As the HVAC industry evolves to be more sustainable, heat pumps are increasingly recognized for their potential to help reduce greenhouse gas emissions and energy consumption. A UC Davis study1 found that air-source heat pumps can lower household carbon dioxide emissions by 38–53% compared to gas furnaces. Additionally, the Department of Energy2 notes that, depending upon heat pump efficiency, modern heat pumps can cut energy use by 31-47% on average compared to electric resistance heating since they work by transferring existing heat, rather than generating it through electric resistance.
Unlike traditional furnaces and boilers, heat pumps can transfer more heat energy than the electrical energy they consume, sometimes reaching efficiency rates of 300% to 400%3 by capturing and transporting energy from the outside environment. Depending on the heat pump’s efficiency, this could result in substantial cost savings—between $300 and $650 annually4—with the opportunity to significantly reduce household carbon footprints.
Advancements in compressor technology, heat exchanger materials, and refrigerant formulations have helped to drive these efficiency gains. Some heat pumps now feature variable-speed inverter compressors that can dynamically adjust operation based on demand and optimize energy use in extreme conditions. These innovations, developed through global R&D collaborations, are expanding the capabilities of heat pumps for use in harsh climates.
Overcoming Performance Challenges in Extreme Climates & The Role of Consortiums in Advancing Technology
Despite potential benefits, heat pumps have sometimes faced challenges in extreme weather conditions. This has spurred research and development efforts aimed at understanding and enhancing their cold-weather performance. Industry leaders, HVAC researchers, academia, and policymakers are collaborating to learn how to maximize the potential benefits of using heat pumps. Key research areas include improving refrigerant compression efficiency at lower pressures and optimizing heat exchanger designs for operation in freezing temperatures.
Collaborative research and development efforts are reshaping the future of HVAC solutions with significant breakthroughs in heat pump efficiency and reliability, even in severe winter conditions. For instance, LG Electronics has established cold-climate heat pump laboratories in Alaska, one of the harshest winter environments. Working with the University of Alaska Anchorage and the University of Alaska Fairbanks, engineers test and refine heat pump systems under real-world extreme temperatures.
The Consortium for Advanced Heat Pump Research, a collaboration between LG and the University of Alaska Anchorage (UAA), has opened state-of-the-art labs in Anchorage and Fairbanks. These labs replicate home environments, enabling realistic and practical heat pump research. The facilities utilize a variety of LG’s HVAC solutions, including both ducted and duct-free units.
OVERCOMING CHALLENGES: Heat pumps may have previously struggled in extreme temperatures, but with the new generation, that’s no longer the case (Courtesy of LG)
The research conducted at these labs aims to optimize heat pump performance in tundra conditions, helping reduce dependence on fossil-fuel heating sources. The Anchorage and Fairbanks labs aim to enhance the capabilities of air-source heat pumps so that they can be the primary source of heating in ambient temperatures as low as -40 degrees Fahrenheit.
Conducting cold-climate heat pump research in Alaska is practical for a number of reasons, including the state’s dispersed population and often challenging climate, lack of consolidated gas infrastructure, and high oil heating costs. Alaska Governor Mike Dunleavy highlighted the importance of this initiative, stating that the collaboration between UAA and LG exemplifies how new business and investment in Alaska can have a major impact on the nation and the world.5
Real-World Applications and Market Growth
As heat pump technology advances, adoption rates are rising6, including in some regions with cold winters, such as Maine7. Governments and regulatory bodies worldwide are supporting the adoption of heat pump technology through incentives and policy frameworks promoting energy-efficient heating solutions.
For example, the U.S. Department of Energy’s Cold Climate Heat Pump Challenge aims to accelerate the commercialization of high-performance models suited for subfreezing temperatures.8 Similar programs in Europe and Asia support heat pump adoption as part of broader carbon reduction goals.
Many manufacturers are expanding their product lines to address diverse climatic needs, such as dual-source heat pumps, which switch between air and ground sources. These systems offer enhanced flexibility and efficiency, making them suitable for a wider range of environmental conditions.
Future Prospects
The future of heat pump technology looks promising, with ongoing research and development paving the way for even greater efficiency and reliability. As global temperatures continue to fluctuate and the demand for sustainable energy solutions grows, the HVAC industry must adapt and innovate. Collaborative efforts among manufacturers, researchers, and policymakers will be crucial in overcoming any new or remaining challenges and helping to ensure that heat pumps can perform optimally in all climates.
By continuing to invest in advanced technologies and fostering international partnerships, the HVAC industry can play a critical role in helping to reduce carbon emissions and promote energy efficiency. The power of collaboration will be key to unlocking the full potential of heat pumps, making them a viable and sustainable heating solution for the future.
Footnotes
- Science Direct, Greenhouse gas emission forecasts for electrification of space heating in residential homes in the US: https://www.sciencedirect.com/science/article/pii/S0301421522000386
- U.S. Department of Energy’s National Renewable Energy Laboratory (NREL), News Release: Benefits of Heat Pumps Detailed in New NREL Report: https://www.nrel.gov/news/press/2024/benefits-of-heat-pumps-detailed-in-new-nrel-report.html
- MIT Technology Review, Everything you need to know about the wild world of heat pumps: https://www.technologyreview.com/2023/02/14/1068582/everything-you-need-to-know-about-heat-pumps/
- U.S. Department of Energy’s National Renewable Energy Laboratory (NREL), News Release: Benefits of Heat Pumps Detailed in New NREL Report: https://www.nrel.gov/news/press/2024/benefits-of-heat-pumps-detailed-in-new-nrel-report.html
- ACHR NEWS, LG, University of Alaska Open Heat Pump Research Labs: /articles/163845-lg-university-of-alaska-open-heat-pump-research-labs
- Canary Media, Heat pumps outsold gas furnaces by their biggest-ever margin in 2024: https://www.canarymedia.com/articles/heat-pumps/heat-pumps-keep-widening-their-lead-on-gas-furnaces
- Canary Media, Heat pumps sold so fast in Maine, the state just upped its target: https://www.canarymedia.com/articles/heat-pumps/heat-pumps-sold-so-fast-in-maine-the-state-just-upped-its-target
- U.S. Department of Energy, Residential Cold Climate Heat Pump Challenge: https://www.energy.gov/eere/buildings/residential-cold-climate-heat-pump-challenge