scholarly journals Mitigation of carbon dioxide from synthetic flue gas using indigenous microalgae

2017 ◽  
Author(s):  
◽  
Virthie Kemraj Bhola
Keyword(s):  
Carbon Dioxide ◽  
Biomass Production ◽  
Flue Gas ◽  
Reference Strain ◽  
Carbon Sources ◽  
Co2 Concentration ◽  
Fractional Factorial ◽  
Gas Mixture ◽  
Chlorella Sp ◽  
Central Composite

Fossil carbon dioxide emissions can be biologically fixed which could lead to the development of technologies that are both economically and environmentally friendly. Carbon dioxide, which is the basis for the formation of complex sugars by green plants and microalgae through photosynthesis, has been shown to significantly increase the growth rates of certain microalgal species. Microalgae possess a greater capacity to fix CO2 compared to terrestrial plants. Selection of appropriate microalgal strains is based on the CO2 fixation and tolerance capability, both of which are a function of biomass productivity. Microalgal biomass could thus represent a natural sink for carbon. Furthermore, such systems could minimise capital and operating costs, complexity, and energy required to transport CO2 to other places. Prior to the development of an effective CO2 mitigation process, an essential step should be to identify the most CO2-tolerant indigenous strains. The first phase of this study therefore focused on the isolation, identification and screening of carboxyphilic microalgal strains (indigenous to the KwaZulu-Natal province in South Africa). In order to identify a high carbon-sequestering microalgal strain, the physiological effect of different concentrations of carbon sources on microalgae growth was investigated. Five indigenous strains (I-1, I-2, I-3, I-4 and I-5) and a reference strain (I-0: Coccolithus pelagicus 913/3) were subjected to CO2 concentrations of 0.03 - 15% and NaHCO3 of 0.05 - 2 g/1. The logistic model was applied for data fitting, as well as for estimation of the maximum growth rate (µmax) and the biomass carrying capacity (Bmax). Amongst the five indigenous strains, I-3 was similar to the reference strain with regards to biomass production values. The Bmax of I-3 significantly increased from 0.214 to 0.828 g/l when the CO2 concentration was increased from 0.03 to 15% (r = 0.955, p = 0.012). Additionally, the Bmax of I-3 increased with increasing NaHCO3 concentrations (r = 0.885, p = 0.046) and was recorded at 0.153 g/l (at 0.05 g/l) and 0.774 g/l (at 2 g/l). Relative electron transport rate (rETR) and maximum quantum yield (Fv/Fm) were also applied to assess the impact of elevated carbon sources on the microalgal cells at the physiological level. Isolate I-3 displayed the highest rETR confirming its tolerance to higher quantities of carbon. Additionally, the decline in Fv/Fm with increasing carbon was similar for strains I-3 and the reference strain (I-0). Based on partial 28S ribosomal DNA gene sequencing, strain I-3 was found to be homologous to the ribosomal genes of Chlorella sp. The influence of abiotic parameters (light intensity and light:dark cycles) and varying nutrient concentrations on the growth of the highly CO2 tolerant Chlorella sp. was thereafter investigated. It was found that an increase in light intensity from 40 to 175 umol m2 s-1 resulted in an enhancement of Bmax from 0.594 to 1.762 g/l, respectively (r = 0.9921, p = 0.0079). Furthermore, the highest Bmax of 2.514 g/l was detected at a light:dark cycle of 16:8. Media components were optimised using fractional factorial experiments which eventually culminated in a central composite optimisation experiment. An eight-factor resolution IV fractional factorial had a biomass production of 2.99 g/l. The largest positive responses (favourable effects on biomass production) were observed for individual factors X2 (NaNO3), X3 (NaH2PO4) and X6 (Fe-EDTA). Thereafter, a three-factor (NaNO3, NaH2PO4 and Fe-EDTA) central composite experimental design predicted a maximum biomass production of 3.051 g/l, which was 134.65% higher when compared to cultivation using the original ASW medium (1.290 g/l). A pilot scale flat panel photobioreactor was designed and constructed to demonstrate the process viability of utilising a synthetic flue gas mixture for the growth of microalgae. The novelty of this aspect of the study lies in the fact that a very high CO2 concentration (30%) formed part of the synthetic flue gas mixture. Overall, results demonstrated that the Chlorella sp. was able to grow well in a closed flat panel reactor under conditions of flue gas aeration. Biomass yield, however, was greatly dependent on culture conditions and the mode of flue gas supply. In comparison to the other batch runs, run B yielded the highest biomass value (3.415 g/l) and CO2 uptake rate (0.7971 g/day). During this run, not only was the Chlorella strain grown under optimised nutrient and environmental conditions, but the culture was also intermittently exposed to the flue gas mixture. Results from this study demonstrate that flue gas from industrial sources could be directly introduced to the indigenous Chlorella strain to potentially produce algal biomass while efficiently capturing and utilising CO2 from the flue gas.

scholarly journals Mitigation of carbon dioxide from synthetic flue gas using indigenous microalgae

2017 ◽  
Author(s):  
◽  
Virthie Kemraj Bhola
Keyword(s):  
Carbon Dioxide ◽  
Biomass Production ◽  
Flue Gas ◽  
Reference Strain ◽  
Carbon Sources ◽  
Co2 Concentration ◽  
Fractional Factorial ◽  
Gas Mixture ◽  
Chlorella Sp ◽  
Central Composite

Fossil carbon dioxide emissions can be biologically fixed which could lead to the development of technologies that are both economically and environmentally friendly. Carbon dioxide, which is the basis for the formation of complex sugars by green plants and microalgae through photosynthesis, has been shown to significantly increase the growth rates of certain microalgal species. Microalgae possess a greater capacity to fix CO2 compared to terrestrial plants. Selection of appropriate microalgal strains is based on the CO2 fixation and tolerance capability, both of which are a function of biomass productivity. Microalgal biomass could thus represent a natural sink for carbon. Furthermore, such systems could minimise capital and operating costs, complexity, and energy required to transport CO2 to other places. Prior to the development of an effective CO2 mitigation process, an essential step should be to identify the most CO2-tolerant indigenous strains. The first phase of this study therefore focused on the isolation, identification and screening of carboxyphilic microalgal strains (indigenous to the KwaZulu-Natal province in South Africa). In order to identify a high carbon-sequestering microalgal strain, the physiological effect of different concentrations of carbon sources on microalgae growth was investigated. Five indigenous strains (I-1, I-2, I-3, I-4 and I-5) and a reference strain (I-0: Coccolithus pelagicus 913/3) were subjected to CO2 concentrations of 0.03 - 15% and NaHCO3 of 0.05 - 2 g/1. The logistic model was applied for data fitting, as well as for estimation of the maximum growth rate (µmax) and the biomass carrying capacity (Bmax). Amongst the five indigenous strains, I-3 was similar to the reference strain with regards to biomass production values. The Bmax of I-3 significantly increased from 0.214 to 0.828 g/l when the CO2 concentration was increased from 0.03 to 15% (r = 0.955, p = 0.012). Additionally, the Bmax of I-3 increased with increasing NaHCO3 concentrations (r = 0.885, p = 0.046) and was recorded at 0.153 g/l (at 0.05 g/l) and 0.774 g/l (at 2 g/l). Relative electron transport rate (rETR) and maximum quantum yield (Fv/Fm) were also applied to assess the impact of elevated carbon sources on the microalgal cells at the physiological level. Isolate I-3 displayed the highest rETR confirming its tolerance to higher quantities of carbon. Additionally, the decline in Fv/Fm with increasing carbon was similar for strains I-3 and the reference strain (I-0). Based on partial 28S ribosomal DNA gene sequencing, strain I-3 was found to be homologous to the ribosomal genes of Chlorella sp. The influence of abiotic parameters (light intensity and light:dark cycles) and varying nutrient concentrations on the growth of the highly CO2 tolerant Chlorella sp. was thereafter investigated. It was found that an increase in light intensity from 40 to 175 umol m2 s-1 resulted in an enhancement of Bmax from 0.594 to 1.762 g/l, respectively (r = 0.9921, p = 0.0079). Furthermore, the highest Bmax of 2.514 g/l was detected at a light:dark cycle of 16:8. Media components were optimised using fractional factorial experiments which eventually culminated in a central composite optimisation experiment. An eight-factor resolution IV fractional factorial had a biomass production of 2.99 g/l. The largest positive responses (favourable effects on biomass production) were observed for individual factors X2 (NaNO3), X3 (NaH2PO4) and X6 (Fe-EDTA). Thereafter, a three-factor (NaNO3, NaH2PO4 and Fe-EDTA) central composite experimental design predicted a maximum biomass production of 3.051 g/l, which was 134.65% higher when compared to cultivation using the original ASW medium (1.290 g/l). A pilot scale flat panel photobioreactor was designed and constructed to demonstrate the process viability of utilising a synthetic flue gas mixture for the growth of microalgae. The novelty of this aspect of the study lies in the fact that a very high CO2 concentration (30%) formed part of the synthetic flue gas mixture. Overall, results demonstrated that the Chlorella sp. was able to grow well in a closed flat panel reactor under conditions of flue gas aeration. Biomass yield, however, was greatly dependent on culture conditions and the mode of flue gas supply. In comparison to the other batch runs, run B yielded the highest biomass value (3.415 g/l) and CO2 uptake rate (0.7971 g/day). During this run, not only was the Chlorella strain grown under optimised nutrient and environmental conditions, but the culture was also intermittently exposed to the flue gas mixture. Results from this study demonstrate that flue gas from industrial sources could be directly introduced to the indigenous Chlorella strain to potentially produce algal biomass while efficiently capturing and utilising CO2 from the flue gas.

Microalgal biomass production and on-site bioremediation of carbon dioxide, nitrogen oxide and sulfur dioxide from flue gas using Chlorella sp. cultures

2011 ◽  
Vol 102 (19) ◽  
pp. 9135-9142 ◽  
Author(s):  
Sheng-Yi Chiu ◽  
Chien-Ya Kao ◽  
Tzu-Ting Huang ◽  
Chia-Jung Lin ◽  
Seow-Chin Ong ◽  
...  
Keyword(s):  
Carbon Dioxide ◽  
Sulfur Dioxide ◽  
Nitrogen Oxide ◽  
Biomass Production ◽  
Flue Gas ◽  
Microalgal Biomass ◽  
Chlorella Sp

Adaptive evolution and carbon dioxide fixation of Chlorella sp. in simulated flue gas

2019 ◽  
Vol 650 ◽  
pp. 2931-2938 ◽  
Author(s):  
Dujia Cheng ◽  
Xuyang Li ◽  
Yizhong Yuan ◽  
Chengyu Yang ◽  
Tao Tang ◽  
...  
Keyword(s):  
Carbon Dioxide ◽  
Adaptive Evolution ◽  
Flue Gas ◽  
Carbon Dioxide Fixation ◽  
Chlorella Sp

Carbon dioxide fixation and biomass production from combustion flue gas using energy microalgae

Energy ◽  
2015 ◽  
Vol 89 ◽  
pp. 347-357 ◽  
Author(s):  
Bingtao Zhao ◽  
Yaxin Su ◽  
Yixin Zhang ◽  
Guomin Cui
Keyword(s):  
Carbon Dioxide ◽  
Biomass Production ◽  
Flue Gas ◽  
Carbon Dioxide Fixation

scholarly journals Study of the conditions for the effective initiation of plasma-chemical treatment of flue gas under the influence of a pulsed electron beam

2020 ◽  
Vol 38 (3) ◽  
pp. 197-203 ◽  
Author(s):  
G. Kholodnaya ◽  
I. Egorov ◽  
R. Sazonov ◽  
M. Serebrennikov ◽  
A. Poloskov ◽  
...  
Keyword(s):  
Carbon Dioxide ◽  
Electron Beam ◽  
Water Vapor ◽  
Flue Gas ◽  
Chemical Treatment ◽  
Drift Chamber ◽  
Gas Mixture ◽  
Plasma Chemical ◽  
Pulsed Electron Beam ◽  
Beam Transmission

AbstractThis paper presents the results of comprehensive studies of the efficiency of a pulsed electron beam transmission through a mixture of gases: nitrogen (83%), carbon dioxide (14%), and oxygen (2.6%) in the presence of ash and water vapor. The studied concentrations correspond to the concentrations of nitrogen, oxygen, and carbon dioxide in flue gas. The pressure and concentration of water vapor and ash in the drift chamber varied (375, 560, and 750 Torr; humidity 15 ± 5% and 50 ± 15%). The charge dissipation of a pulsed electron beam in the gas mixture in the presence of ash and water vapor was investigated, as well as the effect of the concentration of water vapor and ash on the geometric profile of the pulsed electron beam.

In-field experimental verification of cultivation of microalgae Chlorella sp. using the flue gas from a cogeneration unit as a source of carbon dioxide

2010 ◽  
Vol 28 (11) ◽  
pp. 961-966 ◽  
Author(s):  
František Kaštánek ◽  
Stanislav Šabata ◽  
Olga Šolcová ◽  
Ywette Maléterová ◽  
Petr Kaštánek ◽  
...  
Keyword(s):  
Carbon Dioxide ◽  
Experimental Verification ◽  
Flue Gas ◽  
Chlorella Sp

scholarly journals Life Cycle Assessment of Synthetic Natural Gas Production from Different CO2 Sources: A Cradle-to-Gate Study

Energies ◽  
2020 ◽  
Vol 13 (17) ◽  
pp. 4579
Author(s):  
Eleonora Bargiacchi ◽  
Nils Thonemann ◽  
Jutta Geldermann ◽  
Marco Antonelli ◽  
Umberto Desideri
Keyword(s):  
Carbon Dioxide ◽  
Life Cycle Assessment ◽  
Life Cycle ◽  
Carbon Capture ◽  
Carbon Sources ◽  
Electric Energy ◽  
Co2 Concentration ◽  
Gas Production ◽  
Capture Process ◽  
Iron And Steel

Fuel production from hydrogen and carbon dioxide is considered an attractive solution as long-term storage of electric energy and as temporary storage of carbon dioxide. A large variety of CO2 sources are suitable for Carbon Capture Utilization (CCU), and the process energy intensity depends on the separation technology and, ultimately, on the CO2 concentration in the flue gas. Since the carbon capture process emits more CO2 than the expected demand for CO2 utilization, the most sustainable CO2 sources must be selected. This work aimed at modeling a Power-to-Gas (PtG) plant and assessing the most suitable carbon sources from a Life Cycle Assessment (LCA) perspective. The PtG plant was supplied by electricity from a 2030 scenario for Italian electricity generation. The plant impacts were assessed using data from the ecoinvent database version 3.5, for different CO2 sources (e.g., air, cement, iron, and steel plants). A detailed discussion on how to handle multi-functionality was also carried out. The results showed that capturing CO2 from hydrogen production plants and integrated pulp and paper mills led to the lowest impacts concerning all investigated indicators. The choice of how to handle multi-functional activities had a crucial impact on the assessment.

scholarly journals Packed-Bed Reactor Study of NETL Sample 196c for the Removal of Carbon Dioxide from Simulated Flue Gas Mixture

2012 ◽  
Author(s):  
James S. Hoffman ◽  
Sonia Hammache ◽  
McMahan L. Gray ◽  
Daniel J. Fauth ◽  
Henry W. Pennline
Keyword(s):  
Carbon Dioxide ◽  
Flue Gas ◽  
Packed Bed ◽  
Packed Bed Reactor ◽  
Gas Mixture

PENGARUH KELIMPAHAN SEL MIKROALGAE AIR TAWAR (Chlorella sp.) TERHADAP PENAMBATAN KARBONDIOKSIDA = Effect of Microalgae Cell Density (Chlorella sp) on Absorption of Carbondioxide

2016 ◽  
Vol 14 (1) ◽  
pp. 1
Author(s):  
Nida Sopiah ◽  
Adi Mulyanto ◽  
Sindi Sehabudin
Keyword(s):  
Carbon Dioxide ◽  
Energy Source ◽  
Carbon Source ◽  
Co2 Concentration ◽  
Biomass Density ◽  
Co2 Gas ◽  
Chlorella Sp ◽  
Microalgae Biomass ◽  
The Difference ◽  
Carbon Dioxide Co2

Chlorella sp. is a single-cell microalgae that lives in aquatic environment. It grows and developsby making use of sunlight as an energy source and carbon dioxide (CO2) as carbon source. Chlorella sp. can be utilized as biological agents in reducing CO2 gas emissions in the atmosphere. The purpose of this experiment was to assess the influence of microalgae’sincreasing density to its capability in absorbing CO2.The air which contains CO2 was injected to aclosed photobioreactor intermittently by an aerator. The flow rate applied was 2.5 liters/minute.Research result identified that amount of CO2 sequestered by Chlorella sp. in photobioreactor system was equal with increasing of microalgae biomass density. Sequestration of CO2 inphotobioreactor significantly increased at the afternoon because occurring of photosynthesis process. This phenomenon was identified by difference of CO2 concentration during morning andafternoon toward photobioreactor number 1, 2, and 3. The difference was in between 0.15 % -2.40 %; 0.05 % - 2.30 %; and 0.51 % - 2.74 % respectively. Capability of cell on sequestering ofCO2 increased amounting of 102 – 167.2 % per day.Keywords: Chlorella sp, carbondioxide, sequestration, microalgae abundanceAbstrak Chlorella sp. merupakan mikroalgae bersel tunggal yang hidup di lingkungan perairan, tumbuh dan berkembang dengan memanfaatkan sinar matahari sebagai sumber energi dankarbondioksida sebagai sumber karbon. Chlorella sp. dapat dimanfaatkan sebagai agensia hayati dalam menurunkan emisi gas CO2 di atmosfer. Tujuan dari penelitian adalah untuk mengkajipengaruh kelimpahan Chlorella sp. terhadap penambatan karbon dioksida dalam mereduksi emisi karbondioksida. Pada penelitian ini, gas CO2 diinjeksikan ke dalam fotobioreaktor sistemtertutup dengan sistem intermiten dan supply oksigen menggunakan aerator dengan debit sebesar 2,5 liter/menit. Hasil Penelitian menunjukkan bahwa jumlah karbondioksida yangditambat oleh Chlorella sp. dalam sistem fotobioreaktor setara dengan penambahan kelimpahan biomassa mikroalgae. Panambatan karbondioksida pada fotobioreaktor mengalami peningkatansangat signifikan pada siang hari karena adanya proses fotosintesis yang ditunjukkan dengan adanya selisih konsentrasi CO2 saat pagi dan sore hari pada masing-masing fotobioreaktor 1, 2 dan 3 berkisar antara 0,15 % - 2,40 %; 0,05 % - 2,30 % dan 0,51 % - 2,74 %. Sedangkanefisiensi kemampuan penambatan CO2 oleh setiap sel Chlorella sp. selama 21 hari dibandingkan terhadap inokulasi hari pertama menunjukkan peningkatan yang signifikan dengan nilai efisiensimasing-masing 67,2 %; 144,6 %; 222,6 %; 308,8 %; 364,2 %; 416,1 %; 447,0 %; 470,8 %; 505,9%; 555,0 %; 571,4 %; 581,0 %; 587,7 %; 612,6 %; 626,6 %; 656,6 %; 684,7 %; 715,3 %; 733,9%; dan pada hari ke-21 meningkat sebesar 750,5 %. Dan kemampuan setiap sel dalam menambat CO2 setiap hari mampu meningkatkan sebesar 102 % -167,2 %. Kata Kunci : Chlorella sp., karbondioksida, penambatan, kelimpahan mikroalga

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