These new solid-state ACs promise a cool future. Scientists aren’t so sure.

<p>After three years of record-­breaking heat, this one is <a href="https://www.almanac.com/summer-weather-forecast#:~:text=Watch%20for:,expected%20in%20July%20and%20August.">set to be yet another scorcher</a>. Air-conditioning? Not going anywhere. The International Energy Agency <a href="https://ourworldindata.org/air-conditioning-causes-around-greenhouse-gas-emissions-will-change-future">projects that the number of AC units will triple by 2050</a>. </p> <p>That’s good for health—<a href="https://www.thelancet.com/journals/lancet/article/PIIS0140-6736(21)01787-6/fulltext">one <em>Lancet</em> study</a> estimated that AC prevented nearly 200,000 premature deaths in 2019 alone—but bad for the planet. Artificial chill already accounts for 7% of global electricity use and 3% of greenhouse-gas emissions, and if improperly disposed of, the units can leak refrigerants with more global-­warming potential than carbon dioxide.</p> <p>Feeling the heat, a number of scientists and startups are hoping to amp up solid-­state cooling, which is currently used at a small scale for things like mini fridges, EV batteries, and some high-end gaming computers. Traditional ACs transfer heat by using a compressor and a fan to circulate a refrigerant and turn it from liquid to gas. </p> <p>Solid-state systems, on the other hand, move heat through conductive materials like gadolinium and bismuth telluride—which could theoretically cool spaces and surfaces with fewer messy side effects. </p> <p>The catch is whether they can match the efficiency of conventional AC. “One of the key questions that remain is why are the solid-state coolers not as efficient as typical thermodynamic cycles?” says Pramod Reddy, a professor of mechanical engineering at the University of Michigan who studies heat transfer.&nbsp;</p> <p>Research and pilot programs are underway to test a range of approaches. Brooklyn-based Mimic Systems uses thermo­electric cooling, which passes a current through semiconductive materials to shift heat from one side to another. Its room-scale climate control system is <a href="https://praxisinstitute.org/pilot-novel-solid-state-cooling-and-heating-system-advancing-climate-resiliency-for-people-with-disabilities/">being piloted in an apartment in Vancouver</a>. </p> <p>The German company Magnotherm is set to <a href="https://station-frankfurt.de/2026/04/08/magnotherm-and-rewe-group-launch-magnetic-cooling-pilot-in-german-supermarkets/">test its system</a>, which relies on a magneto­caloric setup that transfers heat by magnetizing and demagnetizing materials, in a chain of supermarkets. <a href="https://www.nature.com/articles/s41586-025-09946-4.epdf?sharing_token=XwbiMt-E3d3Xx-JEOKTcNNRgN0jAjWel9jnR3ZoTv0NUOc5QMn2XTcQS71i232YrugBT88BBCDF6JmZT9ZpN5fowB2_etJpIH5mon7I9mjrJqEYswy7nX0YcnjchNp3gpLiExsDP9MJVjsvyH3bcx8LmnRNbwE-4hjBHaP1HVcuZd5FS8s5W9NG9eO7hUegqS7sTpoLmR8KNmFETqOKPD7972H1sJ5I9A5Ws1zzDRnrLCefw8bQVf44xUkhz_2wc7V89CHTgDmB18VeAaVBQvw%3D%3D&amp;tracking_referrer=spectrum.ieee.org">A team in Hong Kong</a> has announced that its elastocaloric device, whose material heats and cools as it expands and contracts, can dip below 0 °C. And the <a href="https://barocal.com/">UK’s Barocal</a> is betting on barocaloric systems, which change temperature in response to shifts in pressure. </p> <p>But experts, especially in thermoelectrics, have doubts about how well any solid-­state scheme can compete. For most modern HVAC systems, the coefficient of performance (COP) is 3, explains Jeff Snyder, a professor at Northwestern University who studies electrical and thermal conductivity. That essentially means the system moves three units of heat for every unit of energy that goes into it. </p> <p>Thermoelectrics in particular tend to have a much lower performance at high levels of temperature change, Snyder says, which means they’re best suited for niche uses such as cooling the back of a car seat. </p> <div class="wp-block-image"> <figure class="wp-block-image size-large"><img decoding="async" height="2000" width="1500" src="https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?w=1500" alt="brown HVAC unit below a window" class="wp-image-1138637" srcset="https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg 1826w, https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?resize=225,300 225w, https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?resize=768,1024 768w, https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?resize=1500,2000 1500w, https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?resize=1152,1536 1152w, https://wp.technologyreview.com/wp-content/uploads/2026/06/IMG_3420.jpg?resize=1536,2048 1536w" sizes="(max-width: 1500px) 100vw, 1500px" /><figcaption class="wp-element-caption">Mimic’s room-scale thermoelectric HVAC unit is being tested in a Vancouver apartment.</figcaption><div class="image-credit">COURTESY OF MIMIC SYSTEMS, INC</div> </figure> </div> <p>Efficiency, however, isn’t everything, argues Lindsay Rasmussen, a manager at the Rocky Mountain Institute’s climate tech accelerator Third Derivative, which supports both Magnotherm and Mimic. In the US, most ACs currently in use employ a refrigerant called R410A, which has a global-­warming potential more than 2,000 times that of carbon dioxide. Plus, their moving parts can make them less durable, especially compared with a solid-state model that’s less mechanically complex.</p> <p>Still, a dearth of units makes it hard to answer the efficiency question. To understand how well alternatives work, says Rasmussen, researchers need to compare their long-term energy consumption with that of conventional models instead of simply looking at COP. Mimic claims, for example, that its room-scale model should match the draw of a typical AC unit over the course of a year. Elastocaloric and barocaloric systems also have promise, Rasmussen adds, but room-scale prototypes are probably two to three years away.&nbsp;</p> <p>In the end, the likelihood that solid-state cooling could replace compressor-based AC is slim. But as the planet warms and places like India install tens of millions of new AC units over the next decade, supplanting even a small number could make a dent. “If [solid-state] could take over even a 5% market share,” Rasmussen says, “that is a really large potential impact.”&nbsp;</p> <p><em>Sara Kiley Watson is a science journalist specializing in climate and sustainability. She’s based in The Hague.</em></p>