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Scientists Have Identified the Origin of an Extraordinarily Powerful Outer Space Radio Wave

Scientists Have Identified the Origin of an Extraordinarily Powerful Outer Space Radio Wave

The Earth is constantly receiving space signals that contain vital information about extremely energetic phenomena. Among the most peculiar are brief pulses of extremely high-energy radio waves, known as fast radio bursts (FRB). Astronomers compare them to a powerful lighthouse that shines for milliseconds in the middle of a rough, distant sea. Detecting one of these signals is an achievement in itself, but identifying its origin and understanding the nature of its source remains one of the great challenges of science.

That is why recent research led by Northwestern University in the United States has captured the attention of the astronomical community. The team not only detected one of the brightest FRBs ever recorded, but also traced its origin with unprecedented precision.

The pulse, identified as RBFLOAT, arrived in March 2025, lasted just a few milliseconds, and released as much energy as the sun produces in four days. Thanks to a new method of analysis, the researchers located its origin in an arm of a spiral galaxy located 130 million light-years away, in the direction of the constellation Ursa Major. The research was published in the journal The Astrophysical Journal Letters.

The CHIME radio telescope in Canada, one of the world’s leading FRB observatories, and a subnetwork of smaller stations called Outriggers detected the anomalous outburst. CHIME characterized the signal, while the Outriggers triangulated it to a narrow region of space. Optical and X-ray telescopes then provided complementary data. The team achieved a precision of 13 parsecs, equivalent to 42 light-years, within the galaxy NGC 4141.

Astronomers had previously pinpointed other FRBs, but in those cases the signals were repeated, which made the analysis easier. “RBFLOAT was the first non-repeating source localized to such precision,” said Sunil Simha, coauthor of the study, in a university statement. “These are much harder to locate. Thus, even detecting RBFLOAT is proof of concept that CHIME is indeed capable of detecting such events and building a statistically interesting sample of FRBs.”

What Caused the RBFLOAT?

Scientists are still not sure what causes RBFs, but they have some ideas. Because of the enormous energy they release and the brevity of the phenomenon, it is likely that they originate from extreme cosmic events, such as neutron star mergers, magnetars, or pulsars.

In the case of RBFLOAT, the data indicate that it is located in a star-forming region with really massive stars. The triangulation places the signal in a galactic arm where new stars are also being born. This suggests that it could be a magnetar, a subclass of neutron star with a magnetic field billions of times stronger than that of the Earth.

The experience with RBFLOAT will allow the team to apply the same triangulation technique to future signals. The authors estimate that they could achieve about 200 accurate RBF detections per year with just the signals CHIME captures.

“For years, we’ve known FRBs occur all over the sky, but pinning them down has been painstakingly slow. Now, we can routinely tie them to specific galaxies, even down to neighborhoods within those galaxies,” said Yuxin Dong, another member of the team.

This story originally appeared on WIRED en Español and has been translated from Spanish.

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#Scientists #Identified #Origin #Extraordinarily #Powerful #Outer #Space #Radio #Wave

The Esports World Cup 2026 has just begun in Paris and is expected to see thousands of players compete over the coming weeks. The tournament will continue until August 23 at the Paris Expo Porte de Versailles. The event has seen the participation of over 2,000 professional players and over 200 esports teams from over 100 nations. With a record $75 million prize pool on the line, the event promises weeks of intense competition across some of the world’s most popular games like PUBG Mobile. Here’s everything you need to know.

Players had to compete through the biggest qualification program in Esports World Cup history. More than 1.5 million players joined the qualification process. Organizers hosted around 330 qualifying tournaments, publisher leagues, and international circuits worldwide. Only the best-performing players and teams reached the final stage in Paris.

Club Championship Returns with Massive Rewards

The Club Championship remains one of the major highlights of the Esports World Cup 2026. Points can be scored by different teams playing many games over seven weeks. The championship will not be about winning a particular title but rather about the clubs’ performance. As much as $30 million in total will be awarded across different positions, with the winner receiving $7 million. Team Falcons will aim for another successful campaign after winning previous editions.

The Esports World Cup 2026 has retained Cristiano Ronaldo and Magnus Carlsen as Global Ambassadors. Both icons represent excellence in their respective fields. The involvement of these individuals enables the link between the worlds of esports, football, and chess.

[embed]https://www.youtube.com/watch?v=ZGJhWLYQjrU[/embed]

Games Included in Esports World Cup 2026

The Esports World Cup 2026 comprises 25 tournaments across 24 esports titles. Some of the best-known games on PC, console, and mobile platforms will be represented in this list.

VALORANTCounter-Strike 2Dota 2
League of LegendsPUBG MOBILEPUBG: Battlegrounds
FortniteApex LegendsRocket League
EA SPORTS FC 26Call of Duty: Black Ops 7Call of Duty: Warzone
ChessTekken 8Street Fighter 6
Honor of KingsMobile Legends: Bang BangOverwatch 2
Rainbow Six Siege XTeamfight TacticsFree Fire
CrossfireFatal Fury: City of the WolvesTrackmania

The 2026 Esports World Cup will be widely available on TV and online platforms. Viewers from more than 160 countries can follow the tournament on television and the Internet. Coverage will be available in more than 40 languages worldwide, and over 100 broadcasting partners will air the tournament. There will be over 7,000 hours of live coverage and 5,000 official co-streamers.

#Esports #World #Cup #Opens #PariseSports">Esports World Cup 2026 Opens in Paris: Everything You Need to Know
	
The Esports World Cup 2026 has just begun in Paris and is expected to see thousands of players compete over the coming weeks. The tournament will continue until August 23 at the Paris Expo Porte de Versailles. The event has seen the participation of over 2,000 professional players and over 200 esports teams from over 100 nations. With a record  million prize pool on the line, the event promises weeks of intense competition across some of the world’s most popular games like PUBG Mobile. Here’s everything you need to know.



Players had to compete through the biggest qualification program in Esports World Cup history. More than 1.5 million players joined the qualification process. Organizers hosted around 330 qualifying tournaments, publisher leagues, and international circuits worldwide. Only the best-performing players and teams reached the final stage in Paris.



Club Championship Returns with Massive Rewards



The Club Championship remains one of the major highlights of the Esports World Cup 2026. Points can be scored by different teams playing many games over seven weeks. The championship will not be about winning a particular title but rather about the clubs’ performance. As much as  million in total will be awarded across different positions, with the winner receiving  million. Team Falcons will aim for another successful campaign after winning previous editions.



The Esports World Cup 2026 has retained Cristiano Ronaldo and Magnus Carlsen as Global Ambassadors. Both icons represent excellence in their respective fields. The involvement of these individuals enables the link between the worlds of esports, football, and chess.




[embed]https://www.youtube.com/watch?v=ZGJhWLYQjrU[/embed]




Games Included in Esports World Cup 2026



The Esports World Cup 2026 comprises 25 tournaments across 24 esports titles. Some of the best-known games on PC, console, and mobile platforms will be represented in this list.



VALORANTCounter-Strike 2Dota 2League of LegendsPUBG MOBILEPUBG: BattlegroundsFortniteApex LegendsRocket LeagueEA SPORTS FC 26Call of Duty: Black Ops 7Call of Duty: WarzoneChessTekken 8Street Fighter 6Honor of KingsMobile Legends: Bang BangOverwatch 2Rainbow Six Siege XTeamfight TacticsFree FireCrossfireFatal Fury: City of the WolvesTrackmania



The 2026 Esports World Cup will be widely available on TV and online platforms. Viewers from more than 160 countries can follow the tournament on television and the Internet. Coverage will be available in more than 40 languages worldwide, and over 100 broadcasting partners will air the tournament. There will be over 7,000 hours of live coverage and 5,000 official co-streamers.

#Esports #World #Cup #Opens #PariseSports

PUBG Mobile. Here’s everything you need to know.

Players had to compete through the biggest qualification program in Esports World Cup history. More than 1.5 million players joined the qualification process. Organizers hosted around 330 qualifying tournaments, publisher leagues, and international circuits worldwide. Only the best-performing players and teams reached the final stage in Paris.

Club Championship Returns with Massive Rewards

The Club Championship remains one of the major highlights of the Esports World Cup 2026. Points can be scored by different teams playing many games over seven weeks. The championship will not be about winning a particular title but rather about the clubs’ performance. As much as $30 million in total will be awarded across different positions, with the winner receiving $7 million. Team Falcons will aim for another successful campaign after winning previous editions.

The Esports World Cup 2026 has retained Cristiano Ronaldo and Magnus Carlsen as Global Ambassadors. Both icons represent excellence in their respective fields. The involvement of these individuals enables the link between the worlds of esports, football, and chess.

[embed]https://www.youtube.com/watch?v=ZGJhWLYQjrU[/embed]

Games Included in Esports World Cup 2026

The Esports World Cup 2026 comprises 25 tournaments across 24 esports titles. Some of the best-known games on PC, console, and mobile platforms will be represented in this list.

VALORANTCounter-Strike 2Dota 2
League of LegendsPUBG MOBILEPUBG: Battlegrounds
FortniteApex LegendsRocket League
EA SPORTS FC 26Call of Duty: Black Ops 7Call of Duty: Warzone
ChessTekken 8Street Fighter 6
Honor of KingsMobile Legends: Bang BangOverwatch 2
Rainbow Six Siege XTeamfight TacticsFree Fire
CrossfireFatal Fury: City of the WolvesTrackmania

The 2026 Esports World Cup will be widely available on TV and online platforms. Viewers from more than 160 countries can follow the tournament on television and the Internet. Coverage will be available in more than 40 languages worldwide, and over 100 broadcasting partners will air the tournament. There will be over 7,000 hours of live coverage and 5,000 official co-streamers.

#Esports #World #Cup #Opens #PariseSports">Esports World Cup 2026 Opens in Paris: Everything You Need to Know

The Esports World Cup 2026 has just begun in Paris and is expected to see thousands of players compete over the coming weeks. The tournament will continue until August 23 at the Paris Expo Porte de Versailles. The event has seen the participation of over 2,000 professional players and over 200 esports teams from over 100 nations. With a record $75 million prize pool on the line, the event promises weeks of intense competition across some of the world’s most popular games like PUBG Mobile. Here’s everything you need to know.

Players had to compete through the biggest qualification program in Esports World Cup history. More than 1.5 million players joined the qualification process. Organizers hosted around 330 qualifying tournaments, publisher leagues, and international circuits worldwide. Only the best-performing players and teams reached the final stage in Paris.

Club Championship Returns with Massive Rewards

The Club Championship remains one of the major highlights of the Esports World Cup 2026. Points can be scored by different teams playing many games over seven weeks. The championship will not be about winning a particular title but rather about the clubs’ performance. As much as $30 million in total will be awarded across different positions, with the winner receiving $7 million. Team Falcons will aim for another successful campaign after winning previous editions.

The Esports World Cup 2026 has retained Cristiano Ronaldo and Magnus Carlsen as Global Ambassadors. Both icons represent excellence in their respective fields. The involvement of these individuals enables the link between the worlds of esports, football, and chess.

[embed]https://www.youtube.com/watch?v=ZGJhWLYQjrU[/embed]

Games Included in Esports World Cup 2026

The Esports World Cup 2026 comprises 25 tournaments across 24 esports titles. Some of the best-known games on PC, console, and mobile platforms will be represented in this list.

VALORANTCounter-Strike 2Dota 2
League of LegendsPUBG MOBILEPUBG: Battlegrounds
FortniteApex LegendsRocket League
EA SPORTS FC 26Call of Duty: Black Ops 7Call of Duty: Warzone
ChessTekken 8Street Fighter 6
Honor of KingsMobile Legends: Bang BangOverwatch 2
Rainbow Six Siege XTeamfight TacticsFree Fire
CrossfireFatal Fury: City of the WolvesTrackmania

The 2026 Esports World Cup will be widely available on TV and online platforms. Viewers from more than 160 countries can follow the tournament on television and the Internet. Coverage will be available in more than 40 languages worldwide, and over 100 broadcasting partners will air the tournament. There will be over 7,000 hours of live coverage and 5,000 official co-streamers.

#Esports #World #Cup #Opens #PariseSports

Like it or not, data centers are now intrinsic to our modern lives, supporting not just the AI boom but healthcare, banking, government services, and other essential sectors. Reliable data center operation depends on effective cooling, which is already a major challenge as many methods require huge inputs of water or energy. To make matters worse, new research suggests that one of our cheapest, most efficient cooling strategies could stop working in a warmer world.

The findings, published Monday in the journal Scientific Reports, show that rising temperatures and humidity levels threaten the viability of direct air free cooling, an energy-efficient, waterless technique that pulls outside air in to cool data center servers. Over the past 45 years, weather conditions that limit direct air cooling have become significantly more common, particularly across the tropics and the southeastern United States, according to the study. As the global temperature continues to rise, this problem is only going to get worse.

“We found that periods of time when temperature and humidity exceed recommended operating thresholds for direct air free cooling are becoming more frequent and lasting longer in many regions,” lead author Christina Karamperidou, a professor of atmospheric sciences professor at the University of Hawaii at Mānoa, said in a statement. “This will reduce the availability of air free cooling for a growing number of data centers globally.”

Climate-driven cooling constraints

For direct air free cooling, the American Society of Heating, Refrigerating and Air-Conditioning Engineers recommends keeping the air entering a data center between 64 and 81 degrees Fahrenheit (18 and 27 degrees Celsius), with 10% to 70% relative humidity and a dew point below 59 degrees F (15 degrees C). Air that is hotter and more humid than this won’t cool the servers effectively and could corrode metal components.

To investigate how this cooling method will function in a warmer, wetter world, Karamperidou and her colleagues used a combination of high-resolution hourly weather observations, climate model simulations, and global records of data center locations. With this data, they evaluated how often environmental conditions exceeded recommended operating limits for direct air free cooling over the past 45 years and in future climate scenarios.

The researchers found that the prevalence of weather conditions that limit direct air free cooling has increased significantly in recent decades. Even regions that have only seen modest long-term increases in heat and humidity are experiencing longer daily exceedance events, and the share of data centers exposed to conditions that limit direct air free cooling availability for at least one quarter of the year is rising.

Interestingly, the findings suggest that the hottest, most humid days are intensifying faster than average days, indicating that environmental stress on direct air free cooling systems is become more and more concentrated in rare, highly consequential events.

“From an operational perspective, those worst-day conditions often drive contingency planning, system overrides, redundancy requirements, and reliability decisions,” Karamperidou said. “This suggests that infrastructure planning may need to account not only for average environmental conditions but also for how the most stressful days are changing over time.”

By 2050, the number of hours that exceed temperature and humidity limits for direct air free cooling is protected to increase under high greenhouse gas emissions scenarios, according to the researchers. In most regions globally, the average number of hours per day during which this cooling strategy is constrained increases by more than two hours per day, the findings show.

A troubling feedback loop

While this study focuses on how weather can influence data centers, it’s important to remember that data centers can influence local weather too. These facilities dissipate a lot of heat, and research has shown that they can actually create heat islands within a 6-mile radius of themselves.

Karamperidou and her colleagues did not account for this effect, so the direct air free cooling constraints they identified may be conservative, they write in their report. Still, they emphasize that their findings do not mean that this cooling strategy is necessarily infeasible in warm, humid regions. Rather, the study shows that the window of feasibility for direct air free cooling is narrowing due to climate change.

“Alternative strategies—including indirect evaporative cooling, liquid cooling, and hybrid architectures—can partially offset these constraints, albeit with distinct trade-offs in water use, system complexity, and operational design,” the researchers write.

Indeed, as one of the simplest, cheapest, and most efficient cooling strategies becomes increasingly unreliable, data center operators may be forced to turn to more energy- and water-intensive methods. This, in turn, could put added strain on electric grids and water resources that are themselves strained by climate change. Adapting data centers to a warming world without exacerbating the impacts of rising global temperatures will require innovative solutions.

#Cheapest #Cool #Data #Centers #Wont #Work #Warmer #WorldAI,data centers,extreme heat,Global warming">The Cheapest Way to Cool Data Centers Won’t Work in a Warmer World 
                Like it or not, data centers are now intrinsic to our modern lives, supporting not just the AI boom but healthcare, banking, government services, and other essential sectors. Reliable data center operation depends on effective cooling, which is already a major challenge as many methods require huge inputs of water or energy. To make matters worse, new research suggests that one of our cheapest, most efficient cooling strategies could stop working in a warmer world. The findings, published Monday in the journal Scientific Reports, show that rising temperatures and humidity levels threaten the viability of direct air free cooling, an energy-efficient, waterless technique that pulls outside air in to cool data center servers. Over the past 45 years, weather conditions that limit direct air cooling have become significantly more common, particularly across the tropics and the southeastern United States, according to the study. As the global temperature continues to rise, this problem is only going to get worse. “We found that periods of time when temperature and humidity exceed recommended operating thresholds for direct air free cooling are becoming more frequent and lasting longer in many regions,” lead author Christina Karamperidou, a professor of atmospheric sciences professor at the University of Hawaii at Mānoa, said in a statement. “This will reduce the availability of air free cooling for a growing number of data centers globally.”

 Climate-driven cooling constraints For direct air free cooling, the American Society of Heating, Refrigerating and Air-Conditioning Engineers recommends keeping the air entering a data center between 64 and 81 degrees Fahrenheit (18 and 27 degrees Celsius), with 10% to 70% relative humidity and a dew point below 59 degrees F (15 degrees C). Air that is hotter and more humid than this won’t cool the servers effectively and could corrode metal components.

 To investigate how this cooling method will function in a warmer, wetter world, Karamperidou and her colleagues used a combination of high-resolution hourly weather observations, climate model simulations, and global records of data center locations. With this data, they evaluated how often environmental conditions exceeded recommended operating limits for direct air free cooling over the past 45 years and in future climate scenarios. The researchers found that the prevalence of weather conditions that limit direct air free cooling has increased significantly in recent decades. Even regions that have only seen modest long-term increases in heat and humidity are experiencing longer daily exceedance events, and the share of data centers exposed to conditions that limit direct air free cooling availability for at least one quarter of the year is rising.

 Interestingly, the findings suggest that the hottest, most humid days are intensifying faster than average days, indicating that environmental stress on direct air free cooling systems is become more and more concentrated in rare, highly consequential events. “From an operational perspective, those worst-day conditions often drive contingency planning, system overrides, redundancy requirements, and reliability decisions,” Karamperidou said. “This suggests that infrastructure planning may need to account not only for average environmental conditions but also for how the most stressful days are changing over time.” By 2050, the number of hours that exceed temperature and humidity limits for direct air free cooling is protected to increase under high greenhouse gas emissions scenarios, according to the researchers. In most regions globally, the average number of hours per day during which this cooling strategy is constrained increases by more than two hours per day, the findings show.

 A troubling feedback loop While this study focuses on how weather can influence data centers, it’s important to remember that data centers can influence local weather too. These facilities dissipate a lot of heat, and research has shown that they can actually create heat islands within a 6-mile radius of themselves. Karamperidou and her colleagues did not account for this effect, so the direct air free cooling constraints they identified may be conservative, they write in their report. Still, they emphasize that their findings do not mean that this cooling strategy is necessarily infeasible in warm, humid regions. Rather, the study shows that the window of feasibility for direct air free cooling is narrowing due to climate change.

 “Alternative strategies—including indirect evaporative cooling, liquid cooling, and hybrid architectures—can partially offset these constraints, albeit with distinct trade-offs in water use, system complexity, and operational design,” the researchers write. Indeed, as one of the simplest, cheapest, and most efficient cooling strategies becomes increasingly unreliable, data center operators may be forced to turn to more energy- and water-intensive methods. This, in turn, could put added strain on electric grids and water resources that are themselves strained by climate change. Adapting data centers to a warming world without exacerbating the impacts of rising global temperatures will require innovative solutions.      #Cheapest #Cool #Data #Centers #Wont #Work #Warmer #WorldAI,data centers,extreme heat,Global warming

AI boom but healthcare, banking, government services, and other essential sectors. Reliable data center operation depends on effective cooling, which is already a major challenge as many methods require huge inputs of water or energy. To make matters worse, new research suggests that one of our cheapest, most efficient cooling strategies could stop working in a warmer world.

The findings, published Monday in the journal Scientific Reports, show that rising temperatures and humidity levels threaten the viability of direct air free cooling, an energy-efficient, waterless technique that pulls outside air in to cool data center servers. Over the past 45 years, weather conditions that limit direct air cooling have become significantly more common, particularly across the tropics and the southeastern United States, according to the study. As the global temperature continues to rise, this problem is only going to get worse.

“We found that periods of time when temperature and humidity exceed recommended operating thresholds for direct air free cooling are becoming more frequent and lasting longer in many regions,” lead author Christina Karamperidou, a professor of atmospheric sciences professor at the University of Hawaii at Mānoa, said in a statement. “This will reduce the availability of air free cooling for a growing number of data centers globally.”

Climate-driven cooling constraints

For direct air free cooling, the American Society of Heating, Refrigerating and Air-Conditioning Engineers recommends keeping the air entering a data center between 64 and 81 degrees Fahrenheit (18 and 27 degrees Celsius), with 10% to 70% relative humidity and a dew point below 59 degrees F (15 degrees C). Air that is hotter and more humid than this won’t cool the servers effectively and could corrode metal components.

To investigate how this cooling method will function in a warmer, wetter world, Karamperidou and her colleagues used a combination of high-resolution hourly weather observations, climate model simulations, and global records of data center locations. With this data, they evaluated how often environmental conditions exceeded recommended operating limits for direct air free cooling over the past 45 years and in future climate scenarios.

The researchers found that the prevalence of weather conditions that limit direct air free cooling has increased significantly in recent decades. Even regions that have only seen modest long-term increases in heat and humidity are experiencing longer daily exceedance events, and the share of data centers exposed to conditions that limit direct air free cooling availability for at least one quarter of the year is rising.

Interestingly, the findings suggest that the hottest, most humid days are intensifying faster than average days, indicating that environmental stress on direct air free cooling systems is become more and more concentrated in rare, highly consequential events.

“From an operational perspective, those worst-day conditions often drive contingency planning, system overrides, redundancy requirements, and reliability decisions,” Karamperidou said. “This suggests that infrastructure planning may need to account not only for average environmental conditions but also for how the most stressful days are changing over time.”

By 2050, the number of hours that exceed temperature and humidity limits for direct air free cooling is protected to increase under high greenhouse gas emissions scenarios, according to the researchers. In most regions globally, the average number of hours per day during which this cooling strategy is constrained increases by more than two hours per day, the findings show.

A troubling feedback loop

While this study focuses on how weather can influence data centers, it’s important to remember that data centers can influence local weather too. These facilities dissipate a lot of heat, and research has shown that they can actually create heat islands within a 6-mile radius of themselves.

Karamperidou and her colleagues did not account for this effect, so the direct air free cooling constraints they identified may be conservative, they write in their report. Still, they emphasize that their findings do not mean that this cooling strategy is necessarily infeasible in warm, humid regions. Rather, the study shows that the window of feasibility for direct air free cooling is narrowing due to climate change.

“Alternative strategies—including indirect evaporative cooling, liquid cooling, and hybrid architectures—can partially offset these constraints, albeit with distinct trade-offs in water use, system complexity, and operational design,” the researchers write.

Indeed, as one of the simplest, cheapest, and most efficient cooling strategies becomes increasingly unreliable, data center operators may be forced to turn to more energy- and water-intensive methods. This, in turn, could put added strain on electric grids and water resources that are themselves strained by climate change. Adapting data centers to a warming world without exacerbating the impacts of rising global temperatures will require innovative solutions.

#Cheapest #Cool #Data #Centers #Wont #Work #Warmer #WorldAI,data centers,extreme heat,Global warming">The Cheapest Way to Cool Data Centers Won’t Work in a Warmer World The Cheapest Way to Cool Data Centers Won’t Work in a Warmer World 
                Like it or not, data centers are now intrinsic to our modern lives, supporting not just the AI boom but healthcare, banking, government services, and other essential sectors. Reliable data center operation depends on effective cooling, which is already a major challenge as many methods require huge inputs of water or energy. To make matters worse, new research suggests that one of our cheapest, most efficient cooling strategies could stop working in a warmer world. The findings, published Monday in the journal Scientific Reports, show that rising temperatures and humidity levels threaten the viability of direct air free cooling, an energy-efficient, waterless technique that pulls outside air in to cool data center servers. Over the past 45 years, weather conditions that limit direct air cooling have become significantly more common, particularly across the tropics and the southeastern United States, according to the study. As the global temperature continues to rise, this problem is only going to get worse. “We found that periods of time when temperature and humidity exceed recommended operating thresholds for direct air free cooling are becoming more frequent and lasting longer in many regions,” lead author Christina Karamperidou, a professor of atmospheric sciences professor at the University of Hawaii at Mānoa, said in a statement. “This will reduce the availability of air free cooling for a growing number of data centers globally.”

 Climate-driven cooling constraints For direct air free cooling, the American Society of Heating, Refrigerating and Air-Conditioning Engineers recommends keeping the air entering a data center between 64 and 81 degrees Fahrenheit (18 and 27 degrees Celsius), with 10% to 70% relative humidity and a dew point below 59 degrees F (15 degrees C). Air that is hotter and more humid than this won’t cool the servers effectively and could corrode metal components.

 To investigate how this cooling method will function in a warmer, wetter world, Karamperidou and her colleagues used a combination of high-resolution hourly weather observations, climate model simulations, and global records of data center locations. With this data, they evaluated how often environmental conditions exceeded recommended operating limits for direct air free cooling over the past 45 years and in future climate scenarios. The researchers found that the prevalence of weather conditions that limit direct air free cooling has increased significantly in recent decades. Even regions that have only seen modest long-term increases in heat and humidity are experiencing longer daily exceedance events, and the share of data centers exposed to conditions that limit direct air free cooling availability for at least one quarter of the year is rising.

 Interestingly, the findings suggest that the hottest, most humid days are intensifying faster than average days, indicating that environmental stress on direct air free cooling systems is become more and more concentrated in rare, highly consequential events. “From an operational perspective, those worst-day conditions often drive contingency planning, system overrides, redundancy requirements, and reliability decisions,” Karamperidou said. “This suggests that infrastructure planning may need to account not only for average environmental conditions but also for how the most stressful days are changing over time.” By 2050, the number of hours that exceed temperature and humidity limits for direct air free cooling is protected to increase under high greenhouse gas emissions scenarios, according to the researchers. In most regions globally, the average number of hours per day during which this cooling strategy is constrained increases by more than two hours per day, the findings show.

 A troubling feedback loop While this study focuses on how weather can influence data centers, it’s important to remember that data centers can influence local weather too. These facilities dissipate a lot of heat, and research has shown that they can actually create heat islands within a 6-mile radius of themselves. Karamperidou and her colleagues did not account for this effect, so the direct air free cooling constraints they identified may be conservative, they write in their report. Still, they emphasize that their findings do not mean that this cooling strategy is necessarily infeasible in warm, humid regions. Rather, the study shows that the window of feasibility for direct air free cooling is narrowing due to climate change.

 “Alternative strategies—including indirect evaporative cooling, liquid cooling, and hybrid architectures—can partially offset these constraints, albeit with distinct trade-offs in water use, system complexity, and operational design,” the researchers write. Indeed, as one of the simplest, cheapest, and most efficient cooling strategies becomes increasingly unreliable, data center operators may be forced to turn to more energy- and water-intensive methods. This, in turn, could put added strain on electric grids and water resources that are themselves strained by climate change. Adapting data centers to a warming world without exacerbating the impacts of rising global temperatures will require innovative solutions.      #Cheapest #Cool #Data #Centers #Wont #Work #Warmer #WorldAI,data centers,extreme heat,Global warming

Like it or not, data centers are now intrinsic to our modern lives, supporting not just the AI boom but healthcare, banking, government services, and other essential sectors. Reliable data center operation depends on effective cooling, which is already a major challenge as many methods require huge inputs of water or energy. To make matters worse, new research suggests that one of our cheapest, most efficient cooling strategies could stop working in a warmer world.

The findings, published Monday in the journal Scientific Reports, show that rising temperatures and humidity levels threaten the viability of direct air free cooling, an energy-efficient, waterless technique that pulls outside air in to cool data center servers. Over the past 45 years, weather conditions that limit direct air cooling have become significantly more common, particularly across the tropics and the southeastern United States, according to the study. As the global temperature continues to rise, this problem is only going to get worse.

“We found that periods of time when temperature and humidity exceed recommended operating thresholds for direct air free cooling are becoming more frequent and lasting longer in many regions,” lead author Christina Karamperidou, a professor of atmospheric sciences professor at the University of Hawaii at Mānoa, said in a statement. “This will reduce the availability of air free cooling for a growing number of data centers globally.”

Climate-driven cooling constraints

For direct air free cooling, the American Society of Heating, Refrigerating and Air-Conditioning Engineers recommends keeping the air entering a data center between 64 and 81 degrees Fahrenheit (18 and 27 degrees Celsius), with 10% to 70% relative humidity and a dew point below 59 degrees F (15 degrees C). Air that is hotter and more humid than this won’t cool the servers effectively and could corrode metal components.

To investigate how this cooling method will function in a warmer, wetter world, Karamperidou and her colleagues used a combination of high-resolution hourly weather observations, climate model simulations, and global records of data center locations. With this data, they evaluated how often environmental conditions exceeded recommended operating limits for direct air free cooling over the past 45 years and in future climate scenarios.

The researchers found that the prevalence of weather conditions that limit direct air free cooling has increased significantly in recent decades. Even regions that have only seen modest long-term increases in heat and humidity are experiencing longer daily exceedance events, and the share of data centers exposed to conditions that limit direct air free cooling availability for at least one quarter of the year is rising.

Interestingly, the findings suggest that the hottest, most humid days are intensifying faster than average days, indicating that environmental stress on direct air free cooling systems is become more and more concentrated in rare, highly consequential events.

“From an operational perspective, those worst-day conditions often drive contingency planning, system overrides, redundancy requirements, and reliability decisions,” Karamperidou said. “This suggests that infrastructure planning may need to account not only for average environmental conditions but also for how the most stressful days are changing over time.”

By 2050, the number of hours that exceed temperature and humidity limits for direct air free cooling is protected to increase under high greenhouse gas emissions scenarios, according to the researchers. In most regions globally, the average number of hours per day during which this cooling strategy is constrained increases by more than two hours per day, the findings show.

A troubling feedback loop

While this study focuses on how weather can influence data centers, it’s important to remember that data centers can influence local weather too. These facilities dissipate a lot of heat, and research has shown that they can actually create heat islands within a 6-mile radius of themselves.

Karamperidou and her colleagues did not account for this effect, so the direct air free cooling constraints they identified may be conservative, they write in their report. Still, they emphasize that their findings do not mean that this cooling strategy is necessarily infeasible in warm, humid regions. Rather, the study shows that the window of feasibility for direct air free cooling is narrowing due to climate change.

“Alternative strategies—including indirect evaporative cooling, liquid cooling, and hybrid architectures—can partially offset these constraints, albeit with distinct trade-offs in water use, system complexity, and operational design,” the researchers write.

Indeed, as one of the simplest, cheapest, and most efficient cooling strategies becomes increasingly unreliable, data center operators may be forced to turn to more energy- and water-intensive methods. This, in turn, could put added strain on electric grids and water resources that are themselves strained by climate change. Adapting data centers to a warming world without exacerbating the impacts of rising global temperatures will require innovative solutions.

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