Fact-checked by Grok 2 weeks ago

Heat Waves

A is a prolonged period of excessively hot weather, typically lasting two or more days, during which temperatures exceed the historical averages for a specific location and time of year. These events are characterized by sustained high temperatures that can strain human physiology, , and natural systems, often accompanied by high that exacerbates the perceived heat through elevated values. Heat waves arise primarily from atmospheric high-pressure systems that trap warm air near the Earth's surface, inhibiting cloud formation, wind circulation, and , which would otherwise provide cooling. In regions like the , such systems can persist due to weakened patterns, as seen in the event where a stationary high-pressure ridge over the led to record-breaking temperatures and over 8,000 warm records broken or tied. Urban areas amplify heat waves through the urban heat island effect, where and absorb and radiate heat, making cities several degrees warmer than surrounding rural areas. The health impacts of heat waves are profound and disproportionately affect vulnerable populations, including the elderly, children, outdoor workers, and those with pre-existing conditions like or . Heat stress is the leading cause of weather-related deaths worldwide, triggering conditions such as , heatstroke, and exacerbation of chronic illnesses, with cascading effects on emergency services, water supplies, and energy grids. In the U.S., heat waves account for more fatalities than all other weather disasters combined, including floods, tornadoes, and hurricanes. Beyond human health, they damage crops, harm livestock, disrupt ecosystems, and increase risks, leading to broader economic and environmental consequences. Climate change is intensifying heat waves, with making them more frequent, longer-lasting, and severe; human-induced is making heat waves more frequent and intense, with projections indicating further increases at 1.5°C and 2°C of above pre-industrial levels. Recent examples include , the warmest year on record globally, and ongoing extreme heat events in 2025. Since the mid-20th century, the number and duration of heat waves in the U.S. have increased, a trend projected to continue with rising . Concurrent events, such as heat waves combined with droughts, are also becoming more common, amplifying risks to and . strategies, including early warning systems and urban greening, are essential to mitigate these escalating threats.

Definition and Characteristics

Definition

A is a prolonged period of excessively hot relative to the normal conditions in a specific , often accompanied by high that exacerbates the perceived . This is distinguished from typical hot by its extended duration and intensity, generally lasting at least two consecutive days, during which maximum temperatures significantly exceed seasonal norms or established thresholds. Definitions of heat waves vary globally and locally to account for regional differences, with no universal standard adopted across all meteorological organizations. For instance, the currently describes a heatwave as a where local excess accumulates over a sequence of unusually hot days and nights. Previously, it used a threshold-based approach, such as a of more than five consecutive days during which the daily maximum surpasses the maximum by 5°C (9°F), or during which the daily minimum exceeds the minimum by 2°C (3.6°F). In contrast, the U.S. defines it more broadly as abnormally hot lasting more than two days, potentially with or without high , emphasizing discomfort and deviation from local expectations. These variations ensure that heat wave criteria reflect the unique vulnerabilities and baselines of different areas, such as urban versus rural settings or temperate versus tropical zones.

Criteria and Classification

Heat waves are quantitatively identified through temperature-based criteria that emphasize deviations from historical norms. A common scientific standard defines a as a period when daily maximum temperatures exceed the 90th of the local climatological distribution for at least three consecutive days, often calculated using a sliding window of 15 to 31 days centered on the calendar date to account for seasonal variability. This approach allows for location-specific thresholds, adapting to regional s rather than fixed absolute values. For instance, the U.S. (NWS) applies localized criteria, such as three or more consecutive days with high temperatures reaching 90°F (32°C) or above in much of the eastern and , reflecting historical patterns in those areas. Recent definitions increasingly incorporate nighttime temperatures, as sustained high minima prevent cooling and heighten health risks. Humidity plays a critical role in perceived heat stress, leading to adjusted criteria that incorporate factors beyond dry-bulb temperature. The apparent temperature, or heat index, combines air and relative to estimate how hot it feels to the , with heat waves sometimes defined by sustained values exceeding operational thresholds like 105°F (41°C) for multiple days under NWS guidelines. Similarly, the wet-bulb globe (WBGT) integrates , , wind speed, and solar radiation to assess physiological strain, particularly in occupational or contexts; thresholds above 30°C WBGT for prolonged periods signal high risk during heat events. These metrics enhance accuracy in humid environments where is limited, preventing underestimation of impacts. Classification of heat waves employs typologies based on intensity, duration, spatial extent, and seasonality to facilitate and comparison. is often graded as moderate (e.g., 90th to 95th exceedance) or severe (above the 95th or absolute extremes like 40°C), reflecting potential for escalating effects. categorizes events as short (3–5 days) or extended (over 7 days), with longer periods amplifying cumulative stress. Spatial extent distinguishes heat waves, intensified by and reduced in cities, from regional ones covering broader areas like entire states or countries. differentiates typical summer occurrences from anomalous off-season events, such as winter heat waves in subtropical zones. These classifications inform models for timely alerts. Regional standards vary to align with local baselines, ensuring relevance. In , thresholds are tailored by ; for example, the United Kingdom's defines a heat wave as three consecutive days with daily maxima exceeding 28°C in southern counties or 25°C in northern and western areas. In contrast, Australian criteria emphasize aridity and extremes, with the identifying s as three or more days of unusually high maximum and minimum temperatures relative to local norms, such as exceeding 35°C in southeastern cities like for three consecutive days. These examples highlight how classifications adapt to continental differences in climate and infrastructure.

Causes and Mechanisms

Meteorological Processes

Heat waves often form under the influence of persistent high-pressure systems, known as anticyclones, which dominate the upper atmosphere and create conditions conducive to extreme . These systems feature subsiding air that suppresses cloud formation and , allowing intense solar to reach unimpeded and leading to radiative warming. The anticyclonic circulation pattern diverts storms away, resulting in prolonged clear skies and dry conditions that trap near the ground, exacerbating surface temperatures over days or weeks. In mid-latitudes, such ridges in the 500-hPa geopotential height field induce local surface high-pressure areas that promote warm, benign weather without cooling influences from fronts or rainfall. A key amplifying mechanism involves feedback, particularly in regions experiencing antecedent . Low reduces —the process by which plants and release water vapor into the atmosphere—shifting energy partitioning toward flux that warms the air directly. This creates a loop: drier soils lead to less evaporative cooling, higher near-surface temperatures, and further soil drying, intensifying conditions especially in transitional climate zones like mid-latitude summers. For instance, during prolonged dry spells, this vicious cycle can elevate maximum temperatures by enhancing atmospheric depth and reducing loss. Atmospheric circulation patterns, such as those involving the , play a crucial role in the stagnation of masses. A blocked or wavy —characterized by amplified Rossby waves—diverts the typical west-to-east flow, creating high-pressure blocks that prevent the of cooler air into affected regions. These meandering patterns allow heat domes to persist, as weather systems become stationary and hot continental air remains trapped for extended periods. Without the 's steering influence, such configurations can sustain heat waves across large areas, from to . Locally, the urban heat island (UHI) effect intensifies heat waves through modifications to the surface energy balance. Urban materials like and absorb solar radiation during the day and re-radiate it as longwave infrared at night, reducing cooling and elevating nighttime temperatures by 1–3°C (2–5°F) compared to rural surroundings. This effect is amplified during heat waves, as reduced vegetation limits and wind flow in built environments traps heat, creating synergistic interactions that make urban areas disproportionately hotter. Studies indicate that UHI can increase peak heat wave intensities by enhancing both daytime and nocturnal warming in densely developed zones. These meteorological processes can be further exacerbated by broader climate trends that favor more frequent persistent patterns.

Role of Climate Change

Anthropogenic climate change has significantly intensified the frequency, duration, and severity of heat waves globally. According to the Intergovernmental Panel on Climate Change (IPCC) Sixth Assessment Report (AR6), there is high confidence that the frequency and intensity of hot extremes, including heat waves, have increased since the pre-industrial period, with observed trends showing substantial increases in frequency and intensity in many regions since the pre-industrial period, with high confidence that human influence has contributed to these changes. This escalation is evident in datasets spanning from the mid-20th century onward, where heat waves that were once rare have become more commonplace due to rising global temperatures. Recent observations, including 2024 as the warmest year on record at approximately 1.55°C above pre-industrial levels (as of 2025), continue to show escalating heat wave trends consistent with IPCC projections. The primary mechanisms linking to heat waves involve a shift in baseline temperatures and alterations in patterns. As global mean surface temperatures rise from , the overall warmer climate elevates the threshold for what constitutes an extreme heat event, making intense heat waves more probable even under similar meteorological conditions. Additionally, —where the Arctic region warms at a rate several times faster than the global average—disrupts polar patterns, potentially leading to more persistent high-pressure systems that trap heat over mid-latitude regions. These changes amplify the likelihood of prolonged heat domes and stagnant air masses conducive to heat waves. Projections indicate further escalation under various emissions scenarios. The IPCC AR6 outlines that, in high-emissions pathways such as Shared Socioeconomic Pathway (SSP) 5-8.5 (comparable to (RCP) 8.5), heat waves are projected to become substantially more frequent, with increases of 15-30 times or more for rare events by the end of the century compared to the late , with substantial increases in and across most land areas. Even under lower-emissions scenarios like SSP1-2.6 (comparable to RCP 2.6), heat extremes are expected to rise, though at a moderated rate, underscoring the benefits of mitigation efforts. Event attribution studies provide concrete evidence of human influence on specific heat waves. For instance, the 2021 heat dome, which saw temperatures exceed 49°C in parts of and the , was analyzed by the initiative and found to be virtually impossible without anthropogenic , with human warming making such an event at least 150 times more likely. These rapid attribution analyses, using climate models and observational data, consistently link recent to the enhanced , highlighting the role of cumulative emissions in exacerbating their probability and severity.

Impacts and Effects

Human Health Effects

Heat waves pose significant risks to human health by inducing heat stress, which disrupts the body's and can lead to a range of acute and chronic conditions. Direct physiological impacts include heat-related illnesses such as , characterized by symptoms like heavy sweating, weakness, dizziness, , and due to and imbalances, and , a life-threatening condition where core body temperature exceeds 40°C, often resulting in , seizures, organ failure, and death if untreated. Certain populations are disproportionately vulnerable to these effects owing to physiological, socioeconomic, or environmental factors. The elderly face heightened risks because of diminished thermoregulatory capacity and higher prevalence of comorbidities like ; children and infants are susceptible due to underdeveloped cooling mechanisms and higher metabolic rates; outdoor workers experience prolonged exposure leading to and ; and individuals with pre-existing conditions, such as respiratory or diabetes-related illnesses, suffer exacerbated symptoms during heat exposure. Mortality from heat waves is substantial, with studies estimating approximately 489,000 heat-related deaths annually worldwide between 2000 and 2019, accounting for a notable portion of summer mortality in affected regions. A prominent example is the 2003 European heat wave, which caused over 70,000 excess deaths, primarily among the elderly. In 2025, heat waves across the contributed to increased heat-related illnesses and strained emergency services. Indirect effects further compound these risks, as heat waves can degrade air quality by promoting formation, thereby worsening respiratory conditions like and . Additionally, extreme heat contributes to strain, aggravating conditions such as anxiety and through disrupted sleep and increased physiological stress.

Environmental and Ecological Effects

Heat waves exert profound pressures on terrestrial ecosystems, exacerbating conditions that lead to widespread stress and mortality. Prolonged high temperatures combined with reduced diminish , causing hydraulic failure in trees and resulting in large-scale die-offs, particularly in boreal forests where like lodgepole have experienced significant mortality during extreme events. These conditions also heighten the risk of fires by drying out fuels such as dead and , with climate-driven heat waves contributing to longer seasons and increased burned area across regions like the , where extent has doubled in recent decades. In aquatic environments, heat waves induce that disrupts and suitability, often resulting in mass mortality events. Elevated temperatures in rivers and lakes act as , lowering dissolved oxygen levels and triggering fish kills, as observed in U.S. waterways where river heat waves are intensifying up to four times faster than atmospheric ones, threatening cold-water species like . Marine heat waves similarly cause by expelling symbiotic algae from reef-building corals, leading to ; for instance, the 2014-2017 global event affected over 70% of coral reefs worldwide with bleaching-level heat stress, with cascading effects on marine biodiversity. Biodiversity faces accelerated decline during heat waves, as many exceed their thermal tolerances, prompting range shifts and heightened risks. Heat-sensitive taxa, such as amphibians, suffer from and disrupted , contributing to population crashes; IPCC models project that at 3°C of warming, up to 20% of in biodiversity hotspots could face very high risk. These events also alter interactions, favoring heat-tolerant invaders over natives and reducing overall resilience. Heat waves disrupt and cycles by accelerating and altering hydrological patterns, fostering in arid and semi-arid regions. Increased from hotter depletes reserves and promotes , as seen in where heat-induced has expanded desertified areas by enhancing and reducing vegetation cover. Such changes constrain nutrient cycling and , with implications extending to through and reduced retention.

Economic and Societal Effects

Heat waves impose substantial direct economic costs, primarily through heightened energy demands for cooling and agricultural yield reductions. During , electricity consumption can surge by 10-25% as households and businesses increase use, straining power grids and elevating utility bills. In the agricultural sector, heat waves trigger crop failures, particularly in grains like and , with yield losses reaching up to 20% in vulnerable regions during prolonged exposure. Indirect costs further compound these burdens, including declines in labor productivity and damage to . Heat stress reduces worker efficiency, leading to estimated GDP losses of 2-4% in heavily affected areas through diminished output in sectors like and . Infrastructure vulnerabilities manifest as rail track buckling from , causing delays and repairs, and power grid overloads that result in widespread outages. Societally, heat waves exacerbate inequalities and disrupt community life. Low-income households, where up to 17% lack access to compared to 8% in higher-income groups, face amplified risks, widening socioeconomic divides during heat events. This vulnerability contributes to patterns of from increasingly uninhabitable hot regions, as extreme heat displaces populations and alters dynamics. Additionally, cultural and public events, such as outdoor festivals and concerts, are frequently canceled due to health risks and logistical challenges, impacting local economies and social cohesion. Globally, the economic toll of heat waves is projected to escalate, with annual losses potentially reaching $200 billion by 2030 and $500 billion by 2050, driven by productivity declines and disruptions; these figures include indirect health-related expenses as a key component.

Measurement and Monitoring

Heat Indices and Metrics

The (HI), developed by the , quantifies the perceived temperature by combining air temperature and relative to reflect how hot it feels to the . It is calculated using the following equation, where T is the air temperature in degrees and RH is the relative humidity in percent: HI = -42.379 + 2.04901523T + 10.14333127RH - 0.22475541T \cdot RH - 0.00683783T^2 - 0.05481717RH^2 + 0.00122874T^2 \cdot RH + 0.00085282T \cdot RH^2 - 0.00000199T^2 \cdot RH^2 For conditions where RH < 13\% and $80^\circ \mathrm{F} \leq T \leq 112^\circ \mathrm{F}, an adjustment is applied: \mathrm{ADJUSTMENT} = \frac{13 - RH}{4} \sqrt{\frac{17 - |T - 95|}{17}}, and HI = HI + \mathrm{ADJUSTMENT}. This metric assumes shaded conditions with light winds and is widely used to assess heat stress risk in real-time. Wet-bulb temperature measures the lowest temperature achievable by evaporating water into the air, serving as a direct indicator of heat stress potential since it accounts for both temperature and humidity's impact on human cooling via sweat evaporation. It is typically measured using a psychrometer, which consists of two thermometers: a dry-bulb for air temperature and a wet-bulb covered in a moist wick, with the temperature difference used to compute relative humidity and wet-bulb values. A wet-bulb temperature of 35°C represents a critical physiological threshold beyond which even healthy humans cannot cool effectively through perspiration, leading to inevitable heat stroke after prolonged exposure, even in shade with unlimited water. Other metrics for quantifying heat wave intensity include the excess heat factor (EHF), which integrates both the magnitude and duration of excess heat relative to local over a three-day period to provide a -based score of severity. The EHF combines two components: the average excess heat during the event compared to the 75th of historical daily mean temperatures, and the rarity of that excess relative to long-term distributions. Additionally, (UHI) intensity ratios capture how urban environments amplify heat waves, often defined as the ratio of temperature differences between urban and rural areas during events compared to non-heat wave periods, highlighting exacerbated risks in cities where UHI can increase nighttime temperatures by 2–5°C or more. These metrics have limitations, including the need for regional calibration to account for varying , , and climate baselines, as formulas like the are primarily tuned for mid-latitude conditions. They also tend to underestimate risks in direct sunlight or with low wind speeds, where radiant and stagnant air exacerbate beyond shaded assumptions. For wet-bulb measurements, psychrometer accuracy can be affected by rates, and the 35°C threshold may vary slightly by age, health, and activity level.

Forecasting and Early Warning Systems

Forecasting heat waves relies on (NWP) models that integrate atmospheric data to predict temperature anomalies and prolonged high-pressure systems. The European Centre for Medium-Range Weather Forecasts (ECMWF) Integrated Forecasting System (IFS) provides deterministic and ensemble forecasts up to 15 days ahead, enabling subseasonal predictions of heat wave onset with lead times of 1-10 days by simulating land-atmosphere interactions and synoptic patterns. Similarly, the U.S. National Oceanic and Atmospheric Administration's (GFS) generates global forecasts extending to 16 days, four times daily, incorporating high-resolution data for medium-range heat wave guidance that informs national and international alert systems. These models often outperform each other in specific regions; for instance, ECMWF demonstrates superior skill in capturing tropical influences on mid-latitude heat waves at 5-15 day leads compared to GFS. Early warning frameworks coordinate these forecasts with responses to mitigate impacts. The (WHO) promotes heat-health action plans (HHAPs) that establish multi-sectoral strategies, including trigger-based s tied to forecast thresholds like values exceeding local norms, to activate cooling centers and vulnerable population outreach. In , the MeteoAlarm system aggregates national forecasts into a harmonized color-coded network across 38 countries, where yellow signals potential risks requiring vigilance, orange indicates dangerous conditions likely causing disruptions, and red warns of extreme threats with widespread damage and health risks. These frameworks emphasize timely dissemination via media and apps, integrating NWP outputs to provide 3-7 day advance notices for coordinated responses. Technological advancements enhance prediction accuracy, particularly for localized events. Satellite observations, such as those from NASA's Soil Moisture Active Passive (SMAP) mission, supply real-time surface soil moisture data that models assimilate to improve heat wave forecasts by accounting for land-atmosphere feedbacks, where dry soils amplify temperature extremes up to 14 days ahead. In urban areas, artificial intelligence (AI) augments nowcasting—short-term predictions from 0-6 hours—by analyzing satellite imagery, weather station data, and urban canopy models to detect emerging heat islands and issue hyper-local alerts for hotspots. For example, AI-driven tools like those developed by Google Research process aerial and satellite data to map surface urban heat at fine scales, enabling rapid nowcasts that guide city-level interventions during ongoing events. The effectiveness of these systems is evident in reduced health burdens, particularly in regions with established programs. In , case studies from and demonstrate that heat alert and response systems (HARS), implemented post-2009 heat waves, lowered heat-related mortality during subsequent events; for instance, 's HARS correlated with decreased all-cause mortality risks under extreme heat conditions compared to pre-implementation periods. In , the heatwave warning program was linked to a 2.9% reduction in emergency department visits and a 4.7% drop in ambulance call-outs during comparable 2014 events versus 2009, suggesting broader mortality benefits through behavioral adaptations. Globally, WHO estimates that scaling heat-health warning systems could avert up to 100,000 annual deaths in vulnerable countries, with Australian examples highlighting 20-50% potential reductions in attributable to timely alerts and action plans.

Historical and Regional Examples

Major Historical Events

One of the most devastating heat waves in modern history occurred in during the summer of , affecting much of the from to and lasting from early June to mid-August. This event resulted in approximately 70,000 excess deaths, primarily among the elderly and those with pre-existing health conditions, due to the prolonged high temperatures and poor air quality. Peak temperatures reached up to 45°C in parts of , exacerbating the impacts. The heat wave was linked to an early and severe that reduced and amplified the intensity of the heat, leading to widespread crop failures and water shortages. In 2010, western experienced an extreme from late June to mid-August, characterized by record-breaking temperatures and accompanied by severe and wildfires. The event caused an estimated 55,000 excess deaths, with significant mortality in urban areas like due to heat stress and respiratory issues from . Wildfires burned more than 15 million hectares of and vegetative land, releasing massive amounts of and contributing to levels that rivaled those of major industrial emissions. The economic toll was substantial, with losses exceeding $15 billion from agricultural devastation, damage, and reduced industrial output during the Great Depression-era conditions. The 2021 , which engulfed parts of and the from late to early , set numerous and highlighted the growing intensity of such events. In British Columbia's Lytton village, temperatures peaked at 49.6°C on June 29, establishing Canada's all-time high and occurring just hours before a destroyed much of the town. The led to over 600 heat-related deaths across the region, including more than 400 in and over 250 in the U.S., straining healthcare systems and causing widespread power outages. In 2023, a severe heat wave affected much of Europe during July and August, resulting in an estimated 47,690 heat-related excess deaths across 35 countries. This event, the second highest mortality burden from heat in the region since records began, featured temperatures exceeding 40°C in several countries, particularly in southern and western Europe, and was made more likely and intense by human-induced climate change. Earlier in the 20th century, the 1936 North American heat wave, occurring amid the Dust Bowl drought, intensified the hardships of the Great Depression across the central and eastern United States from June to September. This prolonged event, with temperatures often exceeding 40°C in the Midwest and Plains states, contributed to nearly 5,000 heat-related deaths, many among vulnerable rural populations without access to cooling or adequate hydration. The heat exacerbated dust storms and crop losses, displacing thousands of farmers and deepening economic distress by destroying agricultural yields essential for recovery efforts during the Depression. These historical events underscore a trend where human-induced climate change has made extreme heat more frequent and intense.

Regional Variations and Case Studies

Heat waves exhibit distinct regional variations influenced by local climate patterns, geography, and atmospheric dynamics. In temperate mid-latitude regions, such as the U.S. Midwest, heat waves are typically shorter in duration but more intense, often resulting from rapid shifts in weather systems that bring sudden spikes in temperature. In contrast, subtropical and tropical areas like experience more prolonged heat waves due to persistent high-pressure systems and seasonal monsoonal influences, leading to extended periods of elevated temperatures that exacerbate and heat stress. These differences highlight how tropical regions face amplified risks from lengthening summer heat events compared to temperate zones. A prominent case study is the 2015 heat wave in India, which struck during May and early June, with temperatures exceeding 45°C in several states. This event resulted in over 2,300 deaths, primarily from heatstroke and dehydration, underscoring its severity in a subtropical context. Rural-urban disparities were evident, as most fatalities occurred in rural southern areas like Andhra Pradesh and Telangana, where limited access to cooling infrastructure and reliance on outdoor labor heightened vulnerability, compared to urban centers with better resources. In , the 2019 heat wave served as a precursor to the devastating bushfires of 2019–2020. Late December 2019 saw record-breaking national average maximum temperatures of 41.9°C, driven by a prolonged high-pressure system that dried vegetation and intensified fire risks across southeastern regions. This extreme heat contributed to the unprecedented scale of the subsequent wildfires, which burned over 18 million hectares and highlighted the interplay between heat waves and fire-prone subtropical environments. Polar amplification, where the warms at more than twice the global average rate, has led to emerging heat waves in high-latitude regions. The 2020 Siberian heat wave exemplifies this, with temperatures reaching a record 38°C in in —nearly impossible without human-induced —and contributing to widespread wildfires and thaw. Such events demonstrate how amplified warming in polar areas is producing unprecedented heat extremes far beyond historical norms. Developing countries in and face higher vulnerability to heat waves than developed nations due to limited , such as inadequate cooling systems and healthcare access, which amplify mortality risks. For instance, between 1990 and 2019, nearly 49% of global heat wave-related deaths occurred in and over 13% in , reflecting socioeconomic factors that exacerbate exposure in these regions. In contrast, developed countries benefit from better adaptation measures, reducing impacts despite similar climatic exposures.

Mitigation and Adaptation Strategies

Public Health and Emergency Measures

Public health measures during heat waves focus on immediate interventions to reduce mortality and morbidity from conditions such as and , which disproportionately affect vulnerable groups like the elderly and those with chronic illnesses. These strategies include establishing cooling centers and hydration campaigns to provide accessible relief from extreme temperatures. In the United States, the (FEMA) recommends opening cooling centers in public buildings like libraries and community centers during heat alerts, ensuring they are equipped with and accessible to low-income residents. Hydration campaigns, often coordinated by local health departments, involve distributing at high-risk locations and promoting public awareness through media alerts to encourage fluid intake and avoid strenuous activity. Outreach to vulnerable populations is a cornerstone of these responses, targeting groups such as the elderly, children, and outdoor workers. Community programs conduct welfare check-ins for seniors, including phone calls or home visits to assess hydration status and cooling access, as emphasized in guidelines from the Centers for Disease Control and Prevention (CDC). Schools may implement early closures or shift to virtual learning during prolonged heat events to protect students from overheating in inadequately cooled facilities, with U.S. districts reporting an average of six to seven closure days annually due to extreme heat. For workplaces, the Occupational Safety and Health Administration (OSHA) recommends and has proposed standards requiring employers to provide water, rest breaks, and periods when the exceeds 80°F (27°C), particularly in high-risk sectors like and ; as of 2025, federal enforcement relies on the General Duty Clause, while some states have specific regulations. In 2025, several U.S. states enacted new laws enhancing occupational heat protections, building on federal proposals. Internationally, the UNEP's Sustainable Cooling Pathway highlights efficient technologies to mitigate heat risks while reducing emissions. Emergency protocols are activated to manage surges in heat-related cases, prioritizing rapid response and healthcare capacity. Hospitals increase surge capacity by reserving beds for heat illnesses, expanding staffing, and coordinating with cooling centers to divert non-critical cases, as outlined in national preparedness exercises. Ambulance services prioritize calls for , a life-threatening condition involving core body temperatures above 104°F (40°C), by dispatching units equipped for on-scene cooling and transport to specialized facilities. Internationally, implemented reforms following the deadly 2003 heat wave, which caused approximately 15,000 excess deaths, by establishing a national Heat Health Watch Warning System in 2004 that mandates daily reporting of heat-related mortality and morbidity to enable timely alerts and resource allocation. This system has significantly reduced heat-attributable deaths through coordinated actions, serving as a model for mandatory surveillance in other countries.

Urban Design and Infrastructure Adaptations

Urban design and infrastructure adaptations play a crucial role in mitigating the impacts of heat waves by modifying the to reduce effects and enhance thermal resilience. , such as widespread and green roofs, provides shading, , and insulation that can lower ambient urban temperatures by 2–5°C in vegetated areas. For instance, the U.S. Agency notes that trees and deflect radiation and release into the air, thereby cooling surfaces and surrounding atmospheres during . Green roofs, in particular, can reduce rooftop surface temperatures by up to 31°C compared to conventional roofs, while also moderating nearby air temperatures through enhanced . Singapore's "Garden City" model exemplifies this approach, integrating extensive urban greening— including vertical gardens and park connectors—to counteract the effect in a densely built tropical , thereby lowering overall temperatures and improving livability. Building standards incorporating designs further bolster heat wave resilience by minimizing reliance on mechanical systems and reducing indoor heat buildup. Techniques such as strategic building orientation, high-performance insulation, and solar-control window films enable homes to maintain cooler interiors without active energy use, with studies showing these measures can keep indoor temperatures 5–10°C below outdoor peaks during heat events, particularly in vulnerable pre-1978 structures. Reflective materials, including cool roofs coated with high reflectance, absorb less and can lower temperatures by 20–30°C, thereby decreasing cooling loads and urban heat contributions. Mandates for energy-efficient in new constructions, combined with passive strategies, ensure buildings remain habitable during prolonged s while aligning with broader goals. Policy frameworks at the city level drive these adaptations through coordinated initiatives aimed at creating heat-resilient urban landscapes. The C40 Cities network, comprising major global metropolises, supports 21 member cities in prioritizing mitigation via expansions, with plans to replace heat-absorbing hard surfaces like with and wetlands, potentially reducing local temperatures by up to 5°C. These efforts align with broader commitments to enhance by 2030, emphasizing equitable access to cooler public spaces and integrated . Transportation adaptations are essential to prevent disruptions from heat-induced expansions and deformations. systems, prone to "heat kinks" where tracks buckle under , benefit from heat-proofing measures such as low-expansion materials and real-time monitoring, as demonstrated in assessments by the that reduced failure risks during extreme heat. Roadways and bridges incorporate heat-resistant mixes and expansion joints to mitigate and rutting, extending lifespan amid rising temperatures. For public transit, providing shaded or cooled waiting areas at stops improves passenger in hot climates, with research indicating that such designs can lower perceived heat stress by facilitating better and reducing direct exposure. These modifications not only maintain service continuity but also yield economic benefits by averting costly repairs and downtime from heat-related damages.

References

  1. [1]
    What Is a Heat Wave? | NESDIS - NOAA
    A heat wave is a period of unusually hot weather that typically lasts two or more days. To be considered a heat wave, the temperatures have to be outside ...
  2. [2]
    Climate Change Indicators: Heat Waves | US EPA
    Prolonged exposure to excessive heat can lead to other impacts as well—for example, damaging crops, injuring or killing livestock, and increasing the risk of ...
  3. [3]
    Adapting to Heat | US EPA
    Mar 19, 2025 · People living in cities are at a higher risk from the impacts of heat waves because urban areas are already warmer than surrounding non-urban ...
  4. [4]
    Heat and health - World Health Organization (WHO)
    May 28, 2024 · Heat stress is the leading cause of weather-related deaths and can exacerbate underlying illnesses including cardiovascular disease, diabetes, ...Heat-health action plans · Biodiversity · El Niño Southern Oscillation
  5. [5]
    Climate change widespread, rapid, and intensifying – IPCC
    Aug 9, 2021 · For 1.5°C of global warming, there will be increasing heat waves, longer warm seasons and shorter cold seasons. At 2°C of global warming, heat ...
  6. [6]
    Chapter 11: Weather and Climate Extreme Events in a Changing ...
    Concurrent heatwaves and droughts have become more frequent, and this trend will continue with higher global warming (high confidence).
  7. [7]
    Heatwaves and health: guidance on warning-system development
    Jun 30, 2016 · The impacts of heatwaves can be great and sometimes catastrophic, as manifested by the large number of heat-related deaths recorded across ...
  8. [8]
    Heatwave - World Meteorological Organization WMO
    A heatwave can be defined as a period where local excess heat accumulates over a sequence of unusually hot days and nights. Heatwaves amplify many risks, ...
  9. [9]
    During a Heat Wave - National Weather Service
    A heat wave is a period of abnormally hot weather generally lasting more than two days. Heat waves can occur with or without high humidity.
  10. [10]
    https://www.weather.gov/safety/heat-during
  11. [11]
    [PDF] EXTREME HEAT/HEAT WAVE - IFRC
    The World Meteorological Organization (WMO) defines a heat wave as a period during which the daily maximum temperature exceeds for more than five consecutive ...
  12. [12]
    Magnitude of extreme heat waves in present climate and their ...
    Oct 24, 2014 · The threshold is defined as the 90th percentile of daily maxima, centered on a 31 day window. Hence, for a given day d, the threshold is the ...
  13. [13]
    On the Measurement of Heat Waves in - AMS Journals
    The three heat wave definitions are employed as described below: CTX90pct—The threshold is the calendar day 90th percentile of Tmax, based on a 15-day window.Missing: maxima | Show results with:maxima
  14. [14]
    [PDF] Longest Heat Waves – Consecutive 90 Degrees + Days (1869 to ...
    Longest Heat Waves – Consecutive 90 Degrees + Days (1869 to Present). A heat wave is defined as 3 or more consecutive 90 Degree + Days.
  15. [15]
    Understanding Heat Alerts - National Weather Service
    A Heat Advisory is issued for dangerous heat conditions that are not expected to reach warning criteria. Consider postponing or rescheduling outdoor activities, ...
  16. [16]
    Climatology of Wet-Bulb Globe Temperature and Associated Heat ...
    This study shows that heat wave days based on minimum WBGT have increased significantly which could have important impacts on human heat stress recovery.
  17. [17]
    Heatwave (MH0501) - UNDRR
    A heatwave is a marked, unusual period of hot weather over a region persisting for at least two or three consecutive days and nights during the hot period ...
  18. [18]
    Increasing Intensity of Extreme Heatwaves: The Crucial Role of Metrics
    Jul 13, 2023 · In the climate science community heatwaves are characterized through measures of their intensity, maximum amplitude, duration, frequency and ...
  19. [19]
    Heat and cold wave intensity and spatial extent on the Iberian ...
    May 9, 2025 · Both heat and cold waves can be characterized by considering four dimensions: intensity, duration, frequency, and spatial extent (Raei et al.
  20. [20]
    Heatwaves – a brief introduction - Copernicus Climate Change
    Jul 18, 2024 · A heatwave is a prolonged period of much-warmer-than-average weather. A heatwave would typically last for several days to a few weeks.
  21. [21]
    How does climate change affect heatwaves?
    Aug 3, 2023 · In Adelaide, Australia, a heatwave is defined as five consecutive days at or above 35°C or three consecutive days at or above 40°C. In ...Missing: criteria | Show results with:criteria
  22. [22]
    Did You Know? | Subtropical Highs
    Its descending air inhibits precipitation and its anticyclonic circulation pattern deflects tropical storms and hurricanes to the south and weakens cold fronts ...
  23. [23]
    High and low pressure - Met Office
    In general, low pressure leads to unsettled weather conditions and high pressure leads to settled weather conditions. Anticyclone (high pressure). In an ...Weather conditions · Blocking patterns · Wind flowMissing: heat waves
  24. [24]
    [PDF] Climatology of Tracked Persistent Maxima of 500-hPa Geopotential ...
    For example, a Z500 maximum indicating a ridge or an anticyclone induces a local surface high pressure system that generally causes benign, dry and warm ...
  25. [25]
    [PDF] Characterizing the Relationship between Temperature and Soil ...
    Dry soil leads to stronger sensible heat and reduced latent heat flux, which leads to a deeper boundary layer that enhances the feedback loop and leads to heat- ...
  26. [26]
    [PDF] Land–atmosphere feedbacks exacerbate concurrent soil drought ...
    Sep 3, 2019 · Reduced evapotranspiration de- creases moisture recycling and increased sensible heat, in some cases, may further enhance atmospheric ...
  27. [27]
    [PDF] The Influence of Drought on Heat Wave Intensity, Duration, and ...
    May 16, 2025 · The feedback loops where droughts can increase air tem- perature (drier soils leading to reduced evaporation) and heat waves reduce moisture ...
  28. [28]
    Summer heat wave arrives in Europe | NOAA Climate.gov
    Jul 14, 2015 · The jet stream, an area of fast moving winds high up in the atmosphere (four to eight miles), became incredibly wavy during the heat wave, ...
  29. [29]
    Basic Wave Patterns - NOAA
    May 18, 2023 · Blocking patterns occurs when centers of high pressure and/or low pressure set up over a region in such a way that they prevent other weather ...Missing: wavy | Show results with:wavy
  30. [30]
    What Is the Jet Stream? | NESDIS - NOAA
    However, if a weather system is far away from a jet stream, it might stay in one place, causing heat waves or floods.Missing: blocked wavy
  31. [31]
    [PDF] Compendium of Strategies - Urban Heat Island Basics
    Urban heat islands are caused by development and the changes in radiative and thermal properties of urban infrastructure as well as the impacts buildings can ...
  32. [32]
    [PDF] Heatwaves and urban heat islands - the NOAA Institutional Repository
    Recent research has shown that heat waves have the potential to amplify UHI [Li and Bou-Zeid, 2013; Ramamurthy et al., 2015], which will bear adverse ...
  33. [33]
    [PDF] Interactions between urban heat islands and heat waves
    Feb 16, 2018 · The risks of heatwaves are amplified by urban heat islands (UHI) (Patz et al 2005, Tan et al 2010)—a phenomenon of higher temperatures in urban ...
  34. [34]
    Arctic amplification of climate change: a review of underlying ...
    Sep 2, 2021 · The Planck response is the most fundamental mechanism acting to stabilize the climate, since surface and tropospheric warming will increase the ...
  35. [35]
    Arctic warming favours weather extremes
    European weather extremes like summer heat waves and winter cold spells could be caused by Arctic warming.
  36. [36]
    [PDF] Weather and Climate Extreme Events in a Changing Climate - IPCC
    Pinto, M. Satoh, S.M. Vicente-Serrano, M. Wehner, and B. Zhou, 2021: Weather and Climate Extreme. Events in a Changing Climate.
  37. [37]
    Projected changes in heatwaves over Central and South America ...
    Oct 4, 2024 · Heatwaves are projected to be more frequent, long-lasting, and intense in the mid-century under both RCP2.6 and RCP8.5 scenarios, with severe ...<|separator|>
  38. [38]
    Western North American extreme heat virtually impossible without ...
    Jul 7, 2021 · An event such as the Pacific Northwest 2021 heatwave is still rare or extremely rare in today's climate, yet would be virtually impossible without human-caused ...
  39. [39]
    Rapid attribution analysis of the extraordinary heat wave on ... - ESD
    Dec 8, 2022 · In this study, the influence of human-induced climate change on the intensity and probability of the Pacific Northwest heat wave of 2021 was ...
  40. [40]
    Heat-related Illnesses - CDC
    Sep 10, 2024 · When heat stroke occurs, the body temperature can rise to 106°F ... Symptoms of heat stroke include: Confusion, altered mental status ...Heat · Workplace Recommendations · Communication Resources
  41. [41]
    Heat Stroke - StatPearls - NCBI Bookshelf - NIH
    Heat stroke is a clinical constellation of symptoms that include a severe elevation in body temperature, typically, but not always, greater than 40°C. Also ...
  42. [42]
    People at Increased Risk for Heat-Related Illness - CDC
    Feb 20, 2024 · People who work outdoors are more likely to become dehydrated and get heat-related illness. Take steps to protect your health during extreme ...
  43. [43]
    Heatwaves - World Health Organization (WHO)
    Heatwaves can burden health and emergency services and also increase strain on water, energy and transportation resulting in power shortages or even blackouts.
  44. [44]
    Climate Change Impacts on Air Quality | US EPA
    Aug 11, 2025 · Climate change is expected to worsen harmful ground-level ozone, increase people's exposure to allergens like pollen, and contribute to worsening air quality.Missing: waves exacerbation
  45. [45]
    The Effects of Climate Change - NASA Science
    Oct 23, 2024 · Extreme heat will affect health, energy, agriculture, and more. Decreased water availability will have economic and environmental impacts.
  46. [46]
    Wildfire climate connection - NOAA
    Climate change, including increased heat, extended drought, and a thirsty atmosphere, has been a key driver in increasing the risk and extent of wildfires.Missing: vegetation die-
  47. [47]
    Heatwaves in US rivers increasing up to four times faster than air ...
    Sep 22, 2025 · Rivers in the U.S. are warming and suffering heatwaves at 2–4x the rate of air heatwaves, threatening aquatic ecosystems, water quality, ...
  48. [48]
    In hot water: exploring marine heatwaves - NOAA Research
    May 22, 2024 · Marine heatwaves stress marine life, leading to mass die-offs of fish, marine mammals, and seabirds, and coral bleaching. They can also trigger ...
  49. [49]
    [PDF] Fact sheet - Biodiversity | IPCC
    The risk of species extinction increases with warming in all climate change ... high extinction risk in biodiversity hotspots due to climate change is ...Missing: heat waves
  50. [50]
    With Temperatures Rising, Can Animals Survive the Heat Stress?
    Mar 19, 2020 · Warmer temperatures are already causing major damage to the world's forests. As temperatures warm, trees become less resilient and die-offs ...Missing: vegetation | Show results with:vegetation
  51. [51]
    Chapter 3 : Desertification
    Increasing water use to compensate for higher evapotranspiration due to rising temperatures and heat waves could increase soil erosion by water in the ...
  52. [52]
    [PDF] 4 - Changes in Impacts of Climate Extremes: Human Systems and ...
    Heat waves can directly impact ecosystems by, for example, constraining carbon and nitrogen cycling and reducing water availability, with the result of ...
  53. [53]
    Electricity demand in the Eastern United States surged from heat wave
    Jun 27, 2025 · Electricity demand increased significantly due to a heat wave that affected most of the Eastern United States this week.
  54. [54]
    Staying cool without overheating the energy system – Analysis - IEA
    Jul 28, 2025 · During the early summer heat waves of 2025, France – where air conditioning ownership is low – recorded an evening electricity peak that was 25% ...
  55. [55]
    Midwest Heat Waves May Cook Crops—and Fry Harvests - NRDC
    Sep 12, 2022 · Extreme weather is affecting agriculture across the globe, with corn yields, for example, expected to decrease by more than 20 percent by 2070.
  56. [56]
    Heat and drought are quietly hurting crop yields
    May 6, 2025 · More frequent hot weather and droughts have dealt a significant blow to crop yields, especially for key grains like wheat, barley, and maize.
  57. [57]
    [PDF] The Economic Consequences of Climate Change | OECD
    level, almost half of the projected GDP loss of 2% can be attributed to the indirect effects on ... from heat-related mortality, including heat waves. To ...<|control11|><|separator|>
  58. [58]
    Articles Potential of shifting work hours for reducing heat-related loss ...
    ... GDP loss from 4·3% to 3·8%. The potential for reducing labour productivity ... The impact of heat waves on occurrence and severity of construction accidents.
  59. [59]
    Infrastructure Breaks Under Extreme Heat | Emerging Issues - BSR
    The infrastructure that society depends upon could buckle and even break as power lines, refrigeration units, roads, and rail lines simultaneously fail.
  60. [60]
    US heat wave exposes infrastructure, health vulnerabilities - CNN
    Jun 25, 2025 · Buckled roads. Broken bridges. Delayed trains. Strained power grids that led to dangerous outages. Cases of heat illness and canceled ...
  61. [61]
    Disparities in Access to Air Conditioning And Implications for Heat ...
    Aug 16, 2024 · In addition, 17% of households with lower incomes (annual household income of less than $25,000) say they lack air conditioning compared to 8% ...
  62. [62]
    [PDF] Extreme heat and migration - IOM Publications
    Extreme heat, due to climate change, displaces people, threatens habitability, and may force migration out of areas with very strong heat stress.
  63. [63]
    Extreme weather caused by climate change increasingly cancelling ...
    Aug 2, 2025 · More and more major cultural, social, business and arts events around the world are being disrupted or cancelled by extreme weather events ...
  64. [64]
    Are extreme temperatures threatening live music events? - BBC
    Dec 2, 2023 · It is not the first time that extreme heat has marred outdoor events in South America this year. In Chile, several acts paused their sets to ...
  65. [65]
    Extreme heat: The economic and social consequences for the US
    The economic costs of extreme heat are already huge.​​ The losses will increase as climate change worsens—to approximately $200 billion by 2030 and $500 billion ...
  66. [66]
    Extreme heat's hidden health and economic toll - DW
    Jul 2, 2025 · Heat-related economic loss is already costing the US about $100 billion a year. That figure is expected to reach $500 billion annually within 25 ...
  67. [67]
    Heat Index Equation - Weather Prediction Center (WPC) Home Page
    May 12, 2022 · HI = -42.379 + 2.04901523*T + 10.14333127*RH - .22475541*T*RH - . · ADJUSTMENT = [(13-RH)/4]*SQRT{[17-ABS(T-95.)]/17}. where ABS and SQRT are the ...
  68. [68]
    Wet-bulb temperature – from traditional psychrometers to a modern ...
    Wet-bulb temperature is the temperature a wet surface can be cooled to by evaporation, measured by a thermometer with a damp fabric. The difference from dry- ...
  69. [69]
    Evaluating the 35°C wet-bulb temperature adaptability threshold for ...
    A wet-bulb temperature of 35°C has been theorized to be the limit to human adaptability to extreme heat, a growing concern in the face of continued and ...Missing: psychrometers | Show results with:psychrometers
  70. [70]
    The Excess Heat Factor: A Metric for Heatwave Intensity and Its Use ...
    The EHF is a new measure of heatwave intensity, incorporating two ingredients. The first ingredient is a measure of how hot a three-day period (TDP) is with ...
  71. [71]
    Insights Into Urban Heat Island and Heat Waves Synergies ...
    Jul 3, 2024 · During heat waves, temperature differences between urban and rural areas (UHI intensity (UHII)) increase more at night in inland regions and ...
  72. [72]
    [PDF] The Heat Index "Equation" (or, More Than You Ever Wanted to Know ...
    Jul 1, 1990 · No true equation for the Heat Index exists. Heat Index values are derived from a collection of equations that comprise a model. This Technical ...
  73. [73]
    Medium-range forecasts | ECMWF
    Forecasts up to 15 days ahead Our medium-range forecasts consist of a single forecast (HRES) and our ensemble (ENS) which together give detailed information ...Missing: heat lead 1-10
  74. [74]
    Global Forecast System (GFS)
    The Global Forecast System (GFS) is a National Centers for Environmental Prediction (NCEP) weather forecast model that generates data for dozens of atmospheric ...Missing: heat ECMWF
  75. [75]
    MAPP Webinar Series: Extreme Heat and Health: Creating ...
    5. The MJO prediction skill of ECMWF IFS is superior to that of NCEP GFS because IFS better captures synoptic-scale variability at the lead time of 5 – 15 days.
  76. [76]
    Heat-health action plans: guidance
    Jan 1, 2008 · This guidance document results from the EuroHEAT project on improving public health responses to extreme weather/heat-waves, co-funded by WHO and the European ...
  77. [77]
    Europe | MeteoAlarm | Early Warnings for Europe
    MeteoAlarm is an Early Warning Dissemination System that visualises, aggregates, and accessibly provides awareness information from 38 European National ...Missing: color- | Show results with:color-
  78. [78]
    [PDF] Heat Preparedness through Early Warning Systems
    HHWS use climate and weather forecasts and predetermined trigger levels of heat stress to provide public advisory and initiate public health interventions.
  79. [79]
    Land data assimilation of satellite‐based surface soil moisture
    Oct 30, 2025 · The atmospheric predictions, which extend up to 14 days, are compared with predictions for which the land surface relies on a purely model-based ...
  80. [80]
    Using AI to battle extreme heat - IBM
    A system that can characterize surface urban heat islands and issue alerts about when and where extreme heat hotspots appear within a city.Missing: nowcasting | Show results with:nowcasting
  81. [81]
    How we're using AI to help cities tackle extreme heat
    Sep 4, 2024 · Google Research is applying AI to satellite and aerial imagery to build a Heat Resilience tool, helping cities understand how to reduce surface temperatures.
  82. [82]
    Temporal changes in temperature-related mortality in relation to the ...
    May 6, 2024 · The study indicated a decrease in heat-related mortality following the operation of HARS in Victoria under extreme heat and high-intensity heatwaves conditions.
  83. [83]
    Evaluation of a heat warning system in Adelaide, South Australia ...
    This study explored the effect of a heatwave warning programme on morbidity and mortality in Adelaide, South Australia, by comparing extreme events in 2009 and ...
  84. [84]
    Accelerating solutions on early warnings and extreme heat
    Sep 26, 2025 · According to WHO and WMO estimates, scaling up heat health warning systems in just 57 countries could save nearly 100,000 lives every year. This ...
  85. [85]
    Inter-seasonal connection of typical European heatwave patterns to ...
    Jan 21, 2023 · For example, the 2003 heatwave in Europe is estimated to have caused more than 70,000 deaths. Globally, 2% of working hours are lost due to ...
  86. [86]
    C1. The impact of the European 2003 heatwave - AR4 WGII Cross ...
    Maximum temperatures of 35 to 40°C were repeatedly recorded and peak temperatures climbed well above 40°C (André et al., 2004; Beniston and Díaz, 2004).
  87. [87]
    Heat Waves & Drought - Nature
    Apr 27, 2018 · Severe drought plagued Europe in 2003, amplifying heatwave conditions that killed more than 30,000 people. Assuming business as usual, such ...
  88. [88]
    Feeling the heat | Nature Climate Change
    Apr 27, 2018 · For instance, upwards of 30,000 and 55,000 people died from the 2003 and 2010 heatwaves, respectively. Increased energy demand, wildfires, ...
  89. [89]
    Russia counts environmental cost of wildfires - Nature
    Aug 12, 2010 · More than 300,000 hectares of forest, vegetation and peat land have burned since the fires began in June. Some of the worst-affected areas are ...Missing: paper | Show results with:paper
  90. [90]
    Russian heat wave 'had both manmade and natural causes'
    Feb 21, 2012 · These conditions caused an estimated 55,000 deaths, a 25% drop in annual crop production, and a total economic loss of more than $15 billion. ' ...
  91. [91]
    The 2021 western North America heat wave among the most ...
    May 4, 2022 · The Canadian town of Lytton broke local temperature records by 4.6°C, setting a national temperature record of 49.6°C (10). The temperatures ...
  92. [92]
    2021 Northwest Heat Dome: Causes, Impacts and Future Outlook
    According to this study, a heat dome of this magnitude is estimated to be 150 times more likely in today's climate than compared to the pre-industrial climate.Missing: attribution | Show results with:attribution
  93. [93]
    [PDF] Heat Wave - NOAA Central Library
    These were cruel years in terms of heat deaths. From 1930 through 1936, ranging from a low of. 678 deaths in 1932 to 4,768 in 1936, heat killed nearly 15,000 ...
  94. [94]
    Heatwave of July 1936 - National Weather Service
    The "Dust Bowl" years of 1930-36 brought some of the hottest summers on record to the United States, especially across the Plains, Upper Midwest and Great Lake ...
  95. [95]
    Changes in regional heatwave characteristics as a function of ...
    Sep 25, 2017 · This study investigates how different regional heatwave characteristics (intensity, frequency and duration) are projected to change relative to increasing ...Cmip5 Global Median Changes... · Cmip5 Regional Median... · Discussion And Conclusion
  96. [96]
    Duration of heat waves accelerating faster than global warming
    Jul 8, 2025 · Tropical regions will see larger changes than temperate regions, and summer heat waves will lengthen more than winter warm spells.
  97. [97]
    Understanding the synergy between heat waves and the built ...
    Aug 2, 2024 · Heat waves and UHI share a synergistic relationship [5, 50]. Ambient temperatures in urban areas are intensified due to the combined effect of ...Missing: ratios | Show results with:ratios
  98. [98]
    India heat wave kills thousands | NOAA Climate.gov
    Jun 9, 2015 · The stifling heat has killed at least 2,300 people in India with most of the deaths located in the southeast states of Andhra Pradesh and ...
  99. [99]
    India heatwave kills more than 500 people - The Guardian
    May 25, 2015 · High of 47.7C recorded in northern city of Allahabad, with most recorded deaths due to heatstroke and dehydration in rural areas in south.
  100. [100]
    Australia heatwave: All-time temperature record broken again - BBC
    Dec 19, 2019 · The nation endured its hottest-ever day on Tuesday, but that record was smashed again on Wednesday - which saw an average maximum of 41.9C ( ...<|separator|>
  101. [101]
    Unveiling the Factors Responsible for Australia's Black Summer ...
    The summer season of 2019–2020 has been named Australia's Black Summer because of the large forest fires that burnt for months in southeast Australia, ...
  102. [102]
    Siberian heatwave of 2020 almost impossible without climate change
    Jul 15, 2020 · In the first six months of 2020, Siberia experienced a period of unusually high temperatures, including a record-breaking 38 degrees C in the town of ...
  103. [103]
    Siberia heatwave: why the Arctic is warming so much faster than the ...
    Jun 25, 2020 · The amplification can be between two and two and a half, meaning that for every degree of global warming, the Arctic will see double or more.
  104. [104]
    Global, regional, and national burden of heatwave-related mortality ...
    May 14, 2024 · Globally, there is no standard heatwave definition either in scientific research or in policy, but are defined based on temperature intensity ...
  105. [105]
    A scorching divide: How heatwaves expose inequality
    Jun 12, 2024 · The IPCC finds that countries in South and Southeast Asia are among the most vulnerable to climate change impacts. Being the most populated ...
  106. [106]
    [PDF] Mitigating the Risk of Extreme Temperatures with Hazard ... - FEMA
    This fact sheet identifies opportunities for hazard mitigation assistance, provides an overview of considerations and identifies other available FEMA resources.
  107. [107]
    Extreme Heat | Ready.gov
    Jul 10, 2025 · Extreme heat is a period of high heat and humidity with temperatures above 90 degrees for at least two to three days.
  108. [108]
    [PDF] The Use of Cooling Centers to Prevent Heat-Related Illness
    There are many tools and programs that can be used to protect the public from extreme heat, including adoption of a heat-alert system, use of real-time data and.
  109. [109]
    Extreme heat shuts schools for millions, widening learning gaps ...
    May 1, 2024 · U.S. schools are now cancelling class for an average of six to seven school days each year for heat, compared with about three to four days a ...
  110. [110]
    https://www.undp.org/blog/scorching-divide-how-heatwaves-expose-inequality
  111. [111]
    As Many American Cities Get Hotter, Health Systems Face Off ...
    Aug 7, 2023 · But to prepare for an influx of patients with heat-related illnesses, UMC has prioritized staffing of the emergency department, Elder said.
  112. [112]
    France takes steps to avoid repeat of deadly 2003 heat wave
    Jul 1, 2015 · France has adopted strict heat wave guidelines since the summer of 2003, when between 15,000 and 19,000 people died as a result of extreme ...
  113. [113]
    Evolving heat waves characteristics challenge heat warning systems ...
    Surveillance of meteorological characteristics and the impact of heat waves, particularly on the all-cause mortality, has been performed in France since 2004, ...
  114. [114]
    https://www.reuters.com/business/environment/extreme-heat-is-closing-schools-widening-learning-gaps-worldwide-2024-04-30/
  115. [115]
    Reduce Heat Islands | US EPA
    Apr 22, 2025 · The heat island effect increases energy costs (e.g., for air conditioning), air pollution levels, and heat-related illness and mortality.
  116. [116]
    Using Green Roofs to Reduce Heat Islands | US EPA
    Apr 2, 2025 · The surface temperature of green roofs can be 56°F lower than those of conventional roofs; and can reduce nearby air temperatures by up to 20°F.
  117. [117]
    [PDF] A SUSTAINABLE AND RESILIENT SINGAPORE
    Jul 7, 2018 · As a highly dense and urbanised country,. Singapore suffers from the Urban Heat Island (UHI) effect ... Singapore has to be innovative in becoming ...
  118. [118]
    [PDF] Passive cooling designs to improve heat resilience of homes in ...
    The study evaluates passive cooling measures, finding solar-control window films and roof insulation most effective for heat resilience, especially in pre-1978 ...
  119. [119]
    Cool Roofs | Department of Energy
    A cool roof is designed to reflect more sunlight than a conventional roof, absorbing less solar energy. This lowers the temperature of the building.
  120. [120]
    [PDF] Enhancing Resilience in Buildings Through Energy Efficiency
    Jul 27, 2023 · The idea that more energy-efficient buildings could keep occupants safer during power outages was a key element of a pilot credit on passive ...
  121. [121]
    Heat Extremes - C40 Cities
    The plan would see hard surfaces such as cement and asphalt on buildings, roads, and walkways, replaced with trees, grass, green roofs and urban wetlands. If ...
  122. [122]
    [PDF] Cool Cities - C40 Cities
    At C40, 21 cities have already prioritized heat as a major concern and are working collectively to address urban heat island effect and extreme heat events in ...
  123. [123]
    [PDF] An Integrated Approach to Climate Adaptation at the Chicago Transit ...
    Aug 31, 2013 · three different CTA rail system vulnerabilities: ROW flooding, rail heat kinks, and signal house overheating. The LCCA demonstrated a ...
  124. [124]
    [PDF] 2024-2027 Climate Adaptation Plan - Sustainability.gov
    National transportation system infrastructure. Extreme heat. Causes railways, roadways, sidewalks, and runways to buckle, crack, and rut; Reduces service life ...
  125. [125]
    Public transit infrastructure and heat perceptions in hot and dry ...
    Jan 26, 2021 · We conclude that cities striving to increase public transit use should prioritize thermal comfort when designing public transit stops in hot climates.
  126. [126]
    [PDF] Potential Impacts of Climate Change on Railroads
    The purpose of this paper is to identify and evaluate the effects associated with the potential impacts of climate change on railroad operators.Missing: transit | Show results with:transit