Using sensors on board platforms such as satellites and advanced modeling systems, European Union-(EU)-funded researchers have quantified the impact of future energy use on the environment. Their headline conclusion? That we can go further than the EU goal of increasing renewable energy’s contribution to global supply to 80% by 2050.
The production, transport, and consumption of energy all put considerable pressure on the environment. If the EU were to make changes to its energy mix, for example by relying more on biomass, solar, or wind energy, what would the impact be? Would it impact air pollution or human health? What about ecosystems, fresh water systems, or the biosphere? The EnerGEO project—an international organization funded by the EU’s 7th Framework Program—designed and built a system to evaluate this.
The team started by linking environmental observation systems already under the umbrella of the Global Earth Observation System of Systems (GEOSSs) with new energy models developed during the project.
One of the major challenges for EnerGEO was to connect a variety of observation systems, each focused on a very specific environmental question, with a large array of energy resources that have widely different impacts on the environment.
Finding a way for experts from very different specializations to work together went some way toward solving this, explains EnerGEO coordinator Martijn Schaap of the Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek (TNO) in The Netherlands: “People came from different backgrounds, which meant they were not talking the same language. We had to connect certain parts and understand how we could use each other’s expertise.”
By linking observation data and energy models, it is possible, for example, to have an idea of how much biomass is available, and then to estimate how much could be harvested. This, in turn, indicates how much energy could be produced from biomass.
EnerGEO also worked with data on air pollution trends and the presence of pollutants such as carbon monoxide and nitrogen dioxide.
Once the data had been connected to the team’s models, the whole system was applied to four scenarios:
• Baseline—current EU policies on limiting CO2 remain as they are;
• Open Europe—solar energy is imported to Europe from North Africa, the share of energy provided by biomass is high, and nuclear energy is phased out;
• Island Europe—no electricity is imported from outside of Europe, renewable energy use is equal to or higher than that in the Open Europe scenario, and nuclear energy use continues;
• Maximum Renewable Energy—renewable energy penetration is close to 100%.
Testing these scenarios showed that the potential of wind, solar, and biomass energy would make it possible to increase the share of energy from renewable sources by more than is currently targeted. “The targets can be more ambitious than the EU 80% target,” confirms Schaap.
Another key finding was confirmation that earth observation data can indeed be used to create spatial maps illustrating renewable energy potential. These would be useful for engineering consultants looking for the optimal location for new infrastructure, such as solar panels.
Many of the EnerGEO project partners are now working with the new modeling systems while continuing to develop them. Although no follow-up project is currently planned, Schaap would be keen to expand the EnerGEO system geographically and to other energy sources, such as geothermal and tidal energy, and to expand beyond electricity production. He also has further scenarios in mind for testing, including the impact of higher electric vehicle usage on electricity demand and consequent shifts in environmental impacts.