Decentralized Biogas Technology of Anaerobic Digestion and Farm Ecosystem: Opportunities and Challenges

Wang, Junye

doi:10.3389/fenrg.2014.00010

Cited by 68 publications

(30 citation statements)

References 60 publications

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“…Furthermore, there was a significant difference (P<0.05) in biomass yield of Zea mays plant concerning the concentration (%) and mode of application of the liquid digestate respectively. This suggests that the concentration and mode of application of the liquid digestate (as organic fertilizer) may have significantly influenced biomass yield of the crop with time [27,28,29,30,31,32,41]. It also suggests that the two-time mode of digestate application (TTDA) may have promoted the growth of the Zea mays plant better than the one-time digestate application (OTDA) treatment mode.…”

Section: Growth Dynamics Of Maize Plantmentioning

confidence: 99%

“…Moreover, the presence of macro and micro elements in most digestates make them excellent form of fertilizer when applied correctly [18,19,20,21,22,23,24,25]. In order to fully exploit biogas digestate in crop production, it is necessary to test its performance in the soil-plant ecosystem by investigating its effect on different soil types, plant growth and greenhouse gas (GHG) emission [26,27,28,29,30,31,32]. As organic farming prohibits the use of synthetic fertilizers on agricultural soils, digestate from anaerobic digestion of organic matter seem to offer a better alternative to these as well as undigested organic matter, which are sometimes used [24,33,34,35,36].…”

Section: Introductionmentioning

confidence: 99%

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Effect of Liquid Digestate on Agricultural Soil – I: Growth Dynamics of Zea mays Plant

Stanley

Ogbonna

Abu

et al. 2019

JEAI

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The study was designed to model the effect of liquid digestate on growth dynamics of Zea mays plant. Maize seeds were subjected to various concentrations of liquid digestate (between 0% and 72%) using One-Factor Response Design with a total of ten (10) runs in 10L-capacity plastic pots containing 10kg of loamy soil. One set of experimental runs were treated with one-time application of the corresponding digestate concentration (OTDA). Another set of experimental runs were treated with two-time application of the corresponding digestate concentration (TTDA). The first application of the liquid digestate (for OTDA and TTDA) was conducted two weeks after sowing while the second application (for TTDA alone) was conducted three weeks after the first application. The height of maize plant in all set-ups was monitored for a period of 70 days. After the 70-day period, the plants were harvested for biomass estimation. In the soil set-ups treated with OTDA, crop growth rate (1.077cm/day) and biomass yield (22.37g/kg of digestate) of Zea mays plant peaked Stanley et al.; JEAI, 31(5): 1-9, 2019; Article no.JEAI.42738 2 with 48% digestate after 70 days. In the soil set-ups treated TTDA, crop growth rate (1.321cm/day) and biomass yield (29.95g/kg) of Zea mays plant peaked with 72% digestate after the same period. Optimum response generated for the crop growth rate of Zea mays plant was approximately 1.038 cm/day with a standard error of 0.014 for the OTDA treatment and 1.165cm/day and a standard error of 0.006 for the TTDA treatment at digestate concentration of 50% with a desirability of 0.928 respectively. Optimum response generated for biomass yield of the Zea mays plant was approximately 22.488 (g/kg) with a standard error of 0.621 for the OTDA treatment and 27.292 (g/kg) with a standard error of 0.399 for the TTDA treatment at digestate concentration of approximately 47.1% and a desirability of 0.930 respectively. The result suggests that the TTDA treatment method may have enhanced the growth of the maize plant better than the OTDA treatment method. Original Research Article

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Section: Growth Dynamics Of Maize Plantmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effect of Liquid Digestate on Agricultural Soil – I: Growth Dynamics of Zea mays Plant

Stanley

Ogbonna

Abu

et al. 2019

JEAI

View full text Add to dashboard Cite

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“…Biogas offers a sustainable fuel to the environment as it contributes to low carbon emissions during its combustion. The raw biogas obtained from an anaerobic digester mainly consist of CH 4 with 40-45% CO 2 including a minor content of impurities, such as water, siloxanes, ammonia and hydrogen sulfide [1,2]. Great efforts have been made in the biogas separation and purification technologies to procure biomethane with a low energy footprint [3,4].…”

Section: Introductionmentioning

confidence: 99%

Freeze Granulated Zeolites X and A for Biogas Upgrading

Narang

Akhtar

2020

Molecules

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Biogas is a potential renewable energy resource that can reduce the current energy dependency on fossil fuels. The major limitation of utilizing biogas fully in the various applications is the presence of a significant volume fraction of carbon dioxide in biogas. Here, we used adsorption-driven CO2 separation using the most prominent adsorbents, NaX (faujasite) and CaA (Linde Type A) zeolites. The NaX and CaA zeolites were structured into hierarchically porous granules using a low-cost freeze granulation technique to achieve better mass transfer kinetics. The freeze granulation processing parameters and the rheological properties of suspensions were optimized to obtain homogenous granules of NaX and CaA zeolites 2–3 mm in diameter with macroporosity of 77.9% and 68.6%, respectively. The NaX and CaA granules kept their individual morphologies, crystallinities with a CO2 uptake of 5.8 mmol/g and 4 mmol/g, respectively. The CO2 separation performance and the kinetic behavior were estimated by breakthrough experiments, where the NaX zeolite showed a 16% higher CO2 uptake rate than CaA granules with a high mass transfer coefficient, 1.3 m/s, compared to commercial granules, suggesting that freeze-granulated zeolites could be used to improve adsorption kinetics and reduce cycle time for biogas upgrading in the adsorption swing technology.

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“…CR are largely at the lower end of the BMP spectrum because of high lignocellulose content. Lignocellulose limits degradation by anaerobic bacteria (Wang, 2014;Achinas, 2017). CR are heterogeneous in nature limiting their use as feedstock for AD (Horváth et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Comparison of pretreatment methods that enhance biomethane production from crop residues - a systematic review

et al. 2019

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Decentralized Biogas Technology of Anaerobic Digestion and Farm Ecosystem: Opportunities and Challenges

Cited by 68 publications

References 60 publications

Effect of Liquid Digestate on Agricultural Soil – I: Growth Dynamics of Zea mays Plant

Effect of Liquid Digestate on Agricultural Soil – I: Growth Dynamics of Zea mays Plant

Freeze Granulated Zeolites X and A for Biogas Upgrading

Comparison of pretreatment methods that enhance biomethane production from crop residues - a systematic review

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