Your search keyword '"CO2 release"' showing total 110 results

1. Towards Energy‐Efficient Direct Air Capture with Photochemically‐Driven CO2 Release and Solvent Regeneration.

Author

Premadasa, Uvinduni I., Doughty, Benjamin, Custelcean, Radu, and Ma, Ying‐Zhong

Subjects

*CARBON sequestration, *ENERGY industries, *ENERGY consumption, *SOLAR energy, *CARBON dioxide

Abstract

The intensive energy demands associated with solvent regeneration and CO2 release in current direct air capture (DAC) technologies makes their deployment at the massive scales (GtCO2/year) required to positively impact the climate economically unfeasible. This challenge underscores the critical need to develop new DAC processes with significantly reduced energy costs. Recently, we developed a new approach to photochemically drive efficient release of CO2 through an intermolecular proton transfer reaction by exploiting the unique properties of an indazole metastable‐state photoacid (mPAH), opening a new avenue towards energy efficient on‐demand CO2 release and solvent regeneration using abundant solar energy instead of heat. In this Concept Article, we will describe the principle of our photochemically‐driven CO2 release approach for solvent‐based DAC systems, discuss the essential prerequisites and conditions to realize this cyclable CO2 release chemistry under ambient conditions. We outline the key findings of our approach, discuss the latest developments from other research laboratories, detail approaches used to monitor DAC systems in situ, and highlight experimental procedures for validating its feasibility. We conclude with a summary and outlook into the immediate challenges that must be addressed in order to fully exploit this novel photochemically‐driven approach to DAC solvent regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of Process Variables on Gas Release from Free and Latex-Coated Calcium Alginate Beads

Author

Peh, Yee-Ming, Lee, Boon-Beng, Kasim, Farizul Hafiz, Ma’Radzi, Akmal Hadi, Balaji, Sakthi, Yaakub, Ahmad Radi Wan, Johar, Hafizah Mohd, Yusoff, Mohd Asri, Ong, Hui Lin, editor, Yusof, Siti Jamilah Hanim Mohd, editor, Kasim, Khairul Farihan, editor, Gunny, Ahmad Anas Nagoor, editor, and Othman, Rahimah, editor

Published

2024

3. Decreased Soil Microbial Nitrogen Under Vegetation 'Shrubification' in the Subarctic Forest–Tundra Ecotone: The Potential Role of Increasing Nutrient Competition Between Plants and Soil Microorganisms.

Author

Stark, Sari, Kumar, Manoj, Myrsky, Eero, Vuorinen, Jere, Kantola, Anu M., Telkki, Ville-Veikko, Sjögersten, Sofie, Olofsson, Johan, and Männistö, Minna K.

Subjects

*TUNDRAS, *PLANT competition, *SOIL microbiology, *PLANT-soil relationships, *GLOBAL warming, *ECOTONES

Abstract

The consequences of warming-induced 'shrubification' on Arctic soil carbon storage are receiving increased attention, as the majority of ecosystem carbon in these systems is stored in soils. Soil carbon cycles in these ecosystems are usually tightly coupled with nitrogen availability. Soil microbial responses to 'shrubification' may depend on the traits of the shrub species that increase in response to warming. Increase in deciduous shrubs such as Betula nana likely promotes a loss of soil carbon, whereas the opposite may be true if evergreen shrubs such as Empetrum hermaphroditum increase. We analyzed soil organic matter stocks and 13C NMR fractions, microbial CO2 respiration, biomass, extracellular enzyme activities (EEAs), and their association with shrub density in northern Sweden after 20 years of experimental warming using open top chambers (OTCs). Our study sites were located in a tundra heath that stores high soil carbon quantities and where the OTCs had increased deciduous shrubs, and in a mountain birch forest that stores lower soil carbon quantities and where the OTCs had increased evergreen shrubs. We predicted that organic matter stocks should be lower and respiration and EEAs higher inside the OTCs than untreated plots in the tundra, whereas no effect should be detected in the forest. Soil organic matter stocks and 13C NMR fractions remained unaffected at both sites. When expressed as per gram microbial biomass, respiration and EEAs for carbohydrate and chitin degradation were higher inside the OTCs, and contrasting our prediction, this effect was stronger in the forest. Unexpectedly, the OTCs also led to a substantially lower microbial biomass carbon and nitrogen irrespective of habitat. The decline in the microbial biomass counteracted increased activities resulting in no effect of the OTCs on respiration and a lower phenol oxidase activity per gram soil. Microbial biomass nitrogen correlated negatively with evergreen shrub density at both sites, indicating that 'shrubification' may have intensified nutrient competition between plants and soil microorganisms. Nutrient limitation could also underlie increased respiration per gram microbial biomass through limiting C assimilation into biomass. We hypothesize that increasing nutrient immobilization into long-lived evergreen shrubs could over time induce microbial nutrient limitation that contributes to a stability of accumulated soil organic matter stocks under climate warming. [ABSTRACT FROM AUTHOR]

Published

2023

4. Carbon release from Large Igneous Province magmas estimated from trace element-gas correlations

Author

Benjamin A Black and Alessandro Aiuppa

Subjects

large igneous provinces, co2 release, trace element geochemistry, volatile outgassing, Geology, QE1-996.5

Abstract

Large Igneous Provinces (LIPs) facilitate massive transfers of CO2 and other volatiles from the mantle to atmosphere, contributing to past global warming and environmental disruption. However, the scale and evolution of magmatic CO2 fluxes during these events remain uncertain due to the tendency of CO2 to degas deep in magmatic systems. Here we estimate LIP CO2 using an approach based on an observed correlation between gas CO2/S ratios and trace elements in volcanic rocks. We apply this method to a compilation of published geochemical data for tholeiitic LIP lavas and to a new major and trace element dataset for alkaline rocks from the Siberian Traps. Our results indicate that CO2/S and therefore CO2 in tholeiitic and alkaline magma suites from LIPs span 1–2 orders of magnitude, emphasizing that changing CO2 concentrations can combine with magma flux to drive strong variations in CO2 release through the evolution of LIP magmatism.

Published

2023

5. Photochemically‐Driven CO2 Release Using a Metastable‐State Photoacid for Energy Efficient Direct Air Capture.

Author

Premadasa, Uvinduni I., Bocharova, Vera, Miles, Audrey R., Stamberga, Diana, Belony, Stella, Bryantsev, Vyacheslav S., Elgattar, Adnan, Liao, Yi, Damron, Joshua T., Kidder, Michelle K., Doughty, Benjamin, Custelcean, Radu, and Ma, Ying‐Zhong

Subjects

*ENERGY industries, *LIGHT intensity, *CARBON dioxide, *CLIMATE change, *BASIC needs

Abstract

One of the grand challenges underlying current direct air capture (DAC) technologies relates to the intensive energy cost for sorbent regeneration and CO2 release, making the massive scale (GtCO2/year) deployment required to have a positive impact on climate change economically unfeasible. This challenge underscores the critical need to develop new DAC processes with substantially reduced regeneration energies. Here, we report a photochemically‐driven approach for CO2 release by exploiting the unique properties of an indazole metastable‐state photoacid (mPAH). Our measurements on simulated and amino acid‐based DAC systems revealed the potential of mPAH to be used for CO2 release cycles by regulating pH changes and associated isomers driven by light. Upon irradiating with moderate intensity light, a ≈55 % and ≈68 % to ≈78 % conversion of total inorganic carbon to CO2 was found for the simulated and amino acid‐based DAC systems, respectively. Our results confirm the feasibility of on‐demand CO2 release under ambient conditions using light instead of heat, thereby providing an energy efficient pathway for the regeneration of DAC sorbents. [ABSTRACT FROM AUTHOR]

Published

2023

6. Transient multiphase CO2 release from high‐pressure tanks: Influence of phase changes, viscous heating, and Joule–Thomson effect.

Author

Fiore, Piergiuseppe, Coppola, Michela, Meninno, Paola, Sannino, Maddalena, De Marco, Giuseppe, Sacco, Serafino, and Caravella, Alessio

Subjects

JOULE-Thomson effect, COMPUTATIONAL fluid dynamics, PHASE transitions, SUPERSONIC flow, TRANSITION flow, STEAM flow, TRANSONIC aerodynamics

Abstract

In this study, CO2 free expansion from high‐pressure tanks is studied in a transient state while considering the influence of different phenomena—that is, viscous heating, phase transition (solid/liquid/vapour phase), and the Joule–Thomson effect—in an initially supersonic flow. This investigation is performed using computational fluid dynamics (CFD) techniques, comparing the obtained results with some experimental data of the literature with a maximum discrepancy of around 8.5%. In particular, for the first time from the literature, it is observed that, according to the velocity evolution at the outlet, the discharge process is conveniently divided into three here‐defined stages: (1) shocking flow, where pressure abruptly decreases with time and flow becomes supersonic, this leading to the condensation of part of CO2; (2) transition flow, characterized by a sort of constant pressure time trend; and (3) flashing flow, where pressure decreases less abruptly following an asymptotic pattern up to the atmospheric one and flow becomes subsonic. Furthermore, non‐equilibrium condensation occurring in the tank, tube, and outlet is observed, finding that the minimum temperature reached by the fluid is around 235 K (−38°C). As well, the non‐equilibrium condensation is taken into account in order to give an indication of the amount of liquid CO2 leaving the outlet in the form of high‐speed jet, which can be a serious danger for personnel and surrounding installations. Moreover, we observe an important effect of viscous heating in the early‐stage expansion for a relatively short time range, within which the temperature in the tube experiences an abrupt increase of around 210 K (from 170 to 380 K). The same effect in the external room creates a convection flow, pushing CO2 towards the top. The results of the present work can be used for health, safety, and environment (HSE) management purposes and for a more precise process design related to CO2 storage and sequestration. [ABSTRACT FROM AUTHOR]

Published

2023

7. Biochar Addition Modified Carbon Flux and Related Microbiota in Cow Manure Composting.

Author

Yan, Hailong, Yang, Hongxiang, Li, Kecheng, Zhu, Pengfei, Li, Xiaolan, and Li, Qunliang

Abstract

Carbon emission is the main cause of carbon loss during composting. This study investigated the effect of bamboo biochar addition to compost on carbon dioxide (CO2) release and fixation through metagenomics sequencing. The results showed that the addition of biochar enriched the relative abundance of ribulose-1,5-diphosphate carboxylase/oxygenase (RuBisCO) gene by 13.22%, improving the diversity of carbon-fixing microbiota. In addition, biochar also inhibited the relative abundances of pyruvate dehydrogenase (PDH), isocitrate dehydrogenase (IDH), and alpha-ketoglutarate dehydrogenase (A_KGD) at the late stage of composting, thereby reducing the CO2 release by 16.77%. Bamboo biochar also decreased the abundance of Methyl coenzyme-M reductase (MCR), which in turn reduced methane (CH4) release. Redundancy analysis (RDA) showed that Proteobacteria was the dominant phylum in the compost system during the cooling and maturity periods, which dominated the release of CO2 and was positively correlated with PDH, IDH, and A_KGD (p < 0.01). In addition, RubisCO was negatively correlated with organic matter (OM), CO2, CH4 (p < 0.01). Taken together, biochar can inhibit the activity of CO2-releasing microorganisms, thereby reducing carbon loss in composting. [ABSTRACT FROM AUTHOR]

Published

2023

8. Erosion modulates the effect of chemical weathering on atmospheric pCO2, Qinghai-Tibet Plateau.

Author

Lu, Heping, Luo, Han, Zhong, Jun, Xu, Sen, Ma, Tingting, and Li, Si-Liang

Subjects

*ATMOSPHERIC carbon dioxide, *WEATHERING, *WATER chemistry, *SULFUR isotopes, *WATERSHEDS

Abstract

Chemical weathering plays an important role in modulating Earth's climate. However, chemical weathering is usually influenced by multiple factors simultaneously (e.g., climate, topography and lithology), and it is difficult to understand how these variables modulate the effect of chemical weathering on atmospheric p CO 2. In this study, we collected and analyzed water chemistry and multiple isotopes (δ34S SO4 , δ18O SO4 and δ18O H2O) in the Bailong River catchment to decipher how these variables influence chemical weathering and its effect on atmospheric p CO 2. We used the Monte Carlo inversion model to partition the sources of major cations and SO 4 2 − , and the results reveal that carbonate weathering is the dominant source contributing cations in river. Sulfide oxidation is the most important source for SO 4 2 − and a supply-limited process that is highly dependent on slope. We thus think slope is main factor modulating the effect of chemical weathering on atmospheric p CO 2. Steep slope increases sulfide oxidation rate by elevating erosion, resulting in chemical weathering acting as a CO 2 source. In contrast, gentle slope could facilitate a thick regolith that contributes long-term silicate weathering and limits sulfide oxidation, resulting in chemical weathering acting as a CO 2 sink. And it has been found that the influence of temperature on chemical weathering becomes progressively pronounced with increasing altitude. This study investigated sulfide weathering in eroding Qinghai-Tibet Plateau, highlighting the geomorphologically controlled CO 2 effects of chemical weathering. • There is significant spatial heterogeneity in climate, topography and lithology, influencing rock weathering in the Bailong River. • Sulfide oxidation is the most important source for SO 4 2 − , and the contribution of sulfide oxidation to SO 4 2 − is highly dependent on slope. • Slope is the main factor modulating the effect of rock weathering on atmospheric p CO 2. • The effect of temperature on rock weathering becomes progressively more pronounced with increasing altitude. [ABSTRACT FROM AUTHOR]

Published

2024

9. Increases in macroaggregate fractions following organic fertilizer application decrease microbial-driven CO2 release.

Author

Hei, Zewen, Geisen, Stefan, Shao, Jiayu, Yang, Yi, Liu, Futing, Hu, Shunran, Zhang, Hongyan, Kammenga, Jan, and Chen, Yongliang

Subjects

*ORGANIC fertilizers, *SOIL mineralogy, *FERTILIZER application, *EXTRACELLULAR enzymes, *SOIL structure

Abstract

Fertilizer application is key for plant yield promotion, but also has side effects on microbes, organic carbon storage and aggregate size distributions. However, links between these factors and especially how different amounts of organic and mineral fertilizers affect microbial-driven CO 2 release at the aggregate scale remains largely unknown. We quantified carbon decomposition gene abundance and diversity, microbial residual carbon and CO 2 release from the labile or stable carbon pools in three soil aggregate size fractions in organic and mineral fertilized soil. Compared to mineral fertilizer, organic fertilizer increased abundances of carbon decomposition genes, extracellular enzyme activities, microbial residual carbon and CO 2 released from the labile carbon pool, but decreased CO 2 released from the stable carbon pool in microaggregates. Likewise, organic fertilizer increased the proportion of macroaggregates, microbial residual carbon and CO 2 released from the labile carbon pool, but had no effect on carbon degradation gene abundance and extracellular carbon enzyme activity. Taken together, we illustrate that organic fertilizer application decreases CO 2 release via increasing the proportion of macroaggregates, leading to increased carbon storage that can provide a means to lessening atmospheric carbon. [Display omitted] • Organic fertilizer decreases CO 2 release via increasing macroaggregates fractions • Organic fertilizer increased carbon degradation gene abundances in microaggregates • Organic fertilizer decreased CO 2 release from the stable carbon pool in three aggregate fractions [ABSTRACT FROM AUTHOR]

Published

2024

10. Carbon Footprint for Post-Mining Soils: The Dynamic of Net CO 2 Fluxes and SOC Sequestration at Different Soil Remediation Stages under Reforestation.

Author

Kowalska, Aneta, Singh, Bal Ram, and Grobelak, Anna

Subjects

*REFORESTATION, *SOIL remediation, *ECOLOGICAL impact, *CARBON dioxide, *CLIMATE change mitigation, *SEWAGE sludge

Abstract

The remediation of open-cast post-mining soil remains a big challenge. Here, the post-mining soils are considered from the viewpoints of CO2 emission and carbon sequestration. We investigated the dynamic of C stock in two different post-mining areas, i.e., the limestone post-mining soil remediated with embankment (S1), and the lignite post-mining soil remediated with sewage sludge (S2). Post-mining soils under four different remediation stages were used. The study was conducted in the spring of 2021 and 2022. The aim of the study was to assess the C sequestration in sewage sludge amended and non-amended post-mining soils at differently advanced remediation techniques. We noticed an increase in or stabilization of SOC in the S1. The stabilization of SOC was observed for the soil with a higher remediation age (S1C, S1D). The remediation of the S2 resulted in the increase in SOC among the soil remediation age. For both soils, we noticed a negative CO2 emission from the soil under remediation, and the net CO2 emission rate (NCER) further decreased after one year. A positive C feedback of both remediation techniques was shown to reflect lower active carbon (POXC). We also noticed an increase in nutrient content (K, Mg), and a decrease in heavy metals content after 1 year. Such a positive relationship between the remediation of post-mining soils and C sequestration indicates a step towards climate change mitigation. [ABSTRACT FROM AUTHOR]

Published

2022

11. Enhanced phytoremediation of soil heavy metals by arbuscular mycorrhizal fungi, Bacillus subtilis and CO2 release in Typha domingensis rhizosphere.

Author

Al-Maliki, Salwan and Al-Shamary, Ayat

Subjects

PHYTOREMEDIATION, HEAVY metals, CARBON dioxide, PAPYRUS (The plant), MYCORRHIZAS

Abstract

Phytoremediation is a green, cost-effective alternative to established soil remediation technologies. The recent bacterial-mycorrhizal revolution in combination with plants has resulted in significant advances in our knowledge of metal removal in polluted soils. However, depending on the biomass and size of the roots, each plant differs in its capacity to remove heavy metals. The study's objective was to study the effects of bacteria, mycorrhiza, papyrus, and CO2 release on lead (Pb) and cadmium (Cd) removal from the soil. Six different combinations (mycorrhiza, Bacillus 10 mL, Bacillus 100 mL, mycorrhiza + Bacillus 10 mL, mycorrhiza + Bacillus 100 mL, and control) were used in the experiment. The results showed that the combination of the mycorrhiza with bacillus 100 mL showed more profound increases in CO2 release and polysaccharide content (2.84 mg CO2 g−1 dry soil, 0.90 mg) respectively. More importantly, the highest concentrations of Cd and Pb were found in the roots of mycorrhiza + Bacillus 100 mL (18.26 mg kg−1 and 155.22 mg kg−1, respectively), implying that microbes played a concrete role in the phytoextraction process. The highest values of the translocation factor (TF) and biological accumulation factor (BAF) for Cd were found at Bacillus 100 mL (3.99) and (75.54), respectively, suggesting efficient translocation and excessive Cd accumulation in the plant. For Pb, Bacillus 100 mL and mycorrhiza + Bacillus 100 mL had the highest TF and BAF, which were 0.49 and 6.08 respectively. In conclusion, the removal of Cd and Pb was linked to the maximum bacterial cell density, mycorrhizal activity, and CO2 emission, resulting in unique phytoremediation in Pb–Cd contaminated papyrus rhizosphere soils. [ABSTRACT FROM AUTHOR]

Published

2022

12. Analytical assays to evaluate enzymatic activity and screening of inhibitors for ornithine decarboxylase.

Author

Tinoco, Luzineide W., da Silva Santos, Bruno Maia, da Silva Soares, Jhones Matheus, and Gadini Finelli, Fernanda

Subjects

ORNITHINE decarboxylase, MEDICAL screening, AFRICAN trypanosomiasis, TRANSMISSIBLE tumors, CHOICE (Psychology)

Abstract

Ornithine decarboxylase (ODC) catalyzes the decarboxylation of ornithine to produce putrescine, the first step in the metabolism of polyamines (putrescine, spermidine, and spermine), which are essential growth factors in eukaryotic cells. ODC is active as a homodimer and depends on pyridoxal 5'-phosphate (PLP) as a cofactor. An increase in the concentration of polyamines has been associated with carcinogenesis. Therefore, there is much interest in identifying inhibitors of this pathway as potential chemotherapeutic and chemopreventive agents. The best-known inhibitor of mammalian ODC is a-difluoromethylornithine (DFMO), a highly selective compound that alkylates Cys-360 (a residue of the ODC active site). Although DFMO was initially developed for the treatment of cancer, the World Health Organization recommends its use in combination with nifurtimox for the treatment of human African trypanosomiasis. Considering the importance of ODC as a promising target for the treatment of various types of cancer and other infectious diseases, choosing the right method for screening potential inhibitors can help to accelerate the discovery of new drugs. Several methods for the determination of ODC activity are found in the literature. Among these, we can mention analysis with radioactive markers, colorimetric assays using auxiliary enzymes to detectCO2 or H2O2 release, chromatographic separations with putrescine derivatization, mass spectrometry, and spectroscopic techniques. In this review, the main analysis methods used will be described, highlighting their advantages and disadvantages, as well as identifying the most promising methods for high-throughput screening. [ABSTRACT FROM AUTHOR]

Published

2022

13. Towards Energy-Efficient Direct Air Capture with Photochemically-Driven CO 2 Release and Solvent Regeneration.

Author

Premadasa UI, Doughty B, Custelcean R, and Ma YZ

Abstract

The intensive energy demands associated with solvent regeneration and CO 2 release in current direct air capture (DAC) technologies makes their deployment at the massive scales (GtCO 2 /year) required to positively impact the climate economically unfeasible. This challenge underscores the critical need to develop new DAC processes with significantly reduced energy costs. Recently, we developed a new approach to photochemically drive efficient release of CO 2 through an intermolecular proton transfer reaction by exploiting the unique properties of an indazole metastable-state photoacid (mPAH), opening a new avenue towards energy efficient on-demand CO 2 release and solvent regeneration using abundant solar energy instead of heat. In this Concept Article, we will describe the principle of our photochemically-driven CO 2 release approach for solvent-based DAC systems, discuss the essential prerequisites and conditions to realize this cyclable CO 2 release chemistry under ambient conditions. We outline the key findings of our approach, discuss the latest developments from other research laboratories, detail approaches used to monitor DAC systems in situ, and highlight experimental procedures for validating its feasibility. We conclude with a summary and outlook into the immediate challenges that must be addressed in order to fully exploit this novel photochemically-driven approach to DAC solvent regeneration., (© 2024 Wiley-VCH GmbH.)

Published

2024

14. Effects of differences in aboveground dead organic matter types on the stand‐scale necromass and CO2 efflux estimates in a subtropical forest in Okinawa Island, Japan.

Author

Abe, Hayato, Katayama, Ayumi, Taniguchi, Shingo, Takashima, Atsushi, Kume, Tomonori, and Matsumoto, Kazuho

Subjects

*COARSE woody debris, *FOREST litter, *ORGANIC compounds, *CARBON cycle

Abstract

Dead organic matter (DOM), which consists of leaf litter, fine woody debris (FWD; <3 cm diameter), downed coarse woody debris (CWDlog), and standing or suspended coarse woody debris (CWDsnag), contributes to forest carbon cycling; however, few studies have considered effects of differences in DOM types on the stand‐scale estimates of carbon stocks of necromass and CO2 efflux (Rstand). This study investigated characteristics of necromass and Rstand in a subtropical forest in Okinawa Island, Japan, to quantify the effect of DOM type on total necromass, total Rstand, and estimate error of total necromass and Rstand. The CWDsnag accounted for the highest proportion (54%) of total necromass (1499.7 g C m−2), followed by CWDlog (24%), FWD (11%), and leaf litter (11%). Leaf litter accounted for the highest proportion (37%) of total Rstand (340.6 g C m−2 year−1), followed by CWDsnag (25%), CWDlog (20%), and FWD (17%). The CWDsnag was distributed locally with 173% coefficient of variation for necromass, which was twofold higher than those of leaf litter and FWD (72%–73%). The potential error in CWD accounted for 99% and 79% estimate error for total necromass and Rstand, respectively. For the estimates of CWDsnag and CWDlog necromass with the estimates error of <10% in this study area, sampling areas of ≥28,750 m2 and ≥2058–42,875 m2, respectively, were required. Our results showed that CWD considerably contributed to stand‐scale carbon stocks and efflux among aboveground DOM in this forest, resulting in a major source of errors in the stand‐scale estimates. [ABSTRACT FROM AUTHOR]

Published

2022

15. Stability of biochar in five soils: Effects from soil property.

Author

Yang, Fan, Zuo, Xiuping, Zhou, Yingying, Wu, Shuang, and Wang, Mengyao

Subjects

BIOCHAR, SOILS, ENVIRONMENTAL chemistry, MOLECULAR structure, SOIL moisture, ACID soils

Abstract

The stability of biochar in soil was an important property influencing biochar environmental effects, most studies attributed biochar stability to its intrinsic molecular structure, but few realized that biochar stability mainly depended on soil environmental factors. In this study, biochar was applied into five soils with distinct properties, and CO2 release was detected during a 28‐days incubation, double‐exponential model was used to fit CO2 cumulative release. Correlation analysis between basic properties of five soils and parameters of double‐exponential model was conducted to screen out crucial soil factors affecting biochar stability. Argi‐Udic Ferrosols soil, showing best performance among five soils on protecting biochar stability, was selected to simulate paddy‐upland rotation, exploring the influence of abrupt increase of soil moisture on biochar stability. Results showed that CO2 release from biochar had negative correlation with clay and Fe content of soil (correlation coefficient was −0.68 ~ −0.61 and −0.60 ~ −0.26), whereas had positive correlation with pH and Ca content of soil (correlation coefficient was 0.29 ~ 0.69 and 0.74 ~ 0.91). Abrupt increase of moisture resulted in labile‐C loss from biochar increased by 1.4 times. It implied that biochar stability was an ecological property, and acid soil, rich in clay and Fe contents and less in Ca content, was more favorable to maintain biochar stability. Results in this study were helpful to understand environmental chemistry behavior of biochar and better perform its soil environmental effects. [ABSTRACT FROM AUTHOR]

Published

2022

16. Biodegradation of pesticides in soil amended with different organic matters

Author

Suhail, Faris Mohammed and Fahmi, Alaa Hasan

Published

2020

17. Carbon Footprint for Post-Mining Soils: The Dynamic of Net CO2 Fluxes and SOC Sequestration at Different Soil Remediation Stages under Reforestation

Author

Aneta Kowalska, Bal Ram Singh, and Anna Grobelak

Subjects

reforestation of post-mining soils, net CO2 emission, soil respiration, SOC, POXC, CO2 release, Technology

Abstract

The remediation of open-cast post-mining soil remains a big challenge. Here, the post-mining soils are considered from the viewpoints of CO2 emission and carbon sequestration. We investigated the dynamic of C stock in two different post-mining areas, i.e., the limestone post-mining soil remediated with embankment (S1), and the lignite post-mining soil remediated with sewage sludge (S2). Post-mining soils under four different remediation stages were used. The study was conducted in the spring of 2021 and 2022. The aim of the study was to assess the C sequestration in sewage sludge amended and non-amended post-mining soils at differently advanced remediation techniques. We noticed an increase in or stabilization of SOC in the S1. The stabilization of SOC was observed for the soil with a higher remediation age (S1C, S1D). The remediation of the S2 resulted in the increase in SOC among the soil remediation age. For both soils, we noticed a negative CO2 emission from the soil under remediation, and the net CO2 emission rate (NCER) further decreased after one year. A positive C feedback of both remediation techniques was shown to reflect lower active carbon (POXC). We also noticed an increase in nutrient content (K, Mg), and a decrease in heavy metals content after 1 year. Such a positive relationship between the remediation of post-mining soils and C sequestration indicates a step towards climate change mitigation.

Published

2022

18. THE ROLE OF PACKAGING IN LOGISTICS PROCESSES - IMPACT ON SUSTAINABLE LOGISTICS IN THE FOOD SECTOR

Author

Stefan Schmidt and Benjamin S. Godwin Schmidt

Subjects

packaging, logistics, sustainability, food sector, green logistics, shelf life, co2 release, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Packaging is one of the main factors of logistics. Its primary roles are protection, preservation, traceability, profitability, convenience / practicality and presentation, while its secondary roles are handling, containment (safety containers), identification, labelling and suitability. A wide range of regulatory measures, high standards and the correct handling of food in logistics processes ensure that food is delivered safely from the producer to the consumer. The essential role of packaging in logistics is to provide products with the necessary protection during storage and transport and to reduce costs. Packaging has a positive impact on product distribution and safety, particularly in the food industry, where it increases shelf life, facilitates transportation and helps to save costs. By carefully arranging and packaging the products in suitable packaging, the available space can be used optimally. This article presents the role of packaging in logistics processes such as transport, storage, loading and packaging of food with an explicit focus on sustainability. A case study shows the example of the overseas logistics chain of the avocado, a type of food with very high CO2 release and high water consumption. The status of the green logistics and further requirements for companies and consumers is demonstrated.

Published

2019

19. Mineralization of Organic Matter in Oil-Polluted and Remediated Oil-Polluted Soils in the Middle Taiga Zone of West Siberia under Laboratory Conditions.

Author

Trofimov, S. Y., Arzamazova, A. V., Kinzhaev, R. R., Khamutovskaia, A. V., and Karpykhin, M. M.

Abstract

Mineralization rates of soil organic matter (SOM) decomposition in nonremediated and remediated oil-polluted soils and background soils from the main types of West Siberian middle-taiga ecosystems have been measured in laboratory experiments. The rates of SOM mineralization were measured by alkali absorption of CO2 released from wet soil samples at 20°C (basal respiration). Taking into account the linear character of the cumulative curves of CO2 release, the rates of SOM mineralization were estimated using the mineralization index K1, equal to the annual amount of CO2 released per 1 g dry soil. The K1 values varied from 0.123 to 1.578 mg CO2/g/day. The highest value was recorded in the background forest soil, while the lowest value in the oil-polluted peat soil with extremely high oil content (544 g/kg). The K1 values were negatively correlated with oil content (K = –0.57). The SOM mineralization rate in remediated oil-polluted peat soils varied from 0.31 to 0.85 mg CO2/g/day. [ABSTRACT FROM AUTHOR]

Published

2021

20. 垄沟填埋秸秆发酵物对SSC番茄根区温度、CO2 释放及番茄生长的影响.

Author

杨佳佳, 刘义飞, and 刘文科

Subjects

CORN straw, STRAW, WHEAT straw, GREENHOUSES, COWPEA, TOMATOES, RICE straw

Abstract

Copyright of Journal of Agricultural Science & Technology (1008-0864) is the property of Journal of Agricultural Science & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

21. Biological drying of municipal solid waste from landfill.

Author

Slezak, Radosław, Krzystek, Liliana, and Ledakowicz, Stanisław

Subjects

*SOLID waste, *WASTE minimization, *LANDFILLS, *CHAR, *WASTE tires, *DRYING, *WASTE heat

Abstract

The aim of this work was to investigate the process of biodrying of municipal solid waste from the old landfill to preparing it for pyrolysis or gasification. New aspect of this research is biodrying of waste from old landfill. Biodrying of wastes was carried out at different aeration rates (7, 35, and 175 dm3/kg dry matter/d) at two temperatures (23 and 50 °C). The research was carried out in the laboratory bioreactors of special design (lysimeters), which simulated the conditions prevailing in the landfill. The optimal conditions for reduction of moisture in waste (63.2%) has been attained for the highest aeration rate (175 dm3/kg dry matter/d) and temperature equal to 50 °C. The final moisture content of the obtained biodried product was 23% w/w. In the bioreactor, in which the greatest reduction of moisture was obtained, the total amount of produced CO2 was 44.9 gC/kg dry matter, and the biodrying efficiency was equal to 0.89. During biodrying of wastes in optimal conditions, higher heating value of waste increased from 4.3 to 11.0 MJ/kg. As a result of the performed pyrolysis of biodried waste at 900 °C, char, oil, and gas were obtained the respective yields of 47, 32, and 21% w/w. The gas emerging in the gasification process was characterized by higher heating value equal to 11.3 MJ/m3. [ABSTRACT FROM AUTHOR]

Published

2020

22. THE POPULATION OF BACTERIA AND CO2 RELEASE ON PROCESS OF COMPOSTING MANURE AND SWAMP GRASS

Author

Diana Utama, Nuni Gofar, and Fitri Siti Nurul Aidil

Subjects

CO2 release, compost, manure, population, swamp grass, Environmental sciences, GE1-350

Abstract

This study aimed to analyze the bacteria population, the release of CO2, pH and organic-C and total-N in the process of compost made from manure and swamp grass. Treatment level consist of 100% manure (K100), 50% of manure + 50% swamp grass (K50R50), 25% of manure + 75% swamp grass (K25R75), and 10% of manure + 90% swamp grass (K10R90). The result of this study indicated the dynamic of different bacteria population on different composting materials by increasing of the composting time. The release of CO2 decrease on all treatment levels by increasing of the composting time. The pH value increased at all levels of treatment, except the composition of 100% manure. The best composition obtained by mixing of 10% manure and 90% swamp grass.

Published

2017

23. Enhanced phytoremediation of soil heavy metals by arbuscular mycorrhizal fungi, Bacillus subtilis and CO2 release in Typha domingensis rhizosphere

Author

Al-Maliki, Salwan and Al-Shamary, Ayat

Published

2022

24. Influence of CO2 on the Electrical Conductivity and Streaming Potential of Carbonate Rocks.

Author

Cherubini, A., Garcia, B., Cerepi, A., and Revil, A.

Subjects

*CARBONATE rocks, *CARBON dioxide, *WATER salinization, *DISSOCIATION (Chemistry), *CARBONATES

Abstract

Minimally intrusive geophysical methods are required to monitor CO2 leakages from underground storage reservoirs. We investigate the impact of gaseous CO2 on both electrical conductivity and electrokinetic properties of two limestones during their drainage. These data are contrasted with measurements performed on one clay‐free sandstone. The initial NaCl brine concentrations before drainage (from 8.5 to 17.1 mMol/L) correspond to the limit between freshwater and slightly brackish water. These values are representative to saturated brine formations inside which CO2 can be stored. Using these water salinities, the surface conductivity of the samples represents less than 5% of the overall electrical conductivity. A CO2 release leads to an increase of the electrical conductivity of the rock during drainage in limestones and no change in sandstone. This increase in the electrical conductivity is due to the dissolution of calcite with the concomitant release of Ca2+ and HCO3− in the pore water. It is not due to the CO2 dissociation in the pore water in the pore pressure range 0–0.5 MPa and at a temperature of T = 20 °C. The measurements of the streaming potential show a substantial decrease of the streaming potential coupling coefficient and zeta potential magnitudes after a CO2 release in carbonates. This observation is explained by the increase of the ionic strength of the pore water in the course of the experiment. This change can be used, in turn, to determine calcite dissolution rates from the measurement of the electrokinetic properties. Key Points: The dissolution of calcite leads to a decrease of the magnitude of the streaming potential coupling coefficientThe pore water conductivity is dominated by the calcite dissolution in carbonatesCalcite dissolution rates calculated from streaming potential measurements are consistent with PHREEQC simulations [ABSTRACT FROM AUTHOR]

Published

2019

25. Incorporación de abonos orgánicos y liberación de C-CO2 como indicador de la mineralización del carbono.

Author

Benedicto-Valdés, Gerardo Sergio, Montoya-García, César Omar, Vicente-Hernández, Zeferino, Ramírez-Ayala, Carlos, and Salvador Escalante-Estrada, José Alberto

Published

2019

26. Mechanism of oxidation and catalysis of organic matter abiotic humification in the presence of MnO2.

Author

Zhang, Yingchao, Yue, Dongbei, Wang, Xu, and Song, Wenfang

Subjects

*MANGANESE oxides, *CATALYSIS, *HUMIFICATION, *OXIDATION, *ORGANIC wastes

Abstract

Abstract Humification plays a critical role in the environmental fate of organic wastes, and MnO 2 holds great promise for enhancing this reaction. However, the effects of MnO 2 on the enhancement of the humification reaction remain ambiguous. To better reveal the mechanism by which MnO 2 enhances the reaction and investigate the fate of the humification products, abiotic humification experiments were performed using increasing concentrations of dissolved organic matter (DOM) to a fixed amount of MnO 2. DOM was represented by model humic precursors consisting of catechol, glucose and glycine. The results indicate that the reduction of MnO 2 played a dominant role in the formation of fulvic-like acids (FLAs), and the subsequent reduction products, MnOOH and Mn(II), acted as catalysts in the formation of humic-like acids (HLAs). Moreover, CO 2 release occurred during the formation of FLAs, and a strong linear correlation between CO 2 release and the formation of FLAs was observed (p < 0.01), where 0.73–1.87 mg of CO 2 was released per mg dissolved organic carbon (DOC) FLAs. Furthermore, the concentration of MnO 2 had a pronounced influence on the product behavior, where a lower MnO 2 concentration decreased the quantity of FLAs produced. Graphical abstract Proposed oxidation catalysis mechanisms of MnO 2 and the related reduction products in the abiotic humification of organic matter. Unlabelled Image [ABSTRACT FROM AUTHOR]

Published

2019

27. Unrevealing the potential of microbes in decomposition of organic matter and release of carbon in the ecosystem.

Author

Raza, Taqi, Qadir, Muhammad Farhan, Khan, Khuram Shehzad, Eash, Neal S., Yousuf, Muhammad, Chatterjee, Sumanta, Manzoor, Rabia, Rehman, Sana ur, and Oetting, Joel Nathaniel

Subjects

*ATMOSPHERIC carbon dioxide, *ORGANIC compounds, *ECOSYSTEMS, *CARBON emissions, *CLIMATE change, *PLANT exudates, *CARBON cycle

Abstract

Organic matter decomposition is a biochemical process with consequences affecting climate change and ecosystem productivity. Once decomposition begins, C is lost as CO 2 or sequestered into more recalcitrant carbon difficult to further degradation. As microbial respiration releases carbon dioxide into the atmosphere, microbes act as gatekeepers in the whole process. Microbial activities were found to be the second largest CO 2 emission source in the environment after human activities (industrialization), and research investigations suggest that this may have affected climate change over the past few decades. It is crucial to note that microbes are major contributors in the whole C cycle (decomposition, transformation, and stabilization). Therefore, imbalances in the C cycle might be causing changes in the entire carbon content of the ecosystem. The significance of microbes, especially soil bacteria in the terrestrial carbon cycle requires more attention. This review focuses on the factors that affect microorganism behavior during the breakdown of organic materials. The key factors affecting the microbial degradation processes are the quality of the input material, nitrogen, temperature, and moisture content. In this review, we suggest that to address global climate change and its effects on agricultural systems and vice versa, there is a need to double-up on efforts and conduct new research studies to further evaluate the potential of microbial communities to reduce their contribution to terrestrial carbon emission. [Display omitted] • Microbes are the player of climate and involved in transfer of C state in ecosystem. • Microorganisms are responsible for processing plant photosynthetic C inputs to soil. • The priming effect alters the microbial biomass turnover on C addition. • Bacteria easily degrade plant exudate while fungi breakdown more resistant compounds. • New model required for understanding of SOC dynamics driven by microbes & Nutrients. [ABSTRACT FROM AUTHOR]

Published

2023

28. Decreased soil microbial nitrogen under vegetation 'shrubification' in the subarctic forest–tundra ecotone : the potential role of increasing nutrient competition between plants and soil microorganisms

Author

Sari Stark, Manoj Kumar, Eero Myrsky, Jere Vuorinen, Anu M. Kantola, Ville-Veikko Telkki, Sofie Sjögersten, Johan Olofsson, and Minna K. Männistö

Subjects

tundra heath, Ekologi, mountain birch forest, Ecology, Empetrum hermaphroditum, soil organic matter, Environmental Chemistry, extracellular enzymes, CO2 release, Ecology, Evolution, Behavior and Systematics, climate warming

Abstract

The consequences of warming-induced ‘shrubification’ on Arctic soil carbon storage are receiving increased attention, as the majority of ecosystem carbon in these systems is stored in soils. Soil carbon cycles in these ecosystems are usually tightly coupled with nitrogen availability. Soil microbial responses to ‘shrubification’ may depend on the traits of the shrub species that increase in response to warming. Increase in deciduous shrubs such as Betula nana likely promotes a loss of soil carbon, whereas the opposite may be true if evergreen shrubs such as Empetrum hermaphroditum increase. We analyzed soil organic matter stocks and 13C NMR fractions, microbial CO2 respiration, biomass, extracellular enzyme activities (EEAs), and their association with shrub density in northern Sweden after 20 years of experimental warming using open top chambers (OTCs). Our study sites were located in a tundra heath that stores high soil carbon quantities and where the OTCs had increased deciduous shrubs, and in a mountain birch forest that stores lower soil carbon quantities and where the OTCs had increased evergreen shrubs. We predicted that organic matter stocks should be lower and respiration and EEAs higher inside the OTCs than untreated plots in the tundra, whereas no effect should be detected in the forest. Soil organic matter stocks and 13C NMR fractions remained unaffected at both sites. When expressed as per gram microbial biomass, respiration and EEAs for carbohydrate and chitin degradation were higher inside the OTCs, and contrasting our prediction, this effect was stronger in the forest. Unexpectedly, the OTCs also led to a substantially lower microbial biomass carbon and nitrogen irrespective of habitat. The decline in the microbial biomass counteracted increased activities resulting in no effect of the OTCs on respiration and a lower phenol oxidase activity per gram soil. Microbial biomass nitrogen correlated negatively with evergreen shrub density at both sites, indicating that ‘shrubification’ may have intensified nutrient competition between plants and soil microorganisms. Nutrient limitation could also underlie increased respiration per gram microbial biomass through limiting C assimilation into biomass. We hypothesize that increasing nutrient immobilization into long-lived evergreen shrubs could over time induce microbial nutrient limitation that contributes to a stability of accumulated soil organic matter stocks under climate warming.

Published

2023

29. Mathematical model of CO2 release during milk fermentation using natural kefir grains.

Author

Goršek, Andreja, Pečar, Darja, and Ritonja, Jožef

Subjects

*KEFIR, *FERMENTATION, *BIOLOGICAL mathematical modeling, *VOLATILE organic compounds, *CARBONYL compounds

Abstract

Abstract: BACKGROUND: Milk fermentation takes place in the presence of various micro‐organisms, producing a variety of dairy products. The oldest of them is kefir, which is usually produced by the fermentation of milk with kefir grains. Carbon dioxide (CO2), as one of the process products, also contributes to the characteristic flavor of kefir. The amount of CO2 generated during fermentation depends on bioprocessing conditions and may change, which is not desirable at the industrial level. RESULTS: In this study we developed a simplified mathematical model of CO2 release in the milk‐fermentation process. An intuitive approach based on superposition and experimental analysis was used for the modeling. The chemical system studied was considered as a two‐input (temperature, rotational frequency of the stirrer) one‐output (CO2 concentration) dynamic system. CONCLUSION: Based on an analysis of CO2 release transients in the case of non‐simultaneous stepwise changed input quantities, two differential equations were defined that describe the influence of the two input quantities on the output quantity. The simulation results were verified by experiments. The proposed model can be used for a comprehensive analysis of the process that is being studied and for the design and synthesis of advanced control systems, which will ensure a controlled CO2 release at the industrial level. © 2018 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2018

30. 正交试验法优选复方清肺泡腾片成型工艺.

Author

陀海燕, 苏健, 罗毅, 曾佩琴, 莫丽萍, 梁丹, 罗春花, 韦艳萍, and 陈卫卫

Abstract

Copyright of Food Research & Development is the property of Food Research & Development Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

31. Structure of the thoracic spiracular valves and their contribution to unidirectional gas exchange in flying blowflies Calliphora vicina.

Author

Wasserthal, Lutz T. and Fröhlich, Anja S.

Subjects

*SPIRACLE (Insect anatomy), *INSECT anatomy, *TRICHOMES, *PHOTOELECTRIC cells, *ATMOSPHERIC pressure

Abstract

The operation of the thoracic spiracular valves was analysed using anatomical and physiological techniques. Dense spiracular filter trichomes impede a diffusive gas exchange. However, the hinged posterior filter flap of the metathoracic spiracle (Sp2) opens passively during upstroke of the wings and closes by the suction of the subatmospheric tracheal pressure during the downstroke, which supports a unidirectional respiratory airflow. The action of the interior spiracular valve lids was recorded by photocell sensors oriented above the enlarged spiracles and projected onto the screen of a video camera. The thoracic spiracles opened much quicker (approximately 0.1 s) than they closed (1 s), suggesting that the spiracular muscles are openers, as confirmed by experimental induction of muscle contraction. Simultaneous photocell measurement revealed that the first and second thoracic spiracles act concordantly. At rest, the spiracles were mostly closed or only slightly open (<1%). During intermittent short flights, the valves opened wide at the start of the flight for a short time, and in many cases opened again after the flight ended. Often, the opening was wider after the flight ended than during the flight itself. During long spontaneous continuous flight phases (up to 2 h), the valves were only slightly open (<5%), widening shortly after transient increases of wing stroke intensity. It is an amazing paradox that the spiracles were only slightly open when the requirement for O2 was high during sustained flight. The advantage of generating sub-atmospheric pressure, supporting a unidirectional airflow with a PO2 increase above the resting level, is discussed. [ABSTRACT FROM AUTHOR]

Published

2017

32. Photochemically-Driven CO 2 Release Using a Metastable-State Photoacid for Energy Efficient Direct Air Capture.

Author

Premadasa UI, Bocharova V, Miles AR, Stamberga D, Belony S, Bryantsev VS, Elgattar A, Liao Y, Damron JT, Kidder MK, Doughty B, Custelcean R, and Ma YZ

Abstract

One of the grand challenges underlying current direct air capture (DAC) technologies relates to the intensive energy cost for sorbent regeneration and CO 2 release, making the massive scale (GtCO 2 /year) deployment required to have a positive impact on climate change economically unfeasible. This challenge underscores the critical need to develop new DAC processes with substantially reduced regeneration energies. Here, we report a photochemically-driven approach for CO 2 release by exploiting the unique properties of an indazole metastable-state photoacid (mPAH). Our measurements on simulated and amino acid-based DAC systems revealed the potential of mPAH to be used for CO 2 release cycles by regulating pH changes and associated isomers driven by light. Upon irradiating with moderate intensity light, a ≈55 % and ≈68 % to ≈78 % conversion of total inorganic carbon to CO 2 was found for the simulated and amino acid-based DAC systems, respectively. Our results confirm the feasibility of on-demand CO 2 release under ambient conditions using light instead of heat, thereby providing an energy efficient pathway for the regeneration of DAC sorbents., (© 2023 Wiley-VCH GmbH.)

Published

2023

33. Micro-cellulose Sheet and Polyvinyl Alcohol Blended Film for Active Packaging

Author

Shukla, S. K., Rizwana, Bharadvaja, Anand, and Dubey, G. C.

Published

2019

34. Tracking solvent and protein movement during CO2 release in carbonic anhydrase II crystals.

Author

Chae Un Kim, HyoJin Song, Avvaru, Balendu Sankara, Gruner, Sol M., SangYoun Park, and McKenna, Robert

Subjects

*CARBONIC anhydrase, *CARBON dioxide, *CATALYSIS research, *ZINC enzymes, *METALLOENZYMES

Abstract

Carbonic anhydrases are mostly zinc metalloenzymes that catalyze the reversible hydration/dehydration of CO2/HCO3-. Previously, the X-ray crystal structures of CO2-bound holo (zinc-bound) and apo (zinc-free) human carbonic anhydrase IIs (hCA IIs) were captured at high resolution. Here, we present sequential timeframe structures of holo- [T = 0 s (CO2-bound), 50 s, 3 min, 10 min, 25 min, and 1 h] and apo-hCA IIs [T = 0 s, 50 s, 3 min, and 10 min] during the "slow" release of CO2. Two active site waters, WDW (deep water) and WDW' (this study), replace the vacated space created on CO2 release, and another water, WI (intermediate water), is seen to translocate to the proton wire position W1. In addition, on the rim of the active site pocket, a water W2' (this study), in close proximity to residue His64 and W2, gradually exits the active site, whereas His64 concurrently rotates from pointing away ("out") to pointing toward ("in") active site rotameric conformation. This study provides for the first time, to our knowledge, structural "snapshots" of hCA II intermediate states during the formation of the His64-mediated proton wire that is induced as CO2 is released. Comparison of the holo- and apo-hCA II structures shows that the solvent network rearrangements require the presence of the zinc ion. [ABSTRACT FROM AUTHOR]

Published

2016

35. Estudo da decomposição de plantas aquáticas em função das quantidades depositadas, da umidade e do tipo de disposição no solo Study on aquatic plant decomposition due to amount deposited, moisture and type of placement in soil

Author

E.D. Velini, M.R. Corrêa, E. Negrisoli, L.F.N Bravin, A.L. Cavenaghi, C.V.S. Rossi, and J.R.M. Silva

Subjects

macrófitas aquáticas, degradação, liberação de CO2, aquatic macrophytes, degradation, CO2 release, Biology (General), QH301-705.5, Botany, QK1-989

Abstract

Um estudo foi realizado com a finalidade de avaliar a decomposição da biomassa de plantas aquáticas, incorporadas ou não ao solo, provenientes do controle mecânico, no reservatório da UHE Americana. O ensaio foi realizado em casa de vegetação, localizada no Núcleo de Pesquisas Avançadas em Matologia (NUPAM) da FCA/Unesp-Botucatu. A avaliação foi conduzida em vasos contendo 14 kg de solo, simulando descartes de 50, 100, 150 e 200 t MF de plantas ha-1 e avaliando o processo de decomposição através da liberação de CO2, divididos em duas etapas: a primeira em solo seco e, a segunda, na seqüência, com o solo úmido. A quantificação do CO2 liberado foi realizada através de titulação de solução adicionada ao processo de incubação de 24 horas dos vasos. Os dados foram interpolados e analisados seguindo modelo de Mitscherlich, com algumas modificações. Na primeira etapa, foi observada uma rápida liberação de CO2 até o décimo dia, seguida de estabilização. O maior teor de CO2 liberado foi observado no tratamento com descarte de 200 t MF ha-1 incorporado ao solo. Os dados avaliados durante a segunda fase do ensaio representaram uma maior linearidade no processo de liberação de CO2, indicando um período mais longo do processo de degradação da biomassa descartada.A study was carried out to evaluate biomass decomposition of aquatic macrophytes incorporated or not into soil, due to mechanical control, at the Americana/SP UHE Reservoir. Analysis was performed in a greenhouse at the Weed Science Research Center (NUPAM), UNESP, Botucatu. Plastic vases containing 24 kg of soil were assessed by simulating discards of 50, 100, 150 and 200 t of fresh matter ha-1.The decomposition process was evaluated by CO2 release, divided into two stages: dry soil and wet soil. Quantification of released CO2 was performed through titration of solution added to vase incubation. Data were interpolated and analyzed by Mitscherlich model with some modifications. A quick CO2 release up to the 10th day was observed in the first stage (dry soil), followed by stabilization. The highest CO2 content released was observed in the 200 t MF ha-1 discard treatment incorporated into soil. Data assessed during the second stage (wet soil) showed a higher linearity in the CO2 release process, indicating a longer period of discarded biomass decomposition.

Published

2005

36. THE ROLE OF PACKAGING IN LOGISTICS PROCESSES - IMPACT ON SUSTAINABLE LOGISTICS IN THE FOOD SECTOR

Author

Benjamin S. Godwin Schmidt and Stefan Schmidt

Subjects

Sustainable logistics, logistics, packaging, co2 release, General Medicine, sustainability, food sector, Food sector, lcsh:TA1-2040, shelf life, Business, green logistics, lcsh:Engineering (General). Civil engineering (General), Industrial organization

Abstract

Packaging is one of the main factors of logistics. Its primary roles are protection, preservation, traceability, profitability, convenience / practicality and presentation, while its secondary roles are handling, containment (safety containers), identification, labelling and suitability. A wide range of regulatory measures, high standards and the correct handling of food in logistics processes ensure that food is delivered safely from the producer to the consumer. The essential role of packaging in logistics is to provide products with the necessary protection during storage and transport and to reduce costs. Packaging has a positive impact on product distribution and safety, particularly in the food industry, where it increases shelf life, facilitates transportation and helps to save costs. By carefully arranging and packaging the products in suitable packaging, the available space can be used optimally. This article presents the role of packaging in logistics processes such as transport, storage, loading and packaging of food with an explicit focus on sustainability. A case study shows the example of the overseas logistics chain of the avocado, a type of food with very high CO2 release and high water consumption. The status of the green logistics and further requirements for companies and consumers is demonstrated.

Published

2019

37. Partitioning riverine sulfate sources using oxygen and sulfur isotopes: Implications for carbon budgets of large rivers

Author

Edward T. Tipper, Daniel R. Parsons, Stephen E. Darby, Mike J. Bickle, Emily I. Stevenson, Alexandra V. Turchyn, K. Relph, Gilad Antler, J. Jotautas Baronas, Stevenson, EI [0000-0003-3907-443X], Bickle, MJ [0000-0001-8889-3410], Darby, SE [0000-0001-8778-4394], Tipper, ET [0000-0003-3540-3558], and Apollo - University of Cambridge Repository

Subjects

010504 meteorology & atmospheric sciences, Sulfide, chemistry.chemical_element, Weathering, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, chemical weathering, chemistry.chemical_compound, Geochemistry and Petrology, pyrite oxidation, Tributary, Earth and Planetary Sciences (miscellaneous), Sulfate, 0105 earth and related environmental sciences, chemistry.chemical_classification, Mekong, geography, Anhydrite, geography.geographical_feature_category, oxygen isotopes, sulfuric acid, Sulfuric acid, Sulfur, Geophysics, chemistry, Space and Planetary Science, Environmental chemistry, engineering, Pyrite, CO2 release, Geology

Abstract

The weathering of carbonate rocks with sulfuric acid releases carbon dioxide (CO 2) to the atmosphere, offsetting the CO 2 drawdown from carbonic acid weathering of silicates thought to regulate global climate. Quantifying CO 2 release from sulfuric acid weathering requires the partitioning of riverine sulfate between its two main sources: sedimentary sulfate and sulfide. Although the sulfur (δ 34S SO 4 ) and oxygen (δ 18O SO 4 ) isotope ratios of sedimentary sulfates (gypsum and anhydrite) of different ages are well constrained, the δ 34S of sulfide minerals is highly variable, restricting the utility of δ 34S for partitioning sulfur sources. Here, we use oxygen isotope ratios in the river water (δ 18O H 2O ) and sulfate molecules (δ 18O SO 4 ) to partition the fraction of sulfate and associated uncertainty delivered by the oxidative weathering of pyrite (f pyr). The partitioning is illustrated using the Mekong River, one of the world's largest river basins, presenting new δ 18O SO 4 , δ 18O H 2O and δ 34S SO 4 data collected on 18 tributaries and 6 mainstem sites over two field seasons at peak flux. The geological, geomorphological and climatic diversity of the Mekong River basin make it an ideal field site to quantify the role of sulfuric acid weathering and its implications for the carbon cycle. There is a 12‰ range in both the difference between δ 18O SO 4 and δ 18O H 2O (Δ 18O SO 4−H 2O ) and δ 34S in the river waters of the basin. In the Mekong tributaries, sources of sulfate are highly variable with the fraction of sulfate derived from pyrite oxidation (f pyr) ranging from 0.19 to 0.84. In the mainstem, f pyr reflects the flux-weighted mean of these tributary inputs, with 56±7% (1σ) of the sulfate delivered to the ocean at the Mekong mouth being derived from the oxidative weathering of pyrite. As a result, we estimate that ∼70% of CO 2 consumed through silicate weathering in the Mekong basin is offset by the release of CO 2 via the dissolution of carbonates by sulfuric acid.

Published

2021

38. Flight-motor-driven respiratory airflow increases tracheal oxygen to nearly atmospheric level in blowflies (Calliphora vicina).

Author

Wasserthal, Lutz T.

Subjects

*BLOWFLIES, *INSECT flight, *RESPIRATION, *ATMOSPHERIC oxygen, *AIR flow, *SPIRACLE (Insect anatomy), *INSECTS

Abstract

It is widelyaccepted that an efficient oxygen supplyand removal of CO2 in small flying insects are sufficiently performed by diffusion with open spiracles. This paper shows that in the tethered flying blowfly, gas exchange occurs byautoventilation and unidirectional airflow. The air is inspired through the mesothoracic spiracles (Sp1) during the downstroke of the wings and is expired through the metathoracic spiracles (Sp2) during the upstroke. This directed airflow through the thoracic tracheal system was documented by pre-atrial pressure measurements at the Sp1 and Sp2, revealing a sub-atmospheric mean pressure at the Sp1 and an over-atmospheric mean pressure at the Sp2. In the mesothoracic air sacs, the mean pressure is subatmospheric, conditioned by the only slightly open spiracles. In a split flow-through chamber experiment, the CO2 released through the Sp2 confirmed this unidirectional respiratory gas flow, implicating an inner tracheal valve. In the thoracic tracheal system, the PO2 during flight exceeds the high resting PO2 by 1-2 kPa, reaching nearly atmospheric values. In the abdominal large air sacs, the PO2 drops during flight, probably due to the accumulation of CO2. Periodic heartbeat reversals continue during flight, with a higher period frequency than at rest, supporting the transport of CO2 via the haemolymph towards the metathoracic tracheae and abdominal air sacs. [ABSTRACT FROM AUTHOR]

Published

2015

39. Periodic heartbeat reversals cause cardiogenic inspiration and expiration with coupled spiracle leakage in resting blowflies, Calliphora vicina.

Author

Wasserthal, Lutz T.

Subjects

*RESPIRATION, *HEART beat, *HEMOLYMPH, *TRACHEA, *CARBON dioxide, *SPIRACLE (Insect anatomy), *PHYSIOLOGICAL transport of oxygen, *CALLIPHORA, *INSECTS

Abstract

Respiration in insects is thought to be independent of the circulatory system because insects typically lack respiratory pigments and because oxygen transport occurs in the gaseous phase through a ramified tracheal system by diffusion and convection directly to the tissues. In the blowfly, as in other insects with periodic heartbeat reversal, the haemolymph is periodically shifted between the anterior body and abdomen, exerting alternating pressure changes on the compliant tracheae in the thorax and in the abdomen. Simultaneous pressure and O2 optode measurements show that, during negative pressure periods, the tracheal partial pressure of oxygen (PO2) increases by 0.5 kPa. In the quiescent fly, tracheal PO2 is rather high (17.5-18.9 kPa), although the thoracic spiracles remain constricted. Microscopic video recordings and reflectance measurements revealed that the dorsal soft edges of the valve lips of the second spiracle leave a very small leak, which is passively widened during backward pulses of the heart. Thus, negative pressure, combined with increased leakage of the spiracle Sp2 valve enable inspiration in the thorax. The positive pressure periods are correlated with a new type of convective CO2 micro-bursts as shown in flow-through measurements. The bulk of the CO2 is, however, released after longer interbursts in macro-bursts with actively opening valves reminiscent of the open phase in a cyclic gas exchange. When the valves open, the PO2 in the thoracic air sacs unexpectedly drops by a mean of 2.75±1.09 kPa, suggesting a displacement of O2 by the transient accumulation of CO2 in the tracheal system before its release. [ABSTRACT FROM AUTHOR]

Published

2014

40. Carbon mineralization kinetics in soils under urban environment.

Author

Saviozzi, Alessandro, Vanni, Giacomo, and Cardelli, Roberto

Subjects

*MINERALIZATION, *SOIL mineralogy, *CARBON in soils, *ENVIRONMENTAL impact analysis, *URBAN soils, *SOIL degradation

Abstract

Highlights: [•] C mineralization process in urban soils is described by several kinetic models. [•] C mineralization in urban soils is related to many different features. [•] The kinetic models identify two differently degradable organic pools. [ABSTRACT FROM AUTHOR]

Published

2014

41. Vertical CO2 Release Experiments from a 1 Liter High Pressure Vessel.

Author

Hulsbosch-Dam, Corina, de Jong, Arjen, Zevenbergen, John, Peeters, Rick, and Spruijt, Mark

Abstract

Abstract: High-speed CO2 release experiments from a pressurized vessel have been conducted for a range of storage pressures nozzle diameters. The experiments are conducted to validate and develop models for accidental releases of CO2 during transport. In cooperation with DNV-KEMA lab (Groningen, The Netherlands), medium scale experiments with a 500 liter tank have been designed and performed in spring of 2012. The results of this experiment are reported in a separate GHGT paper by Ahmad et al. [5]. In preparation of these experiments, some optical measurement techniques have been tested in a smaller set-up of a 1liter vessel, carried out at the TNO Rijswijk facility. These preparatory experiments will be discussed in the current document. A number of optical techniques are evaluated in relation to the observed phenomena. The tested techniques are: HD resolution standard optical camera, HS (high speed) camera and IR (infra-red) camera. In addition some experiments were performed using the PIV (Particle Image Velocimetry) technique, which is reported in a separate paper by de Jong et al. [4]. [Copyright &y& Elsevier]

Published

2013

42. Particle Image Velocimetry for Quantification of High Pressure CO2 Release.

Author

de Jong, Arjen and Spruijt, Mark

Abstract

Abstract: In the current work evaluation of CO2 release velocity profiles is determined using Particle Image Velocimetry (PIV). The formation of solid CO2 particles using the rapid expansion of nozzle flow is used as a seeder particle, making the method truly nonintrusive and negates the use of special seeder equipment. Preliminary tests have been conducted on low speed large CO2 particles. High-speed release PIV experiments have been conducted for a range of storage pressures between 60 and 150 bars using a 13mm (1/2 inch) diameter nozzle. The current paper is reporting combined research with a second paper by Dam et al. [4]. The current investigation is a small scale experiment prior to reported mid scale experiments reported in Ahmed et al. [5]. [Copyright &y& Elsevier]

Published

2013

43. Incorporación de abonos orgánicos y liberación de C-CO2 como indicador de la mineralización del carbono

Author

Escalante Estrada, José Alberto, Benedicto Valdés, Gerardo Sergio, Montoya-García, César Omar, Vicente-Hernández, Zeferino, Ramírez Ayala, Carlos, Escalante Estrada, José Alberto, Benedicto Valdés, Gerardo Sergio, Montoya-García, César Omar, Vicente-Hernández, Zeferino, and Ramírez Ayala, Carlos

Abstract

Sustainable agriculture promotes the reduction of chemical fertilizers with organic waste and increases soil fertility. With the incorporation of organic waste, a poorly evaluated effect is the emission of CO2 which would be an indicator of carbon mineralization and nutrient release for crops. The objective of this study was to assess the incorporation of three organic fertilizers: goat manure (GM), bovine manure (BM) and chicken manure (CM), with two doses of 4.5 and 9.0 kg m-2, to determine the release and accumulation of C-CO2 under laboratory conditions for 95 days. BM applications increased the pH, electrical conductivity, organic carbon, total nitrogen, and CO2 emission and release compared to the other fertilizers. Greater effects were observed for organic fertilizers at a depth of 0 to 15 cm in all study variables. CO2 accumulation is related to carbon mineralization, which was higher in BM followed by CM and GM. The addition of BM to the soil is an option to increase carbon mineralization and maintain crop productivity in a sustainable manner., RESUMEN: La agricultura sustentable promueve la reducción de fertilizantes químicos con residuos orgánicos, e incrementa la fertilidad del suelo. Con la incorporación de residuos orgánicos, un efecto poco evaluado es la emisión de CO2 el cual resultaría un indicador de la mineralización del carbono y la liberación de nutrientes para los cultivos. El objetivo del presente estudio fue evaluar la incorporación de tres abonos orgánicos: estiércol caprino (EC), estiércol bovino (EB) y gallinaza (EG), con dos dosis de 4.5 y 9.0 kg m-2, para determinar la liberación y acumulación de C-CO2 en condiciones de laboratorio por 95 días. Las aplicaciones de EB incrementaron el pH, conductividad eléctrica, carbono orgánico, nitrógeno total, emisión y liberación de CO2 en comparación con los otros abonos. Se observaron mayores efectos por los abonos orgánicos a la profundidad de 0 a 15 cm en todas las variables de estudio. La acumulación de CO2 se relaciona con la mineralización del carbono, esta fue mayor en EB seguido de EG y EC. La adición de EB al suelo es una opción para incrementar la mineralización del carbono y mantener la productividad de los cultivos de manera sustentable.

Published

2019

44. Effects of fertilizer-modes on soil CO2 emission in post-harvest paddy.

Author

ZHANG Shu-juan, WANG Li, MA Fang, ZHANG Xue, XU Ya-nan, LI Zhe, and JIANG Xiao-feng

Subjects

FERTILIZERS, CARBON dioxide, PHOTOSYNTHESIS, NITROGEN fertilizers, PHOSPHATE fertilizers, PADDY fields, SOILS

Abstract

The release rate of soil CO2 and its factors were measured with CIRAS-2 portable photosynthesis system, then their relationship was analyzed to investigate the influences of the additional nitrogen fertilizer, phosphate fertilizer and arbuscular fertilizer on characteristics of soil CO2 release in paddy. The results showed that: (1) The addition of nitrogen fertilizer resulted in soil CO2 release rate rising by 97.73% in 0 cm layer, and dropped by 39.93% and 31.36% in 10 cm and 20 cm layer, respectively. (2) While there was no significant difference between soil CO2 release rates after the addition of phosphate fertilizer and of CK in 0 cm layer, the rate dropped 33.84% in 10 cm layer and rose 48.03% in 20 cm layer. (3) The additional arbuscular fertilizer had no significant influence on all three layers. (4) The related coefficients of soil CO2 releasing rates and their factors in the same layers were affected by the fertilizer-modes, and its impact became lighter with the increasing of depth. Compared with nitrogen fertilizer and phosphate fertilizer, mycorrhizal fertilizer had no significant influence on the soil CO2 release. [ABSTRACT FROM AUTHOR]

Published

2012

45. Combining local pressure and temperature measurements during bread baking: insights into crust properties and alveolar structure of crumb

Author

Grenier, D., Le Ray, D., and Lucas, T.

Subjects

*BREAD, *BAKING, *TEMPERATURE measurements, *PRESSURE transducers, *THERMOCOUPLES, *GELATION, *DOUGH, *PERMEABILITY

Abstract

Abstract: Improvements in both the miniaturisation and heat compensation of pressure transducers made it possible to measure pressures as low as 5kPa inside bread dough during baking (ΔT =80°C). Additional calibration was found to be necessary to decrease it below 0.18kPa according to the variations in temperature encountered during baking. Two probes with both a thermocouple and a miniature pressure transducer were used to reveal pressure gradients inside bread dough during baking and post-cooling. During baking, increase in pressure (up to 1.1kPa) was mainly attributed to the mechanical restrictions exerted on the dough by the stiffened surface layers. Pressure build-up due to the stiffening of bubble walls could not be detected. Various effects of the rupture in the bubble walls are reported. Sudden falls in pressure observed up to 70°C were attributed to the bubble coalescence phenomenon. Evidence of an open porous structure was provided by the balance in pressure through the dough before the end of baking and the almost simultaneous lowering of pressure (−0.15kPa) throughout the crumb during cooling. The slight lowering of pressure during post-cooling was also evidence of lower permeability of the crust compared to the crumb. [Copyright &y& Elsevier]

Published

2010

46. CO2 release in vertical tube falling film evaporators

Author

Donner, Jan-Helge, Fokken, Jürren, Boeck, Katharina, Glade, Heike, and Will, Stefan

Subjects

*PHYSICAL & theoretical chemistry, *CHEMICAL apparatus, *SALINE waters, *SIMULATION methods & models

Abstract

Abstract: The release of non-condensable (NC) gases, essentially carbon dioxide, oxygen and nitrogen, from the evaporating brine in desalination distillers notably affects the heat transfer for condensation, the energy consumption, the performance and the material life span of the distillers. A better knowledge of CO2 release and of the interaction with the carbonate system in desalination distillers is very important for the design of the venting system and a stable distiller operation. Since CO2 release and scale formation are closely related to the carbonate system of the brine, a better understanding of CO2 release may contribute to the knowledge of scale formation in desalination distillers and improve scale prediction and prevention methods. A model has been developed for the prediction of the CO2 release rates in falling film evaporators with vertical tubes. The theory of mass transfer coupled with chemical reaction kinetics (chemical desorption) was applied to the problem of CO2 release. The mass transfer and the chemical reaction kinetics were studied for the conditions prevailing in falling film seawater evaporators. In addition to the CO2 release rates the model allows for calculation of the HCO3 −, CO3 2−, CO2, H+, and OH− concentrations in the carbonate system of the brine. The model was applied to a falling film evaporator at various operating conditions. The release rates of CO2 along the flow path of the falling film were determined. The paper presents the main principles of the model and discusses the simulation results. The effects of process parameters and the seawater properties such as evaporation temperature, seawater salinity, and pH value on the CO2 release rates are shown. Moreover, the paper discusses in which desorption regime (e.g. slow, fast, instantaneous) the CO2 release process takes place and whether the mass transfer is enhanced by the chemical reactions. [Copyright &y& Elsevier]

Published

2008

47. Modeling of CO2 release and the carbonate system in multiple-effect distillers

Author

Glade, Heike and Al-Rawajfeh, Aiman Eid

Subjects

*SPACE environment, *CHEMICAL processes, *CHEMICAL reactions, *THERMODYNAMICS

Abstract

Abstract: The release of CO2 in multiple-effect distillers has scarcely been investigated and little has been published about it. There is no approach available to reliably predict the release rates in individual stages and the effects of influencing parameters. Until now the dimensioning of the design venting rates has been based mainly on experience and very sparse experimental data. The present work was aimed at gaining an in-depth understanding of the physical and chemical processes involved in CO2 release and the carbonate system in multiple-effect distillers. A model has been developed that describes the CO2 release and the carbonate system in multiple-effect distillers. Included is the flow path of brine through the final condenser and the evaporator stages. The desorption of CO2 was described as a problem of coupled mass transfer with chemical reaction. The mass transfer coefficient and the phase interface area were studied for the fluid dynamics of falling water films on horizontal tubes. [Copyright &y& Elsevier]

Published

2008

48. Effects of crust constraints on bread expansion and CO2 release

Author

Zhang, Lu, Lucas, T., Doursat, C., Flick, D., and Wagner, M.

Subjects

*BREAD, *BAKING, *MAGNETIC resonance imaging, *POROSITY, *DYNAMICS

Abstract

Abstract: Artificial covers were designed and used to study the effects of crust constraints on bread expansion and gas release during baking. The results were interpreted by comparison with the results of simulations using a mathematical model of baking. The cover levels were set at 45mm, 50mm and 55mm, as the maximum height reached by the dough without cover under the conditions studied was 60mm. MRI images were used to evaluate the local porosity of the crumb. Porosity kinetics showed that different cover levels resulted in densification within the crumb structure: the later the dough encountered the cover, the deeper the dense crumb formed in the loaf. The kinetics of CO2 release were monitored with an infrared detector and the results showed that the lower the cover level the shorter the induction time. The predominant role of crust setting in the CO2 release response was demonstrated. [Copyright &y& Elsevier]

Published

2007

49. Scaling in multiple-effect distillers: the role of CO2 release

Author

Al-Rawajfeh, Aiman Eid, Glade, Heike, and Ulrich, Joachim

Subjects

*SALINE water conversion, *WATER purification, *WATER quality management, *DISTILLERS

Abstract

Abstract: Scale formation in seawater distillers is mainly caused by crystallization of the inversely soluble salts calcium carbonate, magnesium hydroxide, and calcium sulphate. The formation of the alkaline scales CaCO3 and Mg(OH)2 strongly depends on temperature, pH, the release rate of CO2 as well as the concentrations of HCO3 −, CO3 2−, Ca2+, and Mg2+ ions. The release of CO2 from the evaporating brine shifts the pH to higher values and considerably influences the concentrations of HCO3 − and CO3 2− ions in the brine. Thus, it plays an important role in alkaline scale formation. Based on simulation results for the CO2 release and the carbonate system in a reference multiple-effect distiller, the scale forming potential was inferred from the composition of the brine by using the Langelier Saturation Index (LSI) and the Ryznar Stability Index (RSI). In the first stage of the reference distiller at a top brine temperature of 64 °C, the LSI based on the solubility product of aragonite increases from 1 on the first tube row to 1.5 on the last tube row. The RSI decreases from 5.9 on the first tube row to 5.0 on the last tube row. Thus it appears that the supersaturation with CaCO3 and the scale forming potential grow along the flow path of brine from the first to the last tube row. The LSI for the brine decreases from 1.5 at the outlet of the first stage to 1.3 at the outlet of the last stage. The RSI increases from 5.0 at the outlet of the first stage to 5.4 at the outlet of the last stage. Since the scaling tendency increases the more the Ryznar Stability Index falls below 6, scale formation is much more likely to occur in the high temperature stages. A larger quantity of scale is to be expected in the first stages on the lower tube rows. [Copyright &y& Elsevier]

Published

2005

50. The release of CO2 in MSF and ME distillers and its use for the recarbonation of the distillate: a comparison

Author

Glade, Heike, Meyer, Jan-Helge, and Will, Stefan

Subjects

*SALINE water conversion, *WATER purification, *WATER quality management, *DISTILLATION

Abstract

Abstract: The knowledge of the CO2 release from the evaporating brine in multi-stage flash (MSF) and multiple-effect (ME) distillers is very important for the design, the operation, and the cost of desalination distillers as well as for the recarbonation of the distillate. The CO2 released in MSF plants can be used for the recarbonation of the distillate. The recarbonation method using CO2 from the vent gases of MSF plants has gained importance, since the post-treatment of potable water can be effected without additional CO2 production by combustion processes. The paper discusses if this approach may also be applied to ME distillers. The amounts of CO2 required for the recarbonation are compared with the amounts released. To this end, the CO2 release rates were calculated on the basis of two previously developed models. One consequence of the differences between MSF and ME systems regarding evaporation mechanisms, fluid flow, operating temperatures, and concentrations is that in MSF distillers the specific phase interface areas are lower and the mass transfer coefficients are higher compared to ME distillers. Consequently, the specific CO2 release in MSF plants is significantly higher than in ME plants. The total CO2 release in MSF recycle distillers amounts to about 82 g CO2 per ton of distillate at a top brine temperature of 100°C. The calculations show that, for the limestone/carbon dioxide method, MSF recycle distillers produce sufficient CO2 to allow recarbonation of the distillate up to an alkalinity of 187 ppm as CaCO3 at a top brine temperature of 100°C. The total CO2 release in ME distillers amounts to about 55 g CO2 per ton of distillate at a top brine temperature of 64°C. Utilizing the CO2 for the limestone recarbonation process would result in an alkalinity in the distillate of 124 ppm as CaCO3. Provided that the alkalinity values aimed at in the distillate range from 50 to 80 ppm as CaCO3, the calculations suggest that the CO2 release in ME distillers may be just sufficient in terms of stoichiometric consumption to allow for recarbonation using the limestone method. [Copyright &y& Elsevier]

Published

2005