A journey to the place where in 1904 lightbulbs were lit by current from the Earth's interior for the first time. Tuscan Larderello is the cradle of global geothermal energy and a unique example of using "dry steam" technology, which despite the passage of a century still powers millions of Italian households.

This is the most important European reference point for Polish geothermal investments. Unterhaching near Munich proves that deep geothermal in sedimentary rocks – just like in Poland – can be an efficient and profitable heat source for cities, without the need for neighboring volcanoes.

Can a power plant create one of the world's biggest tourist attractions? The story of Svartsengi proves yes. Learn how "waste" from energy production gave rise to the famous Blue Lagoon and how the "Resource Park" concept allows utilizing every drop of extracted brine.

Located on the Hengill volcanic ridge, Hellisheiði is not only one of the world's largest geothermal power plants, but also a climate innovation testing ground. Read about how Icelanders combine electricity and heat production with the revolutionary CarbFix method, which turns emitted carbon dioxide into stone.

Polish geothermal relies on two radically different geological models, making the comparison of Podhale and Stargard fascinating – both regions achieve success but fight completely different natural challenges.

Against the background of Polish geothermal heating plants, Stargard stands out both in scale of production and innovative method of integration with the municipal heating network.

Thanks to utilizing natural geothermal resources, the city is improving its heating system, limiting pollution emissions, and stabilizing heating costs – this is an important step towards clean and modern urban energy.

For over two decades, the installation has been supplying heat to residents, supporting the region's recreational offer, and – in a unique way – participating in the drinking water supply system.

The installation in Poddębice combines an ecological heat source with the development of thermal recreation, health balneological services, and the possibility of using thermal waters as drinking water, making it unique also in socio-cultural terms.

Thanks to utilizing heat accumulated deep beneath the earth's surface, the city has been minimizing fossil fuel consumption and reducing pollutant emissions since the 90s, while ensuring residents receive ecological thermal energy.

The project relies on the exploitation of warm underground waters occurring in the geological structures of the Polish Lowlands and constitutes a significant element of the region's energy transformation aimed at reducing emissions and improving air quality.

In this article, we present the key advantages of the G-Term Energy system, which determine its technological, economic, and ecological superiority.

In the process of heating Stargard with energy from the earth's interior, three separate and completely isolated circuits play a key role. Thanks to this, extracted brine never mixes with network water, and the system operates at highest efficiency.

The viability of using thermal waters depends on a confluence of natural (geological) and infrastructural parameters. In 2025, with rising CO₂ emission costs, geothermal energy is becoming one of the most price-stable alternatives to coal and gas.

Green revolution on the Ina river: How Stargard transformed its energy mix and environmental state in 15 years.

Although Poland is not associated with geysers and volcanoes, immense energy potential slumbers beneath our country's surface. From Podhale, through Mazovia, to Western Pomerania – geothermal waters are becoming a key element of energy transformation. We look at what the map of Polish geothermal looks like and which installations set development directions.

If one were to line up all the wagons with coal that thanks to geothermal didn't need to be burned in Stargard, they would form a line stretching for tens of kilometers. Data for the years 2012–2025 clearly show: G-Term Energy is not just a heat supplier, it is primarily a powerful shield protecting the air above our city.

Although Poland is not associated with geysers and volcanoes, immense energy potential slumbers beneath our country's surface. From Podhale, through Mazovia, to Western Pomerania – geothermal waters are becoming a key element of energy transformation. We look at what the map of Polish geothermal looks like and which installations set development directions.

Stargard's true energy capital lies over 2.5 kilometers beneath our feet. This is where the thermal water resources are located, placing our city at the forefront of the green transformation. The key to success in their exploitation is the combination of unique natural conditions with precise technology developed by G-Term Energy.

In the process of extracting energy from the earth's interior, there is a key moment where the raw force of nature meets urban technology – this is the heat exchange stage. Although water extracted from a depth of almost 3 kilometers possesses an impressive temperature of 90°C, it never goes directly into the municipal network. How then does it heat our homes? The answer lies in advanced technology.

Once the network water has been heated by the Geotermia Stargard exchangers, it sets off on a journey through an extensive system of pipelines weaving through our city. This is the stage residents feel directly, turning on thermostatic valves in their apartments or using domestic hot water from their taps.

The European Union recognizes geothermal as a strategic energy source. In 2025, regulations facilitating its development came into force, especially in Central European countries.

Modern closed-loop geothermal technologies are becoming a viable alternative to classic boreholes. Eavor Loop and similar solutions are changing the industry landscape.

The global geothermal sector is accelerating at a pace unseen for two decades, with record investments flowing from both Europe and Asia. More and more countries are treating geothermal energy as a key element of energy transformation.

A journey to the place where in 1904 lightbulbs were lit by current from the Earth's interior for the first time. Tuscan Larderello is the cradle of global geothermal energy and a unique example of using "dry steam" technology, which despite the passage of a century still powers millions of Italian households.

This is the most important European reference point for Polish geothermal investments. Unterhaching near Munich proves that deep geothermal in sedimentary rocks – just like in Poland – can be an efficient and profitable heat source for cities, without the need for neighboring volcanoes.

Can a power plant create one of the world's biggest tourist attractions? The story of Svartsengi proves yes. Learn how "waste" from energy production gave rise to the famous Blue Lagoon and how the "Resource Park" concept allows utilizing every drop of extracted brine.

Located on the Hengill volcanic ridge, Hellisheiði is not only one of the world's largest geothermal power plants, but also a climate innovation testing ground. Read about how Icelanders combine electricity and heat production with the revolutionary CarbFix method, which turns emitted carbon dioxide into stone.

Icelandic technology and Chinese scale created the world's largest district heating system powered by geothermal energy. Discover the project in Xiong’an, which thanks to 100% reinjection technology became a global model for fighting smog and proof that geothermal can effectively replace coal in great metropolises.

The Bańska PGP-4 well in Szaflary, completed in 2025, will likely enable the tapping of thermal waters with temperatures significantly exceeding 100°C. This is a historic success opening the way for Poland to a new era of renewable energy.

Polish geothermal relies on two radically different geological models, making the comparison of Podhale and Stargard fascinating – both regions achieve success but fight completely different natural challenges.

Against the background of Polish geothermal heating plants, Stargard stands out both in scale of production and innovative method of integration with the municipal heating network.

Thanks to utilizing natural geothermal resources, the city is improving its heating system, limiting pollution emissions, and stabilizing heating costs – this is an important step towards clean and modern urban energy.

For over two decades, the installation has been supplying heat to residents, supporting the region's recreational offer, and – in a unique way – participating in the drinking water supply system.

The installation in Poddębice combines an ecological heat source with the development of thermal recreation, health balneological services, and the possibility of using thermal waters as drinking water, making it unique also in socio-cultural terms.

Thanks to utilizing heat accumulated deep beneath the earth's surface, the city has been minimizing fossil fuel consumption and reducing pollutant emissions since the 90s, while ensuring residents receive ecological thermal energy.

The project relies on the exploitation of warm underground waters occurring in the geological structures of the Polish Lowlands and constitutes a significant element of the region's energy transformation aimed at reducing emissions and improving air quality.

Thanks to geothermal, the city has become one of the country's most important centers of green energy and spa thermal services.

Thanks to utilizing underground thermal resources, the city increases energy security, limits pollution emissions, and develops renewable energy sources.

A modern renewable energy source installation that has been powering the municipal heating network since 2025 and fits into the city's sustainable development strategy.

The project, initiated in the early 90s, became the foundation of the region's energy transformation and one of the key tools in the fight against low-stack emission.

In this article, we present the key advantages of the G-Term Energy system, which determine its technological, economic, and ecological superiority.

The foundation of operational safety is an advanced system of geothermal doublets, based on the close cooperation of production and injection wells.

In the process of heating Stargard with energy from the earth's interior, three separate and completely isolated circuits play a key role. Thanks to this, extracted brine never mixes with network water, and the system operates at highest efficiency.

The viability of using thermal waters depends on a confluence of natural (geological) and infrastructural parameters. In 2025, with rising CO₂ emission costs, geothermal energy is becoming one of the most price-stable alternatives to coal and gas.

Green revolution on the Ina river: How Stargard transformed its energy mix and environmental state in 15 years.

Although Poland is not associated with geysers and volcanoes, immense energy potential slumbers beneath our country's surface. From Podhale, through Mazovia, to Western Pomerania – geothermal waters are becoming a key element of energy transformation. We look at what the map of Polish geothermal looks like and which installations set development directions.

If one were to line up all the wagons with coal that thanks to geothermal didn't need to be burned in Stargard, they would form a line stretching for tens of kilometers. Data for the years 2012–2025 clearly show: G-Term Energy is not just a heat supplier, it is primarily a powerful shield protecting the air above our city.

Although Poland is not associated with geysers and volcanoes, immense energy potential slumbers beneath our country's surface. From Podhale, through Mazovia, to Western Pomerania – geothermal waters are becoming a key element of energy transformation. We look at what the map of Polish geothermal looks like and which installations set development directions.

Stargard's true energy capital lies over 2.5 kilometers beneath our feet. This is where the thermal water resources are located, placing our city at the forefront of the green transformation. The key to success in their exploitation is the combination of unique natural conditions with precise technology developed by G-Term Energy.

In the process of extracting energy from the earth's interior, there is a key moment where the raw force of nature meets urban technology – this is the heat exchange stage. Although water extracted from a depth of almost 3 kilometers possesses an impressive temperature of 90°C, it never goes directly into the municipal network. How then does it heat our homes? The answer lies in advanced technology.

Once the network water has been heated by the Geotermia Stargard exchangers, it sets off on a journey through an extensive system of pipelines weaving through our city. This is the stage residents feel directly, turning on thermostatic valves in their apartments or using domestic hot water from their taps.

The European Union recognizes geothermal as a strategic energy source. In 2025, regulations facilitating its development came into force, especially in Central European countries.

Modern closed-loop geothermal technologies are becoming a viable alternative to classic boreholes. Eavor Loop and similar solutions are changing the industry landscape.

The global geothermal sector is accelerating at a pace unseen for two decades, with record investments flowing from both Europe and Asia. More and more countries are treating geothermal energy as a key element of energy transformation.

The City of Vienna is implementing a breakthrough project using deep geothermal energy to power the district heating system, and its progress has been noted by The New York Times. Among the technical partners of the venture is RED Drilling GmbH, providing specialized drilling services – a significant contribution to the development of sustainable urban heating.