Atmospheric CO2 Enrichment and Delivery (ACED)

Klaus Lackner (Inventor), Bruce Rittmann (Inventor)

Research output: Patent

Abstract

Microalgae are very useful biological systems for capturing carbon dioxide (CO2 ) and generating biomass and many useful products. Increasing the CO2 concentration in gas supplied to a microalgae growth system can improve its productivity many fold over using atmospheric air. Flue gas could be a good source of CO2 -enriched gas; however, its usefulness is compromised by transportation costs and toxic contaminants that can introduce impurities into fuel or other high value products. Researchers at Arizona State University have developed systems and methods for capturing and concentrating CO2 from the atmosphere and delivering the concentrated CO2 to microalgae growth systems. This system is highly efficient and delivers CO2 at a rate that is great enough to promote high biomass-production rates in closed or open systems. This system creates a concentrated stream of CO2 similar to flue gas, but is located at the site of microalgae growth (eliminating transportation costs and risks) and it doesnt contain contaminants. This system can enable the high microalgae productivity needed to meet the significant global demand for high-density liquid transportation fuels and lower production costs. Potential Applications ?CO2 capture and concentration for delivery into microalgae growth systems ?Production of renewable biofuels ?Production of animal and fish feed ?Production of bioplastics/biopolymers ?Production of fine chemicals (agrochemicals, specialty chemicals, etc.) ?Production of human and animal supplements & therapeutics ?Production of recombinant proteins ?Production of cosmetics Benefits and Advantages ?Produced on site significantly expands the number of feasible growing sites ?Eliminate CO2 transport costs and risks associated with building pipelines ?Carbon neutral CO2 removed from atmosphere, not from burning fossil fuels ?Pure and concentrated CO2 stream without the drawbacks of flue gas ?Versatile - can be used in open microalgae systems (open ponds) or closed systems (photobioreactors) ?Minimizes CO2 loss 90% or more CO2 uptake efficiency ?More precise control over the pH and inorganic-C (Ci) levels ?Eliminates the input of undesired microorganisms from gas delivery Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Rittmanns laboratory webpage Dr. Lackner's laboratory webpage Dr. Wrights laboratory webpage Dr. Florys directory webpage
LanguageEnglish (US)
StatePublished - Jan 15 2015

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carbon dioxide
microalgae
gases
high-value products
closed loop systems
biopolymers
fossil fuels
agrochemicals
concentrating
cosmetics
biofuels
recombinant proteins
production costs
fish feeds
biomass production
researchers
microorganisms
air
therapeutics
liquids

Cite this

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title = "Atmospheric CO2 Enrichment and Delivery (ACED)",
abstract = "Microalgae are very useful biological systems for capturing carbon dioxide (CO2 ) and generating biomass and many useful products. Increasing the CO2 concentration in gas supplied to a microalgae growth system can improve its productivity many fold over using atmospheric air. Flue gas could be a good source of CO2 -enriched gas; however, its usefulness is compromised by transportation costs and toxic contaminants that can introduce impurities into fuel or other high value products. Researchers at Arizona State University have developed systems and methods for capturing and concentrating CO2 from the atmosphere and delivering the concentrated CO2 to microalgae growth systems. This system is highly efficient and delivers CO2 at a rate that is great enough to promote high biomass-production rates in closed or open systems. This system creates a concentrated stream of CO2 similar to flue gas, but is located at the site of microalgae growth (eliminating transportation costs and risks) and it doesnt contain contaminants. This system can enable the high microalgae productivity needed to meet the significant global demand for high-density liquid transportation fuels and lower production costs. Potential Applications ?CO2 capture and concentration for delivery into microalgae growth systems ?Production of renewable biofuels ?Production of animal and fish feed ?Production of bioplastics/biopolymers ?Production of fine chemicals (agrochemicals, specialty chemicals, etc.) ?Production of human and animal supplements & therapeutics ?Production of recombinant proteins ?Production of cosmetics Benefits and Advantages ?Produced on site significantly expands the number of feasible growing sites ?Eliminate CO2 transport costs and risks associated with building pipelines ?Carbon neutral CO2 removed from atmosphere, not from burning fossil fuels ?Pure and concentrated CO2 stream without the drawbacks of flue gas ?Versatile - can be used in open microalgae systems (open ponds) or closed systems (photobioreactors) ?Minimizes CO2 loss 90{\%} or more CO2 uptake efficiency ?More precise control over the pH and inorganic-C (Ci) levels ?Eliminates the input of undesired microorganisms from gas delivery Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Rittmanns laboratory webpage Dr. Lackner's laboratory webpage Dr. Wrights laboratory webpage Dr. Florys directory webpage",
author = "Klaus Lackner and Bruce Rittmann",
year = "2015",
month = "1",
day = "15",
language = "English (US)",
type = "Patent",

}

TY - PAT

T1 - Atmospheric CO2 Enrichment and Delivery (ACED)

AU - Lackner,Klaus

AU - Rittmann,Bruce

PY - 2015/1/15

Y1 - 2015/1/15

N2 - Microalgae are very useful biological systems for capturing carbon dioxide (CO2 ) and generating biomass and many useful products. Increasing the CO2 concentration in gas supplied to a microalgae growth system can improve its productivity many fold over using atmospheric air. Flue gas could be a good source of CO2 -enriched gas; however, its usefulness is compromised by transportation costs and toxic contaminants that can introduce impurities into fuel or other high value products. Researchers at Arizona State University have developed systems and methods for capturing and concentrating CO2 from the atmosphere and delivering the concentrated CO2 to microalgae growth systems. This system is highly efficient and delivers CO2 at a rate that is great enough to promote high biomass-production rates in closed or open systems. This system creates a concentrated stream of CO2 similar to flue gas, but is located at the site of microalgae growth (eliminating transportation costs and risks) and it doesnt contain contaminants. This system can enable the high microalgae productivity needed to meet the significant global demand for high-density liquid transportation fuels and lower production costs. Potential Applications ?CO2 capture and concentration for delivery into microalgae growth systems ?Production of renewable biofuels ?Production of animal and fish feed ?Production of bioplastics/biopolymers ?Production of fine chemicals (agrochemicals, specialty chemicals, etc.) ?Production of human and animal supplements & therapeutics ?Production of recombinant proteins ?Production of cosmetics Benefits and Advantages ?Produced on site significantly expands the number of feasible growing sites ?Eliminate CO2 transport costs and risks associated with building pipelines ?Carbon neutral CO2 removed from atmosphere, not from burning fossil fuels ?Pure and concentrated CO2 stream without the drawbacks of flue gas ?Versatile - can be used in open microalgae systems (open ponds) or closed systems (photobioreactors) ?Minimizes CO2 loss 90% or more CO2 uptake efficiency ?More precise control over the pH and inorganic-C (Ci) levels ?Eliminates the input of undesired microorganisms from gas delivery Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Rittmanns laboratory webpage Dr. Lackner's laboratory webpage Dr. Wrights laboratory webpage Dr. Florys directory webpage

AB - Microalgae are very useful biological systems for capturing carbon dioxide (CO2 ) and generating biomass and many useful products. Increasing the CO2 concentration in gas supplied to a microalgae growth system can improve its productivity many fold over using atmospheric air. Flue gas could be a good source of CO2 -enriched gas; however, its usefulness is compromised by transportation costs and toxic contaminants that can introduce impurities into fuel or other high value products. Researchers at Arizona State University have developed systems and methods for capturing and concentrating CO2 from the atmosphere and delivering the concentrated CO2 to microalgae growth systems. This system is highly efficient and delivers CO2 at a rate that is great enough to promote high biomass-production rates in closed or open systems. This system creates a concentrated stream of CO2 similar to flue gas, but is located at the site of microalgae growth (eliminating transportation costs and risks) and it doesnt contain contaminants. This system can enable the high microalgae productivity needed to meet the significant global demand for high-density liquid transportation fuels and lower production costs. Potential Applications ?CO2 capture and concentration for delivery into microalgae growth systems ?Production of renewable biofuels ?Production of animal and fish feed ?Production of bioplastics/biopolymers ?Production of fine chemicals (agrochemicals, specialty chemicals, etc.) ?Production of human and animal supplements & therapeutics ?Production of recombinant proteins ?Production of cosmetics Benefits and Advantages ?Produced on site significantly expands the number of feasible growing sites ?Eliminate CO2 transport costs and risks associated with building pipelines ?Carbon neutral CO2 removed from atmosphere, not from burning fossil fuels ?Pure and concentrated CO2 stream without the drawbacks of flue gas ?Versatile - can be used in open microalgae systems (open ponds) or closed systems (photobioreactors) ?Minimizes CO2 loss 90% or more CO2 uptake efficiency ?More precise control over the pH and inorganic-C (Ci) levels ?Eliminates the input of undesired microorganisms from gas delivery Dowload Original PDF For more information about the inventor(s) and their research, please see Dr. Rittmanns laboratory webpage Dr. Lackner's laboratory webpage Dr. Wrights laboratory webpage Dr. Florys directory webpage

M3 - Patent

ER -