Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Dahunsi, S. O.; Oranusi, S. U.; Efeovbokhan, Vincent Enon

doi:10.1016/j.jclepro.2017.04.042

Cited by 69 publications

(26 citation statements)

References 58 publications

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“…This has made the hydrolysis process rate-limiting thereby requiring prior biomass pretreatment for easy digestion in the digester [20,21]. Pretreatment helps in changing the complex chemical structure of the lignocellulose causing quick hydrolysis and higher rate of digestion [22]. There are many pretreatment methods that have been applied to diverse lignocellulosic biomass over time.…”

Section: Introductionmentioning

confidence: 99%

Liquefaction of pineapple peel: Pretreatment and process optimization

Dahunsi

2019

Energy

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a b s t r a c tThis study explored the optimization of pretreatment of pineapple peel for biogas generation. Pretreatments were carried out sulfuric acid and alkaline hydrogen peroxide prior to anaerobic digestion while the response surface methodology (RSM) was used for optimization of the pretreatment procedures. The physical, chemical, proximate and structural compositions of the peels were determined prior to and at the end of the pretreatment procedures. The dynamics of microorganisms in the reactors were also evaluated by rapid molecular methods while the Fourier Transform Infra-red (FTIR) spectroscopy was employed in the identification of the chemical changes as a result of pretreatments. The use of H 2 O 2 pretreatment caused enormous lignin solubilization in the pineapple peel. In comparison, biogas production was 67% more in the alkaline pretreated pineapple peel than the biomass treated with acid and also 51% over the untreated samples. The total biogas volume produced from the acidic pretreated, alkaline pretreated, not sifted untreated and sifted untreated samples are 194.2 ± 3.0, 587.5 ± 5.2, 287.8 ± 2.1 and 245.4 ± 3.1 respectively. Thus, the alkaline pretreated experiment used lower retention time to achieve maximum gas production in this study. The use of alkaline H 2 O 2 on lignocelluloses has remained unpopular prior to this study. However, its usage in this study yielded better result than all the conventional treatments in terms of lignin solubilization and improvement in methane yield. Economically, the use of H 2 O 2 for pretreatment is adjudged feasible because the 1504 kWh t À1 TS thermal energy gain obtained from the biogas produced by the alkaline treated peel exceeded the 921 kWh t À1 TS used in the pretreatment. This gives a net thermal energy of 583 kWh t À1 TS. Whereas, the investment into acidic pretreatment of pineapple peel may not be economically justified because the total thermal energy gain of À200 kWh t À1 TS was far lower than the 1236 kWh t À1 TS thermal energy that was consumed during the pretreatment giving a net thermal energy of À1436 kWh t À1 TS. Therefore, the use of mild alkaline pretreatment is advocated in biogas generation from pineapple peel and also for biofertilizer production mostly in localities of mass production.

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Section: Introductionmentioning

confidence: 99%

Liquefaction of pineapple peel: Pretreatment and process optimization

Dahunsi

2019

Energy

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“…They include shoots of Tithonia diversifolia (Mexican sunflower), and Chromolaena odorata (Siam weed). Others are fruit peels of Carica papaya (pawpaw), Telfairia occidentalis (fluted pumpkin), Ananas comosus (pineapple), Citrullus lanatus (water melon), Cucumeropsis mannii (melon) and the hull or pod of Arachis hypogaea (peanut or groundnut), Theobroma cacao (Cocoa) and Kola nitida (kolanut) [14,[65][66][67][68][69][70][71][72]. Despite the huge availability of these biomasses in their various locations of production, they mostly end up as solid wastes in the environment as little or no usage has been sought for them over the years.…”

Section: Suitable Feedstock For Biogas Generation In Sub-saharan Africamentioning

confidence: 99%

Biofuel Development in Sub-Saharan Africa

Dahunsi¹,

Shoyombo²,

Fagbiele³

2019

Anaerobic Digestion

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The quest for renewable and sustainable energy generation is fast becoming widespread across Africa due to the understanding that there is a need to seek an alternative to fuels of fossil origin, which currently sustains the largest portion of the world's energy need. Research into the generation of renewable fuels had been on-going in continents like Europe, South America, Asia, and other developed countries bearing in mind the extinction nature of fossil fuels. Globally, attentions are being drawn to fuel generation from biomass and its derivatives such as lignin, triglycerides, cellulose, and hemicelluloses. The aim is to use such fuels for cooking and heating and in vehicles, jet engines, and other applications. Therefore, the integration of the African continent in the race for biofuel production is germane in the quest for survival and developments considering favorable factors like climate, soil, and land mass among other environmental-friendly resources in different African countries.

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“…In ancient times, natural dyes were applied to the dyeing of fabrics. Since the middle of the nineteenth century, with the development of the chemical industry, synthetic dyes with convenient large‐scale production, wide chromatographic spectra and low prices have gradually occupied the dye market , and are widely used in the textiles, paper, leather, food and other industries . In recent years, some synthetic dyes have been banned because of the carcinogenic effects of synthesis precursors or products on the human body .…”

Section: Introductionmentioning

confidence: 99%

Yellow pigment of Metarhizium anisopliae and its application to the dyeing of fabrics

Yan

Yang

Zhou

et al. 2019

Coloration Technology

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Microbial dyes have received substantial attention because of their natural environmental protection, simple access, and reduced regional and seasonal restriction. In this work, a microbial dye, the yellow pigment produced by Metarhizium anisopliae, was first studied then applied. The strain produced by the culture was identified, and the conditions for producing yellow pigment were optimised. Further, the stability of M. anisopliae yellow pigment was examined, and the pigment was applied to the dyeing of silk and wool fabrics. The results showed that the homology of the strain with M. anisopliae was 99.98%. In liquid fermentation culture, the optimal carbon source was glucose, and the dosage was 30 g/l. The maximum pigment yield can be obtained by culturing with 4% v/v of inoculation quantity at pH 7 and 30 °C. In addition, the effects of pH, temperature and metal ions on the yellow pigment of M. anisopliae were significant. The optimum dyeing process conditions were dyeing temperatures of 80 °C for silk and 90 °C for wool, with a dyeing time of 60 min. This research developed a novel microbial dye and studied its application for the dyeing of protein fibres.

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Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Cited by 69 publications

References 58 publications

Liquefaction of pineapple peel: Pretreatment and process optimization

Liquefaction of pineapple peel: Pretreatment and process optimization

Biofuel Development in Sub-Saharan Africa

Yellow pigment of Metarhizium anisopliae and its application to the dyeing of fabrics

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