Impact of energy storage on reducing dependence on fossil fuels

Introduction

Energy storage is currently a major topic of interest in renewable energy dialogues and conferences, with a view to transition to a sustainable energy future. Storage technology offers different alternative solutions to reduce dependence on traditional energy sources derived from fossil fuels, which have dominated the energy landscape since the industrial revolution.

Stored energy facilitates greater integration of renewable sources into the power grid, contributing significantly to reducing greenhouse gas emissions, increasing energy security and optimizing economic and environmental efficiency. Throughout this article, we discuss how various energy storage technologies are forging a more resilient and sustainable energy infrastructure, highlighting their relevance and applicability in the current context.

What is energy storage?

It is a process that involves the collection and conservation of energy using special storage systems for its subsequent controlled release. This technology is necessary to balance supply and demand on the power grid, especially for renewable energy sources, whose production can be unpredictable and not aligned with peak demand. Although traditionally a costly process, technological advances have simplified and improved the costs of retaining surplus energy. Below is a representative image of a storage system that receives and distributes solar energy.

Fossil fuel dependence: Definition and historical context

Since the Industrial Revolution, fossil fuels: oil, coal and natural gas, have been the protagonists in the world’s energy development. They stand out for their high energy density and relative ease of access; in addition, the existence of wells and the ease of extraction and transportation have made them the predominant energy sources for more than a century. However, this dependence has generated sustained challenges over time in environmental and socioeconomic terms.

Problems associated with dependence on fossil fuels

• Negative environmental impacts: The intensive use of fossil fuels is the main contributor to greenhouse gas emissions, aggravating global climate change. Dependence on traditional energy sources has caused multiple impacts on the atmosphere, climate and additionally causes health and food security problems due to air and water pollution.
• Risks to energy and economic security: The volatility of oil and gas prices, together with the geographic concentration of fossil resources, creates economic instability and geopolitical vulnerability. This dependence compromises the energy security of certain nations, forcing them to rely on imports and exposing them to price fluctuations and political conflicts.

Transition to sustainable alternatives

In the face of these adversities, the transition to more sustainable storage systems must be accelerated, representing an important technological solution that allows greater independence from fossil fuels through the efficient integration of renewable energies such as solar and wind, among others. This transition would mitigate the negative environmental impacts associated with fossil fuels, and strengthen global energy and economic security.

How energy storage reduces dependence on fossil fuels

The transition to a future less dependent on fossil fuels is indispensable for long-term sustainability, which is a focal point in this shift, enabling the effective integration of renewable energies and offering a sustainable alternative for energy demand management. The following sections summarize how innovations in storage technologies, with their global deployment and associated benefits, are facilitating a decline in traditional energy sources:

Energy storage technologies

Large-scale energy storage is one of the main processes in the transition to a more sustainable energy system. Technologies such as lithium-ion, lead-acid and sodium-ion batteries, thermal storage systems and compressed air storage, among others, are fundamental. It is important to recognize that battery energy storage systems (BESS) project the future of the clean energy transition.

These technologies provide a rapid response to energy demand without resorting to traditional energy sources, as well as maximizing the efficiency of renewable energies by storing surplus during production peaks and releasing it during deficits. A representative diagram of a compressed air energy storage system (CAES) is shown below.

Integration of renewable energies with storage systems

The ability to store energy facilitates greater inclusion of renewables into the power grid. By compensating for their intermittent nature, storage allows sources such as solar, wind and geothermal to become more reliable and predictable. This integration forms part of the foundation for a sustainable energy system, allowing for a gradual and stable transition away from fossil fuels toward cleaner, more sustainable energy alternatives.

Economic and energy security benefits

Energy storage economically enables savings by taking advantage of low energy tariffs and storing it for use when prices rise, thus reducing dependence on fossil fuel prices. In terms of energy security, it guarantees a reliable supply even when weather conditions affect renewable energy generation, reducing the need for fossil fuels; it also boosts employment in this sector.

Examples of successful projects

• Alamitos BESS project: Conducted in collaboration with Southern California Edison and Fluence, it marked a milestone in the history of the energy storage industry, being the first global project intended to replace the functions of a natural gas plant and receive a long-term power purchase agreement.

This project demonstrated the feasibility of large-scale battery energy storage, showing its ability to meet the demands of a modern, flexible grid. Its success established a model for future initiatives, promoting this process as a solution to reduce dependence on fossil fuels and move towards a carbon-free energy future¹.

• Edwards & Sanborn Project: This is an exemplary case in the U.S. renewable energy industry, highlighting the importance of energy storage in reducing dependence on fossil fuels. This facility is one of the largest of its kind, covering 4,600 acres and is equipped with more than 1.9 million First solar modules, generating 875 MWdc of solar power.

It also has a storage capacity of 3,287 megawatt-hours, facilitating the efficient integration of renewable energy into the grid. This project supplies clean energy to major consumers and several California utilities, and allows for the optimization of the area’s electric grid. It represents an advanced and effective model of how solar energy combined with storage solutions can support the transition to a sustainable energy future².

Benefits of energy storage for the environment

This process offers multiple benefits for ecosystems that are basic in the dispute against dependence on fossil fuels:

1. Reduced greenhouse gas emissions: energy storage facilitates the use of renewable energy, reducing the activation of fossil fuel plants during peak demand. This directly decreases CO2 emissions, supporting a low-carbon economy.
2. Improved energy efficiency: By storing energy when demand is low and using it when demand increases, the use of energy resources is optimized, reducing wasted generation and fossil fuel consumption.
3. Conservation of natural resources: The use of energy storage reduces dependence on fossil fuels, which leads to less extraction of these resources, benefiting environmental conservation and reducing the degradation and pollution associated with the extraction and use of these resources.
4. Reduced impact on biodiversity: Energy storage minimizes the need to build new energy infrastructure in sensitive areas, such as forests or unique ecosystems, helping to preserve biodiversity and natural habitats. By reducing habitat fragmentation and wildlife disturbance, this process directly contributes to the conservation of the natural environment.

These aspects point to how energy storage benefits the transition to a more sustainable energy future that is less dependent on fossil fuels, and in favor of climate change mitigation and natural resource conservation.

Accelerating global adoption of energy storage

The expansion of energy storage worldwide is being driven by a number of factors. These include growing interest in renewable energy, the need to mitigate climate change, and technological advances that have reduced the cost and improved the efficiency of these solutions. As renewable energy generation becomes more common, storage becomes critical to ensure a stable and reliable electricity supply.

To accelerate the transition to a more sustainable energy future, a number of strategies need to be implemented. These include investing in research and development to improve storage technologies, fostering collaboration between governments, the public and private sectors, establishing clear and flexible regulatory frameworks, and developing markets that allow owners of storage systems to sell excess energy.

Conclusions

Energy storage is presented as an alternative solution needed to mitigate dependence on fossil fuels and move more feasibly towards a sustainable energy future. Its ability to effectively integrate renewable energy sources allows power grid optimization, these systems contribute to the reduction of carbon emissions, and also improve global energy security and efficiency.

As technology evolves and costs decline, the deployment of energy storage is set to accelerate, offering innovative solutions to tomorrow’s energy and environmental challenges. Through appropriate policies and international cooperation, this transition can be accelerated and ensure a cleaner environment for future generations.

References

1. https://www.aes.com/aes-alamitos-battery-energy-storage-system-launched-energy-storage-industry-we-know-it-0. Accessed 24 July 2024.
2. https://www.mortenson.com/newsroom/edwards-sanborn-solar-storage-completion. Accessed 24 July 2024.