Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water
This thesis discusses efforts made to develop a gas-liquid membrane contactor for direct oceanic CO2 capture and describes the synthesis and characterization of the photoacid 6-hydroxypyrene-1-sufonate (HPMS). In the first study, efforts are made to increase CO2 extraction yields from ocean water by...
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| Language: | English |
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eScholarship, University of California
2022
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| Online Access: | https://escholarship.org/uc/item/1hq5p98n |
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ftcdlib:oai:escholarship.org:ark:/13030/qt1hq5p98n |
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ftcdlib:oai:escholarship.org:ark:/13030/qt1hq5p98n 2023-05-15T15:53:02+02:00 Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water Bender, Anastasiya Ardo, Shane A 2022-01-01 https://escholarship.org/uc/item/1hq5p98n en eng eScholarship, University of California qt1hq5p98n https://escholarship.org/uc/item/1hq5p98n CC-BY CC-BY Chemistry CO2 capture direct ocean capture Donnan potential gas-liquid membrane contactor ion-exchange membrane etd 2022 ftcdlib 2023-01-16T18:39:51Z This thesis discusses efforts made to develop a gas-liquid membrane contactor for direct oceanic CO2 capture and describes the synthesis and characterization of the photoacid 6-hydroxypyrene-1-sufonate (HPMS). In the first study, efforts are made to increase CO2 extraction yields from ocean water by studying the influence of various catalysts, ion-exchange membranes, and buffers on rates of mass transfer and mass action interconversion of bicarbonate and CO2(aq).In the second study, HPMS is developed because its pKa values are suitable to photogenerate both H+ and OH- in aqueous media and its single sulfonate group will aid in controllable modification of surface and polymer characteristics that could potentially aid in light-driven water desalination. The first study focuses on maximizing CO2 extraction yields from ocean water by using a gas-liquid membrane contactor with various catalysts, buffers, and ion-exchange membranes, as well as varying flow rates. When atmospheric CO2 dissolves in the ocean it reacts with water to yield carbonic acid, which dissociates into bicarbonate and solvated protons at the ocean water pH of 8.1. These events have caused the pH of the ocean to decrease. The goal of this project is to deacidify the ocean by extracting CO2(aq) by catalyzing the interconversion between bicarbonate and CO2. This work shows it is possible to extract CO2 from ocean water using ion-exchange membranes, and that extraction yield can be maximized by coating the membranes with various molecular catalysts or polymers, such as zinc-cyclen (a carbonic anhydrase mimic), and polyethylenimine. This work also demonstrates the influence of high salt concentration on oceanic CO2 capture when using ion-exchange membranes with no added catalyst. In addition, the effect of liquid flow rate on extraction yield and flux of CO2 was evaluated using a single porous PTFE fiber membrane contactor. Lastly, this work documents analytical calibrations made on the Hidden HPR 20-QIC Vacuum System mass spectrometer used for the ... Other/Unknown Material Carbonic acid University of California: eScholarship |
| institution |
Open Polar |
| collection |
University of California: eScholarship |
| op_collection_id |
ftcdlib |
| language |
English |
| topic |
Chemistry CO2 capture direct ocean capture Donnan potential gas-liquid membrane contactor ion-exchange membrane |
| spellingShingle |
Chemistry CO2 capture direct ocean capture Donnan potential gas-liquid membrane contactor ion-exchange membrane Bender, Anastasiya Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| topic_facet |
Chemistry CO2 capture direct ocean capture Donnan potential gas-liquid membrane contactor ion-exchange membrane |
| description |
This thesis discusses efforts made to develop a gas-liquid membrane contactor for direct oceanic CO2 capture and describes the synthesis and characterization of the photoacid 6-hydroxypyrene-1-sufonate (HPMS). In the first study, efforts are made to increase CO2 extraction yields from ocean water by studying the influence of various catalysts, ion-exchange membranes, and buffers on rates of mass transfer and mass action interconversion of bicarbonate and CO2(aq).In the second study, HPMS is developed because its pKa values are suitable to photogenerate both H+ and OH- in aqueous media and its single sulfonate group will aid in controllable modification of surface and polymer characteristics that could potentially aid in light-driven water desalination. The first study focuses on maximizing CO2 extraction yields from ocean water by using a gas-liquid membrane contactor with various catalysts, buffers, and ion-exchange membranes, as well as varying flow rates. When atmospheric CO2 dissolves in the ocean it reacts with water to yield carbonic acid, which dissociates into bicarbonate and solvated protons at the ocean water pH of 8.1. These events have caused the pH of the ocean to decrease. The goal of this project is to deacidify the ocean by extracting CO2(aq) by catalyzing the interconversion between bicarbonate and CO2. This work shows it is possible to extract CO2 from ocean water using ion-exchange membranes, and that extraction yield can be maximized by coating the membranes with various molecular catalysts or polymers, such as zinc-cyclen (a carbonic anhydrase mimic), and polyethylenimine. This work also demonstrates the influence of high salt concentration on oceanic CO2 capture when using ion-exchange membranes with no added catalyst. In addition, the effect of liquid flow rate on extraction yield and flux of CO2 was evaluated using a single porous PTFE fiber membrane contactor. Lastly, this work documents analytical calibrations made on the Hidden HPR 20-QIC Vacuum System mass spectrometer used for the ... |
| author2 |
Ardo, Shane A |
| format |
Other/Unknown Material |
| author |
Bender, Anastasiya |
| author_facet |
Bender, Anastasiya |
| author_sort |
Bender, Anastasiya |
| title |
Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| title_short |
Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| title_full |
Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| title_fullStr |
Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| title_full_unstemmed |
Evaluation of the Influence of Ion-exchange-membrane Properties, Chemical Catalysis, and Liquid Flow Rate on the Rate of CO2 Extraction from Varying Salinity Synthetic Ocean Water |
| title_sort |
evaluation of the influence of ion-exchange-membrane properties, chemical catalysis, and liquid flow rate on the rate of co2 extraction from varying salinity synthetic ocean water |
| publisher |
eScholarship, University of California |
| publishDate |
2022 |
| url |
https://escholarship.org/uc/item/1hq5p98n |
| genre |
Carbonic acid |
| genre_facet |
Carbonic acid |
| op_relation |
qt1hq5p98n https://escholarship.org/uc/item/1hq5p98n |
| op_rights |
CC-BY |
| op_rightsnorm |
CC-BY |
| _version_ |
1766388104230338560 |