Related references
Note: Only part of the references are listed.Synthesis of Sintering-Resistant Sorbents for CO2 Capture
Wenqiang Liu et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2010)
Calcium Precursors for the Production of CaO Sorhents for Multicycle CO2 Capture
Wenqiang Liu et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2010)
Cyclic CO2 capture behavior of KMnO4-doped CaO-based sorbent
Yingjie Li et al.
FUEL (2010)
CO2 Carrying Behavior of Calcium Aluminate Pellets under High-Temperature/High-CO2 Concentration Calcination Conditions
Vasilije Manovic et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2010)
Study of the CO2/Sorbent Interaction in Sorbents Prepared with Mesoporous Supports and Calcium Compounds
Josefa Fernandez et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2010)
Behavior of CaTiO3/Nano-CaO as a CO2 Reactive Adsorbent
S. F. Wu et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2010)
CO2 looping cycles with CaO-based sorbent pretreated in CO2 at high temperature
Vasilije Manovic et al.
CHEMICAL ENGINEERING SCIENCE (2009)
Reactivity of CaO derived from nano-sized CaCO3 particles through multiple CO2 capture-and-release cycles
Nicholas H. Florin et al.
CHEMICAL ENGINEERING SCIENCE (2009)
The rate and extent of uptake of CO2 by a synthetic, CaO-containing sorbent
J. S. Dennis et al.
CHEMICAL ENGINEERING SCIENCE (2009)
Screening of Binders for Pelletization of CaO-Based Sorbents for CO2 Capture
Vasilije Manovic et al.
ENERGY & FUELS (2009)
Flame-Made Durable Doped-CaO Nanosorbents for CO2 Capture
Hong Lu et al.
ENERGY & FUELS (2009)
CaO-Based Pellets Supported by Calcium Aluminate Cements for High-Temperature CO2 Capture
Vasilije Manovic et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2009)
Modified CaO-based sorbent looping cycle for CO2 mitigation
Yingjie Li et al.
FUEL (2009)
Influence of calcination conditions on carrying capacity of CaO-based sorbent in CO2 looping cycles
Vasilije Manovic et al.
FUEL (2009)
Sintering and Reactivity of CaCO3-Based Sorbents for In Situ CO2 Capture in Fluidized Beds under Realistic Calcination Conditions
Dennis Y. Lu et al.
JOURNAL OF ENVIRONMENTAL ENGINEERING-ASCE (2009)
Parametric study on the CO2 capture capacity of CaO-based sorbents in looping cycles
Vasilije Manovic et al.
ENERGY & FUELS (2008)
CO2 looping cycle performance of a high-purity limestone after thermal activation/doping
Vasilije Manovic et al.
ENERGY & FUELS (2008)
Thermal activation of CaO-based sorbent and self-reactivation during CO2 capture looping cycles
Vasilije Manovic et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2008)
Sequential SO2/CO2 capture enhanced by steam reactivation of a CaO-based sorbent
Vasilije Manovic et al.
FUEL (2008)
Ca-based sorbent looping combustion for CO2 capture in pilot-scale dual fluidized beds
Dennis Y. Lu et al.
FUEL PROCESSING TECHNOLOGY (2008)
Solid looping cycles: A new technology for coal conversion
Edward J. Anthony
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2008)
Properties of a nano CaO/Al2O3 CO2 sorbent
Su F. Wu et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2008)
CO2 storage in geological media: Role, means, status and barriers to deployment
Stefan Bachu
PROGRESS IN ENERGY AND COMBUSTION SCIENCE (2008)
Properties of Ca-base CO2 sorbent using Ca(OH)2 as precursor
S. F. Wu et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2007)
The effect of CaO sintering on cyclic CO2 capture in energy systems
P. Sun et al.
AICHE JOURNAL (2007)
Cost structure of a postcombustion CO2 capture system using CaO
J. Carlos Abanades et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2007)
Change of CO2 carrying capacity of CaO in isothermal recarbonation-decomposition cycles
Anton I. Lysikov et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2007)
Regeneration of sintered limestone sorbents for the sequestration of CO2 from combustion and other systems
P. S. Fennell et al.
JOURNAL OF THE ENERGY INSTITUTE (2007)
Economics of CO2 capture using the calcium cycle with a pressurized fluidized bed combustor
A. MacKenzie et al.
ENERGY & FUELS (2007)
Steam reactivation of spent CaO-based sorbent for multiple CO2 capture cycles
Vasilije Manovic et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2007)
CO2 capture capacity of CaO in long series of carbonation/calcination cycles
Gemma S. Grasa et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2006)
Simultaneous CO2/SO2 capture characteristics of three limestones in a fluidized-bed reactor
Ho-Jung Ryu et al.
ENERGY & FUELS (2006)
Steam reactivation of 16 bed and fly ashes from industrial-scale coal-fired fluidized bed combustors
D Gora et al.
FUEL (2006)
Review-calcination and carbonation of limestone during thermal cycling for CO2 sequestration
BR Stamnore et al.
FUEL PROCESSING TECHNOLOGY (2005)
Design, process simulation and construction of an atmospheric dual fluidized bed combustion system for in situ CO2 capture using high-temperature sorbents
RW Hughes et al.
FUEL PROCESSING TECHNOLOGY (2005)
Synthesis, experimental studies, and analysis of a new calcium-based carbon dioxide absorbent
ZS Li et al.
ENERGY & FUELS (2005)
Fluidized bed combustion systems integrating CO2 capture with CaO
JC Abanades et al.
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2005)
Sorbent cost and performance in CO2 capture systems
JC Abanades et al.
INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH (2004)
Conversion limits in the reaction of CO2 with lime
JC Abanades et al.
ENERGY & FUELS (2003)
What future for carbon capture and sequestration?
H Herzog
ENVIRONMENTAL SCIENCE & TECHNOLOGY (2001)
Sulfation and reactivation characteristics of nine limestones
K Laursen et al.
FUEL (2000)