The utilization of supercritical carbon dioxide (sCO 2) in the Brayton cycle presents several
advantages, such as compact equipment, high efficiency, and rapid response time. The sCO …

Supercritical carbon dioxide (SCO2) is widely used in many fields of energy and power
engineering, such as nuclear reactors, solar thermal power generation systems, and …

Recently, the development and exploitation of renewables-driven multigeneration systems
can be a sensible solution to reduce the limitations of fossil energies and their negative …

Abstract A modified recompression S–CO 2 Brayton cycle (RCSCBC) that combines
advantages of the preheated S–CO 2 Brayton cycle (PSCBC) is proposed to recovery the …

Integrating Brayton cycles, utilizing supercritical carbon dioxide (sCO 2) as a working
medium, with a concentrating solar power (CSP) system is an attractive solution to enable …

The availability of ample solar energy resources holds significant importance for populated
islands as it represents a vital avenue for ensuring sustainable energy provision while …

Waste-to-energy conversion technologies have been attracted extensive attentions due to
the promising contribution not only to the municipal waste disposal but also to the electricity …

The energy storage system plays a pivotal role in optimizing the power grid's peak
mobilization. In this study, we propose a combined cycle of supercritical carbon dioxide …

Compressed carbon dioxide energy storage (CCES) systems are beneficial for power grids
as they absorb energy from intermittent renewable energy sources. This study proposes a …

The transient performance of an inventory-controlled supercritical CO 2 recompression cycle
under synchronous adjustment of parameters has rarely been studied. In this study, a one …