, Brazil

Guedes¹,

Andrade²,

Silva³

et al. 2023

Front. Hum. Dyn.

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IntroductionData indicate an increase in the number of natural disasters in Brazil, with a large share of these events occurring in the state of Minas Gerais. This study examines precipitation-related natural disasters recorded between 1991 and 2016 in Minas Gerais by identifying municipality profiles (encompassing the number of droughts, flash floods, and flooding events), their sensitivity to geophysical and extreme climatic exposure, and their relation to sociodemographic and infrastructure characteristics.MethodsWe combine climate data on seven extreme rainfall indices with elevation data for each municipal seat. We obtained data on droughts, flash floods, and floods from the Center for Engineering and Civil Defense Research and Studies. Population and socio-sanitary characteristics were obtained from the 2010 Brazilian Demographic Census. First, we modeled the climatic-geo-socio-sanitary data using latent class analysis as a pure latent cluster model (LCM) without covariates on seven extreme precipitation indices coupled with altitude data. Subsequently, the LCM was used to identify precipitation-related disaster clusters, including clusters from the 1S-LCM as an active covariate (2S-LCM). Finally, we utilized sociodemographic and infrastructure variables simultaneously with the clusters from the 2S-LCM on an LCM without active covariates (3S-LCM).ResultsOur results show an increase in precipitation-related disasters in Minas Gerais, with municipalities located in the northern part of the state being particularly affected. The state registered 5,553 natural disasters in this period, with precipitation-related disasters representing 94.5% of all natural disasters. The 1S-LCM identified four homoclimatic zones, encompassing a low-altitude dry zone, a relatively low-altitude intermediately wet zone, a relatively high-altitude intermediately wet zone, and a high-altitude wet zone. The 2S-LCM produced four precipitation-related disaster classes, denominated low risk, high risk of excess precipitation, intermediate risk of precipitation deficit and excess, and high risk of precipitation deficit.DiscussionCities with better infrastructure and sociodemographic profiles in semi-arid regions are more resilient to droughts. In richer areas, floods are still a concern where incomplete urbanization transitions may undermine resilience to these events as they increase in intensity with the advance of climate change.

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“…This would be attributed to the overcoming of thresholds of the thermoregulatory capacity of the human body, hindered by the concomitant increase in humidity and temperature, particularly in low-elevation tropical cities. All these impacts are particularly worrisome given that, under a business-as-usual scenario, a significant increase in temperature (e.g., warm days, heatwaves) and precipitation (e.g., very wet days, rainfall intensity) extremes over the mid-twenty-first century is likely to occur in Colombia [5].…”

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confidence: 99%