AirJoule Technologies Partners With Arizona State University To Supply High-Capacity AirJoule A250TM System For Water Harvesting Research, Demonstrating Over 4x Efficiency Compared To Traditional Moisture Removal Systems

Author: Benzinga Newsdesk | April 08, 2025 09:16am

AirJoule Technologies Corporation (NASDAQ:AIRJ) ("AirJoule Technologies" or the "Company"), the developer of the transformational AirJoule® system for separating pure water from air, today announced an agreement with Arizona State University ("ASU"), which is widely recognized as an international leader in the field of atmospheric water harvesting research. Under the binding agreement, ASU will purchase one AirJoule® A250TM unit, a high-capacity system capable of producing 250 liters of pure distilled water per day directly from ambient air.

AirJoule® utilizes advanced sorbents and a dual-chamber vacuum system to separate water from air. The proprietary dual-chamber design allows internally generated heat to be re-used in the system, which significantly reduces external power requirements. AirJoule® can also utilize low-grade waste heat from industrial operations to further reduce its energetics for separating moisture from air. Compared to conventional moisture removal systems, AirJoule® is over 4x more efficient than refrigerant-based systems and over 8x more efficient than desiccant systems when utilizing low-grade waste heat.

The AirJoule® A250TM unit purchased by ASU will be operated within the greater Phoenix area at various testing locations, where researchers will independently evaluate its performance across a range of real-world conditions, including arid climates and variable humidity levels. Phoenix, known for its hot desert climate, frequently experiences relative humidity levels below 20% – conditions that significantly impact the ability of conventional atmospheric water harvesting systems to function effectively. AirJoule®'s enhanced capability to produce pure distilled water in these dry conditions significantly expands its potential for deployment in water-stressed regions around the world.

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