Sustainable Energy Systems

Topic Information

Dear Colleagues,

Sustainable energy systems are at the forefront of scientific research due to their potential to combat climate change, promote energy security, and reduce environmental degradation. These systems, based on renewable energy sources, seek to meet global energy demands while minimizing the negative impacts of traditional fossil fuel use. Scientific interest in sustainable energy systems spans multiple disciplines, addressing challenges from energy generation to technological integration in key sectors like agriculture, buildings, and cities.

From a general perspective, sustainable energy systems include renewable energy sources such as solar, wind, geothermal, and bioenergy. These systems generate clean, renewable energy, which helps reduce carbon emissions and fossil fuel dependence. However, optimizing these systems to meet the fluctuating energy demands while ensuring reliability and efficiency remains a major focus of research. Innovations in energy storage and grid integration are key to expanding their scalability and applicability across different regions.

Sensor technologies are essential for the efficient management of sustainable energy systems. Sensors monitor energy production, consumption, and system performance in real time, providing valuable data for optimizing operations. In agriculture, sensors enable precision farming by managing energy-intensive processes like irrigation. In buildings and cities, smart sensors are used to regulate lighting, heating, cooling, and overall energy consumption, thereby improving efficiency and reducing waste. The integration of these sensors with the Internet of Things (IoT) further enhances the effectiveness of energy systems by enabling automated adjustments and predictive maintenance.

From a technological standpoint, energy storage solutions are a critical area of research. Technologies such as advanced batteries, hydrogen storage, and thermal storage systems allow renewable energy to be stored and used when needed, addressing the intermittency of sources like solar and wind. Additionally, smart grids and microgrids, which incorporate decentralized renewable energy sources, are emerging as important components of sustainable energy infrastructures. These technologies allow for better control, distribution, and management of energy flows, leading to improved reliability and resilience in energy systems.

The applications of sustainable energy systems are expanding in diverse sectors. In agriculture, renewable energy powers efficient irrigation systems, farm machinery, and cold storage, reducing energy costs and improving sustainability. Solar-powered water pumps and wind turbines provide off-grid energy solutions for rural farms, while biogas from agricultural waste offers a circular approach to energy production. In buildings, sustainable energy technologies like solar panels, energy-efficient insulation, and smart HVAC systems lower energy demand, reduce emissions, and improve building sustainability. Cities are also adopting sustainable energy systems, with smart grids, renewable-powered public infrastructure, and electric vehicle (EV) charging stations becoming increasingly prevalent. These innovations are crucial for reducing urban carbon footprints and improving energy management in densely populated areas.

New trends in sustainable energy systems include the development of hybrid renewable energy systems, which combine multiple energy sources (e.g., solar and wind) to improve reliability and efficiency. In agriculture, the rise of agrivoltaics—where solar panels are installed over crops—optimizes land use by generating electricity while protecting crops. In buildings, net-zero energy buildings (NZEBs) are becoming a significant focus, where buildings are designed to generate as much energy as they consume. In cities, decentralized energy systems such as microgrids are becoming more prominent, providing communities with localized energy generation and distribution. The application of artificial intelligence (AI) and machine learning is also advancing, allowing for the real-time optimization of energy production, distribution, and consumption, as well as predictive maintenance for energy infrastructure.

The transition to sustainable energy systems is essential to address the growing challenges of climate change and energy security. Research plays a pivotal role in developing innovative solutions that optimize energy efficiency, integrate renewable resources, and minimize environmental impact. Within this context, vehicles serve as fundamental agents of transformation. By advancing technologies such as electric mobility, hydrogen-powered engines, and smart transportation systems, vehicles not only reduce emissions but also act as catalysts for cleaner, more sustainable energy ecosystems. For example, agricultural vehicles hold a particularly vital role in this transition, as they are key to enhancing the sustainability of the farming sector. By integrating renewable energy sources, precision farming technologies, and low-emission powertrains, these vehicles can reduce environmental impact while boosting efficiency and productivity. Their evolution is instrumental in building a sustainable future for both agriculture and energy systems.

In conclusion, sustainable energy systems are a crucial area of scientific research, with applications across agriculture, buildings, and cities. These systems offer solutions to pressing global challenges such as climate change, energy security, and resource depletion. Innovations in sensor technologies, energy storage, and smart grids are helping to optimize these systems, making them more efficient and scalable. As new trends continue to emerge, sustainable energy systems will play an increasingly important role in shaping a low-carbon, resilient energy future.

Prof. Dr. Luis Hernández-Callejo
Prof. Dr. Carlos Meza Benavides
Dr. Jesús Armando Aguilar Jiménez
Topic Editors

Keywords

Participating Journals

Journal Name	Impact Factor	CiteScore	Launched Year	First Decision (median)	APC
Agriculture agriculture	3.3	4.9	2011	19.2 Days	CHF 2600	Submit
Energies energies	3.0	6.2	2008	16.8 Days	CHF 2600	Submit
Vehicles vehicles	2.4	4.1	2019	19.9 Days	CHF 1600	Submit
World Electric Vehicle Journal wevj	2.6	4.5	2007	16.2 Days	CHF 1400	Submit
Sensors sensors	3.4	7.3	2001	18.6 Days	CHF 2600	Submit
Sustainability sustainability	3.3	6.8	2009	19.7 Days	CHF 2400	Submit
Urban Science urbansci	2.1	4.3	2017	20.7 Days	CHF 1600	Submit

MDPI Topics is cooperating with Preprints.org and has built a direct connection between MDPI journals and Preprints.org. Authors are encouraged to enjoy the benefits by posting a preprint at Preprints.org prior to publication:

1. Immediately share your ideas ahead of publication and establish your research priority;
2. Protect your idea from being stolen with this time-stamped preprint article;
3. Enhance the exposure and impact of your research;
4. Receive feedback from your peers in advance;
5. Have it indexed in Web of Science (Preprint Citation Index), Google Scholar, Crossref, SHARE, PrePubMed, Scilit and Europe PMC.

Published Papers