Gigatonne scale geological storage of carbon dioxide and energy (such as hydrogen) will
be central aspects of a sustainable energy future, both for mitigating CO2 emissions and …

The decarbonization of industry and industrial systems is a pressing challenge given the
relative lack of low-carbon options available for “hard to decarbonize” sectors such as …

The mitigation scenarios database of the Intergovernmental Panel on Climate Change's
Sixth Assessment Report is an important resource for informing policymaking on energy …

The urbanization and increase in the human population has significantly influenced the
global energy demands. The utilization of non-renewable fossil fuel-based energy …

With the proposal to achieve carbon neutrality by the mid-21st century, carbon capture,
utilization, and storage (CCUS) as a critical negative carbon technology is receiving …

Climate change mitigation requires the large-scale deployment of carbon capture and
storage (CCS). Recent plans indicate an eight-fold increase in CCS capacity by 2030, yet …

The total emission mitigation potential achievable by the year 2030, calculated based on
sectoral assessments, is sufficient to reduce global greenhouse gas emissions to half of the …

Carbon capture (ie, CO2 capture) and storage (CCS) and carbon capture and utilization
(CCU) are recognized as potential pathways to combat global climate change. Numerous …

Due to the small scale and few functions of the single integrated energy system, the
absorption capacity of wind turbine and photovoltaic is limited, the ability to cope with …

The Paris climate goals and the Glasgow Climate Pact require anthropogenic carbon
dioxide (CO 2) emissions to decline to net zero by mid-century. This will require overcoming …