Currently most of the hydrogen produced worldwide is obtained by reforming fossil fuels.
The advancement and use of carbon capture and sequestration technologies ensure the CO …

Biodiesel production from waste oils is an attractive option to produce biodiesel
economically, but high free fatty acids (FFA) in waste oils are a serious bottleneck for the …

Annually billions of cubic meters of natural gas are flared around the globe at various oil and
gas production sites. Natural gas flaring practices waste valuable energy resources that can …

In recent years, the potential of Solid oxide fuel cell (SOFC) technologies as energy
conversion devices with high efficiency and zero‑carbon emissions has been …

The high volumetric energy density and easy storage capability of liquid hydrocarbons such
as bio-diesel or diesel are needed for power generation in several applications such as …

Solid oxide fuel cell (SOFC) recently emerges as a promising technology for distributed
power generation with high energy efficiency. While H 2 production and delivery are still the …

The limitations of conventional fuel reforming power generation systems lie in their capability
to reform only a single type of fuel, restricted by both the catalyst and system design. This …

Despite significant interest in optimizing solid oxide fuel cell (SOFC) combined heat and
power (CHP) systems, a gap exists in systematic, top-down methods for refining …

This chapter focuses on hydrogen production by steam reforming from nonrenewable
feedstocks. It starts with the fundamentals of natural gas steam reforming, main reactions …

Distributed hydrogen generation from liquid fuels has attracted increasing attention in the
past years. Petroleum-derived fuels with already existing infrastructure benefit from high …