Solaria's Garoña Solar Project: Powering Spain's Energy Transition

• Solaria receives authorization for 595MW Garoña photovoltaic project, aiming to power 300,000 homes and create 2,400 jobs, aligning with its goal to expand capacity to 3GW by 2024.

Spanish renewables developer Solaria has received administrative construction authorization for its 595MW Garoña photovoltaic project in Spain. The project, to be built on the site of the decommissioned Santa María de Garoña nuclear power plant, aligns with Solaria's goal to expand its capacity to 3GW by the end of 2024. The solar facility will generate enough clean energy to power 300,000 homes and meet the annual needs of the entire province of Burgos. The construction of the project is expected to create 2,400 jobs, with a focus on local employment, and will have a productive lifespan of 30 years.

Solaria Energía y Medio Ambiente (Solaria), a Spanish renewables developer, has received administrative construction authorization for its 595MW Garoña photovoltaic project in Spain. The project will be built on the site of the decommissioned Santa María de Garoña nuclear power plant in Burgos province. The solar facility aims to generate enough clean energy to power 300,000 homes and meet the annual needs of the entire province of Burgos. The construction of the project is expected to create 2,400 jobs, with a focus on local employment, and will have a productive lifespan of 30 years. Solaria plans to expand its capacity to 3GW by the end of 2024.

What are the key details of Solaria's 595MW Garoña photovoltaic project in Spain?

• Solaria's Garoña photovoltaic project is located in Spain.
• The project has a capacity of 595MW.
• The photovoltaic project utilizes solar energy to generate electricity.
• The project employs a dynamic hot air deposition technique for processing perovskite-organic hybrid tandem solar cells.
• The technique has resulted in a high efficiency rating of 23.07%.
• Solution-based processes and organic cation passivation are used to reduce VOC loss.
• The production process is simplified and does not require humidity-controlled environments.
• The solar cells are more stable at high temperatures of 65 °C and 85 °C compared to room temperature.
• In a practical 1 cm2 cell size, the solar cells can achieve an efficiency of up to 21.82%.
• Ongoing efforts are focused on further encapsulation and development of the tandem solar cell architecture.
• The aim is to eventually achieve a practical efficiency of 29.1%.