Sustainable AI
WAIYS is committed to UN sustainability goals
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We integrate ESG factors into all our activities, guided by the 17 United Nations Sustainable Development Goals (SDGs), including clean energy and water and sanitation, adopted by UN member states in 2015. Additionally, we are committed to the "Zero Routine Flaring by 2030" initiative introduced by the World Bank.
UN Sustainable Development Goals
At WAIYS, we develop and deploy technology solutions to address environmental challenges in the energy sector while supporting the growing demand for computing power. Our solutions create tangible benefits for the countries and communities in which we operate by driving infrastructure investment and generating jobs in rapidly growing and essential sectors. WAIYS also maintains active engagement with governments worldwide, supporting effective climate planning, advancing zero-flaring strategies, and promoting sustainable digitalization solutions.
Contribution to Net-Zero
Did you know that as part of WAIYS’s commitment to reducing environmentally damaging GHG emissions and making a positive contribution on the journey to a net-zero world we have partnered with Trefadder, Norway’s largest player in biological carbon capture, to plant trees in our home country of Norway to capture CO2, helping to create a better climate and create local jobs.
Optimizing AI for a Sustainable Future
WAIYS is dedicated to advancing sustainability and energy efficiency in the AI sector. AI technologies consume increasing amounts of energy which we counteract by integrating advanced technologies that optimize energy use and minimize waste. One key aspect of this approach is the deployment of energy-efficient chip technologies designed to perform high-computing tasks with minimal power requirements (such as SambaNova's SN40L or Cerebras' WSE-3). Additionally, WAIYS utilizes advanced liquid cooling technology in its data center containers. By directly cooling computing components with liquid instead of relying on traditional air-based systems. This approach significantly lowers power consumption, extends hardware lifespan, and makes waste heat easily available for repurposing. The excess heat from the computing processes is captured and directly fed into heating facilities such as local or district heating. This waste heat recovery further enhances resource utilization and supports a circular economy.