Sneha Sachar, who spent half her life in Delhi and now lives in California, is used to heat. But her hometown feels much hotter now than when she was growing up. Even commuting by car is so uncomfortable in certain months, says Ms Sachar, who works for the Clean Cooling Collaborative, a philanthropic initiative focused on improved cooling. Rising temperatures areeven worse for outdoor workers. "This is really impacting the ability of people to continue to earn their livelihoods," Ms Sachar says. She says that there are a number of low-tech ways to keep buildings cool, such as designing for air flow. For outdoor workers, even a 20-minute break from the heat and humidity, such as inwell-designed cooling stations, can make a difference. But beyond this, active cooling will become increasingly critical as temperatures continue to rise due to climate change. Morgan Stanley is predicting that the annual growth rate of the cooling market, already worth $235bn (£180bn) a year,could more than double by 2030. Yet existing cooling devices have serious drawbacks. One issue the refrigerant - the fluid that transitions back and forth from liquid to gas, in a process that transfers heat. It's common for them to leak from standard systems, harming both efficiency and potentially health. The refrigerants typically used in cooling today are hydrofluorocarbons (HFCs), a group of synthetic gases with high global warming potential. HFCs are much more potent than carbon dioxide. So one option is to replace the refrigerants with more climate-friendly versions. But the candidates with the lower global warming potential, also have problems. For instance, propane is highly flammable. Ammonia is toxic. Carbon dioxide works at high pressures, requiring specialised equipment. But as many places phase down HFCs, alternative refrigerants will remain important. Ms Sachar says that we still need refrigerants because for home cooling, "A/Cs as we know them today will continue to be the solution, at least for the next decade or so". In the longer term, some scientists are looking toward cooling devices that don't need liquid refrigerants at all. Lindsay Rasmussen, who manages building and land-use projects at the energy non-profit RMI, calls these "revolutionary technologies". A major set of revolutionary cooling tech is solid-state cooling. This uses solid materials and some sort of additional force to induce temperature changes. That extra force could be pressure, voltage, magnets or mechanical stress. Ms Rasmussen says that solid-state devices can go further than incremental improvements because "not only do they eliminate those super-polluting refrigerants, but they can also offer improved efficiency to the systems". RMI has identified between 10 and 20 start-ups working on early versions of solid-state cooling devices. One of those startups is the German company Magnotherm, which uses magnets. Certain materials change temperature when exposed to magnetic fields. "With our technology, it's inherently safe because it's not toxic, it's a metal, and we operate at very low pressures," according to Timur Sirman, the CEO and cofounder of Magnotherm. The idea of magnetocaloric cooling has been around for years, but commercialising it is relatively new. Magnotherm has built about 40 beverage coolers, and about five refrigerators, in what is so far a manual and in-house process. The permanent magnets are the most expensive part of the technology, Mr Sirman reports. "But it never breaks, so we can always reuse this quite cost-intensive component." The company is seeking out alternative sources of magnetic fields, as well as optimising materials, as they aim to dramatically increase the cooling capacity of their devices. Mr Sirman believes that if you account for the efficiency and health issues of refrigerants, like leakages, Magnotherm products can compete on price. "We are not targeting customers who are only looking at initial cost." He acknowledges that for now the company's beverage coolers are quite pricey. Their customers tend to be early adopters of new technologies. Another technology under development is thermoelectric cooling. This involves moving heat between two sides of a device. With the application of electrical energy, heat is transferred in the direction of the current. A notable thermoelectric start-up is Phononic, which is based in the US and has an additional manufacturing facility in Thailand. Millions of Phononic cooling devices are now in use, including in data centres, supermarkets and other buildings. Their cooling devices are built in a similar way to computer chips, using semiconducting materials to transfer the heat. "Our chips are really thin, really small, but they get really cold. They consume a small amount of electricity in generating that coldness, but they pack one hell of a punch," says Tony Atti, the CEO of Phononic. He says that, to work at their best, traditional fridges need to be run all the time. But thermoelectric devices can be easily switched on off. This helps to reduce the costs, energy use and space requirements. "We like to present the coolness on demand where you need it," says Mr Atti. Another advantage is that thermoelectric cooling can operate silently. "That's because there's zero moving parts," Ms Rasmussen explains. "The heat is occurring because of the reaction in the material level." In contrast, standard vapour compression systems contain pumps, condensers and expanders for refrigerant, which all generate much of the noise. A different type of solid-state cooling is elastocaloric cooling. This achieves temperature changes through mechanical stress to elastocaloric materials, which can cool down or heat up with the application of stress. Researchers in four European countries are collaborating on SMACool, an elastocaloric air conditioner that uses metal tubes made from specific metallic alloys. At the moment, elastocaloric prototypes have much lower cooling capacity than commercial air conditioning. And the maximum possible efficiency of SMACool is still lower than that of conventional air conditioning, although the aim is tobeat the energy efficiency of A/C. However, progress is continuing.A team led by Hong Kong researchersrecently created an A/C alternative that achieved a cooling power of 1,284W—the first time an elastocaloric device surpassed the 1,000W mark. One innovation was using graphene nanofluid rather than distilled water to transfer the heat. Overall, Ms Rasmussen says, solid-state devices are generally not yet as powerful as conventional vapour-compression air conditioning. But she expects performance improvements over time. She also expects improvements in affordability. So far solid-state cooling has mainly been deployed in wealthy countries. A key question, Ms Rasmussen says, is "Can these technologies scale up to where they could be affordable for those who need it the most and where the greatest demand for cooling is coming from?"
Why we need 'revolutionary' cooling tech
TruthLens AI Suggested Headline:
"Emerging Technologies Aim to Transform Cooling Solutions Amid Rising Global Temperatures"
Bbc News
7.7
TruthLens AI Summary
Sneha Sachar, who has experienced the rising heat in her hometown of Delhi and now resides in California, highlights the growing discomfort caused by increasing temperatures. This rise in temperature particularly affects outdoor workers, making it challenging for them to earn a living. Sachar, who works with the Clean Cooling Collaborative, emphasizes the need for innovative cooling solutions as traditional methods may no longer suffice in the face of climate change. While low-tech solutions like improved airflow designs and cooling stations can provide temporary relief, the demand for active cooling technologies is expected to surge. Morgan Stanley anticipates that the cooling market, currently valued at $235 billion annually, could more than double by 2030. However, existing cooling systems come with significant drawbacks, particularly concerning the refrigerants they use, which are often hydrofluorocarbons (HFCs) that have a high global warming potential and can leak, causing health and efficiency issues. As the phase-out of HFCs progresses, finding viable alternative refrigerants becomes crucial to mitigate these concerns.
In response to these challenges, researchers and companies are exploring 'revolutionary technologies' in cooling, such as solid-state cooling, which eliminates the need for harmful refrigerants. Solid-state devices, including those developed by startups like Magnotherm and Phononic, utilize solid materials and various forces to induce temperature changes efficiently. Magnotherm employs magnetic fields to achieve cooling, while Phononic's thermoelectric devices transfer heat using semiconductor technology, offering silent operation and reduced energy consumption. Despite the current limitations in cooling capacity compared to conventional systems, advancements in solid-state technology are expected to enhance both performance and affordability over time. The future of cooling will depend on the ability of these innovative solutions to scale up, making them accessible to regions most in need, especially as global temperatures continue to rise due to climate change.
TruthLens AI Analysis
The article sheds light on the urgent need for innovative cooling technologies in the face of rising global temperatures. It highlights the personal experience of Sneha Sachar, who emphasizes the significant impact of heat on daily life and livelihoods, particularly for outdoor workers. As climate change accelerates, the demand for effective cooling solutions is expected to grow, prompting a critical examination of current technologies and their environmental implications.
Rising Temperatures and Public Health
The narrative begins with a personal account of increased heat discomfort, which resonates with many living in urban areas affected by climate change. It underscores the health risks and economic challenges posed by extreme heat, particularly for outdoor workers who depend on favorable weather conditions to earn a living. This sets the stage for a broader discussion on the importance of implementing better cooling solutions, both low-tech and high-tech.
Current Cooling Technologies and Their Drawbacks
The article critically assesses existing cooling technologies, particularly the use of hydrofluorocarbons (HFCs) as refrigerants. It points out the environmental hazards associated with HFCs, which have a much higher global warming potential than carbon dioxide. This acknowledgment could foster greater public awareness about the need for sustainable alternatives, thereby aligning with global climate goals.
Alternatives and Future Directions
Despite the drawbacks of current refrigerants, the article suggests that alternatives are necessary as society moves away from HFCs. However, it also presents the challenges associated with these alternatives, such as flammability and toxicity. This nuanced discussion helps to inform readers about the complexities involved in developing effective cooling technologies without compromising safety or environmental standards.
Public Perception and Industry Response
The article likely aims to raise awareness about the urgent need for revolutionary cooling technologies while also fostering a sense of urgency among stakeholders, including policymakers, businesses, and the general public. By highlighting the economic implications of inadequate cooling systems, it seeks to mobilize support for investments in innovative solutions.
Potential Economic and Political Implications
Should the cooling market grow as projected, there could be significant implications for global economies, particularly for companies involved in HVAC (heating, ventilation, and air conditioning) technologies. This growth could spur competition and innovation within the industry, impacting stock prices and investment trends. Politically, the discussion around cooling technologies may influence climate policies and regulations as the need for sustainable practices becomes more pressing.
Community Engagement
The content appears to target environmentally conscious communities, particularly those advocating for climate action and sustainable living. By addressing the direct impact of climate change on individuals' lives, the article appeals to a wide audience concerned about public health, environmental sustainability, and economic stability.
Market Impact
The insights presented could influence investors and stakeholders in the cooling technology sector, potentially affecting market dynamics. Companies focused on developing eco-friendly refrigerants or innovative cooling solutions may find themselves in a more favorable position as awareness grows.
Global Context
The article fits within a larger discourse on climate change and its multifaceted impacts on society. As global temperatures continue to rise, discussions around cooling technologies will remain relevant, linking the topic to broader environmental and economic challenges faced today.
In assessing the reliability of the article, it appears to provide factual information grounded in current industry trends and environmental science. However, the framing of the narrative suggests a deliberate push towards innovation and change, which could be interpreted as a call to action rather than a purely objective reporting of facts.
Overall, the article effectively raises awareness about the critical need for revolutionary cooling technologies in the context of climate change, while also presenting the complexities and challenges associated with current and alternative solutions.