Edward J. Anthony scite author profile

In recent years, Carbon Capture and Storage (Sequestration) (CCS) has been proposed as a potential method to allow the continued use of fossil-fuelled power stations whilst preventing emissions of CO 2 from reaching the atmosphere. Gas, coal (and biomass)-fired power stations can respond to changes in demand more readily than many other sources of electricity production, hence the importance of retaining them as an option in the energy mix. Here, we review the leading CO 2 capture technologies, available in the short and long term, and their technological maturity, before discussing CO 2 transport and storage. Current pilot plants and demonstrations are highlighted, as is the importance of optimising the CCS system as a whole. Other topics briefly discussed include the viability of both the capture of CO 2 from the air and CO 2 reutilisation as climate change mitigation strategies. Finally, we discuss the economic and legal aspects of CCS.

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The calcium looping cycle for large-scale CO2 capture

Blamey

Anthony

Wang

et al. 2010

Progress in Energy and Combustion Science

872

706

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An overview of advances in biomass gasification

Sikarwar

Zhao

Clough

et al. 2016

Energy Environ. Sci.

876

377

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Biomass gasification is a widely used thermochemical process for obtaining products with more value and potential applications than the raw material itself. Cutting-edge, innovative and economical gasification techniques with high efficiencies are a prerequisite for the development of this technology. This paper delivers an assessment on the fundamentals such as feedstock types, the impact of different operating parameters, tar formation and cracking, and modelling approaches for biomass gasification. Furthermore, the authors comparatively discuss various conventional mechanisms for gasification as well as recent advances in biomass gasification. Unique gasifiers along with multi-generation strategies are discussed as a means to promote this technology into alternative applications, which require higher flexibility and greater efficiency. A strategy to improve the feasibility and sustainability of biomass gasification is via technological advancement and the minimization of socio-environmental effects. This paper sheds light on diverse areas of biomass gasification as a potentially sustainable and environmentally friendly technology

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Thermal Activation of CaO-Based Sorbent and Self-Reactivation during CO₂ Capture Looping Cycles

Manović

Anthony

2008

Environ. Sci. Technol.

366

317

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In this study, the thermal activation of different types of CaO-based sorbents was examined. Pretreatments were performed at different temperatures (800--1300 degrees C) and different durations (6--48 h) using four Canadian limestones. Sieved fractions of the limestones, powders obtained by grinding, and hydroxides produced following multiple carbonation/calcination cycles achieved in a tube furnace were examined. Pretreated samples were evaluated using two types of thermogravimetric reactors/ analyzers. The most important result was that thermal pretreatment could improve sorbent performance. In comparison to the original, pretreated sorbents showed better conversions over a longer series of CO2 cycles. Moreover, in some cases, sorbent activity actually increased with cycle number, and this effectwas especially pronounced for powdered samples preheated at 1000 degrees C. In these experiments, the increase of conversion with cycle number (designated as self-reactivation) after 30 cycles produced samples that were approximately 50% carbonated for the four sorbents examined here, and there appeared to be the potential for additional increase. These results were explained with the newly proposed pore--skeleton model. This model suggests, in addition to changes in the porous structure of the sorbent, that changes in the pore--skeleton produced during pretreatment strongly influence subsequent carbonation/ calcination cycles.

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Fluidized Bed Combustion Systems Integrating CO₂Capture with CaO

Abanades

Anthony

Wang

et al. 2005

Environ. Sci. Technol.

399

332

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Capturing CO2 from large-scale power generation combustion systems such as fluidized bed combustors (FBCs) may become important in a CO2-constrained world. Using previous experience in capturing pollutants such as SO2 in these systems, we discuss a range of options that incorporate capture of CO2 with CaO in FBC systems. Natural limestones emerge from this study as suitable high-temperature sorbents for these systems because of their low price and availability. This is despite their limited performance as regenerable sorbents. We have found a range of process options that allow the sorbent utilization to maintain a given level of CO2 separation efficiency, appropriate operating conditions, and sufficiently high power generation efficiencies. A set of reference case examples has been chosen to discuss the critical scientific and technical issues of sorbent performance and reactor design for these novel CO2 capture concepts.

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Sulfation phenomena in fluidized bed combustion systems

Anthony

Granatstein

2001

Progress in Energy and Combustion Science

384

282

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Capture of CO₂ from combustion gases in a fluidized bed of CaO

et al. 2004

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Edward J. Anthony

Carbon capture and storage (CCS): the way forward

Carbon capture and storage update

The calcium looping cycle for large-scale CO2 capture

An overview of advances in biomass gasification

Thermal Activation of CaO-Based Sorbent and Self-Reactivation during CO₂ Capture Looping Cycles

Fluidized Bed Combustion Systems Integrating CO₂Capture with CaO

Sulfation phenomena in fluidized bed combustion systems

Capture of CO₂ from combustion gases in a fluidized bed of CaO

Contact Info

Product

Resources

About

Edward J. Anthony

Carbon capture and storage (CCS): the way forward

Carbon capture and storage update

The calcium looping cycle for large-scale CO2 capture

An overview of advances in biomass gasification

Thermal Activation of CaO-Based Sorbent and Self-Reactivation during CO2 Capture Looping Cycles

Fluidized Bed Combustion Systems Integrating CO2Capture with CaO

Sulfation phenomena in fluidized bed combustion systems

Capture of CO2 from combustion gases in a fluidized bed of CaO

Contact Info

Product

Resources

About

Thermal Activation of CaO-Based Sorbent and Self-Reactivation during CO₂ Capture Looping Cycles

Fluidized Bed Combustion Systems Integrating CO₂Capture with CaO

Capture of CO₂ from combustion gases in a fluidized bed of CaO