Biohythane production from sugarcane bagasse and water hyacinth: A way towards promising green energy production

Kumari, Sinu; Das, Debabrata

doi:10.1016/j.jclepro.2018.10.050

Cited by 59 publications

(20 citation statements)

References 51 publications

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“…Seengenyoung et al investigated biohythane production from palm oil mill effluent by two‐stage thermophilic anaerobic fermentation and recorded a Biohythane production rate of 1.93 L‐gas/L.d with biogas consisting of 11% H 2 , 37% CO 2 , and 52% CH 4 , respectively (Seengenyoung, Mamimin, Prasertsan, & O‐Thong, 2018). Kumari and Das utilized a combination of sugarcane bagasse and water hyacinth for biohythane production and recorded maximum hydrogen and methane yield of 303 ml/g COD and 142 ml/g COD, respectively (Kumari & Das, 2019). The findings of these research studies emphasize the potentiality of FW as a future feedstock for the production of biohythane.…”

Section: Other Forms Of Bioenergy From Fwmentioning

confidence: 99%

Present scenario and future scope of food waste to biofuel production

Dhiman

Mukherjee

2020

J Food Process Engineering

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Food waste is the outcome of different food processing practices that have not been reused and are disposed of as waste. Food wastes are rich in a wide variety of organic constituents including starches, proteins, oils, fats, phosphates, nutrients, amino acids, and natural acids. Food waste is a zero‐value and nonconsumable resource. In this context, the valorization of food waste to different sorts of biofuels, for example, biodiesel, bioethanol, biohydrogen, bio‐oil, biochar, and biomethane by employing well‐structured and efficient valorization technologies can be an attractive and viable approach to counter the current global energy crisis and in establishing a sustainable bioeconomy. This type of food waste management not only resolves the serious pollution problem but also helps to reduce the dependency of the energy sector on fossil fuels. This review discusses the characteristics of food waste, common strategies for food waste management, food waste as a feedstock, biofuels as a renewable energy source, valorization of food waste to various types of biofuels, microbes‐assisted valorization of food waste, biofuels and bioeconomy, and future scope and challenges in the valorization of food waste to biofuels.

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Section: Other Forms Of Bioenergy From Fwmentioning

confidence: 99%

Present scenario and future scope of food waste to biofuel production

Dhiman

Mukherjee

2020

J Food Process Engineering

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“…Sequential hydrogen and methane fermentation of sugarcane bagasse hydrolysate obtained by steam explosion yielded a total energy of 304.11 kJ/L-substrate [78]. The gaseous (hydrogen and methane) recovery from mixed sugarcane bagasse hydrolysate and water hyacinth was maximized by continuous two-stage hydrogen and methane production at a hydraulic retention time of 8 h and 10 days, respectively, providing energy yield of 8.97 KJ/g-COD [98]. Continuous two-stage hydrogen and methane production from agave bagasse enzymatic hydrolysate was optimized at an organic loading rate of 44 g-COD/L-d (for hydrogen) and 20 g-COD/L-d (for methane), in which 9.22 kJ/g-bagasse was recovered [99].…”

Section: Methanementioning

confidence: 99%

Bio-hydrogen and Methane Production from Lignocellulosic Materials

Salakkam¹,

Plangklang²,

Sittijunda³

et al. 2019

Biomass for Bioenergy - Recent Trends and Future Challenges

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“…Structurally, SCB consists of cellulose (45–55%), hemicellulose (20–25%), and lignin (18–24%) [ 4 ]. Recently, SCB was found to be an impeccable source material for many applications [ 5 , 6 , 7 ]. However, its use as a scaffold in tissue engineering is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Supermagnetic Sugarcane Bagasse Hydrochar for Enhanced Osteoconduction in Human Adipose Tissue-Derived Mesenchymal Stem Cells

et al. 2020

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Hydrothermally carbonized sugarcane bagasse (SCB) has exceptional surface properties. Looking at the huge amount of SCB produced, its biocompatible nature, cheap-cost for carbonization, and its easy functionalization can give impeccable nano-biomaterials for tissue engineering applications. Herein, sugarcane bagasse was converted into hydrochar (SCB-H) by hydrothermal carbonation. The SCB-H produced was further modified with iron oxide (Fe3O4) nanoparticles (denoted as SCB-H@Fe3O4). Facile synthesized nano-bio-composites were characterized by SEM, HR-TEM, XRD, FT-IR, XPS, TGA, and VSM analysis. Bare Fe3O4 nanoparticles (NPs), SCB-H, and SCB-H@Fe3O4 were tested for cytocompatibility and osteoconduction enhancement of human adipose tissue-derived mesenchymal stem cells (hADMSCs). The results confirmed the cytocompatible and nontoxic nature of SCB-H@Fe3O4. SCB-H did not show enhancement in osteoconduction, whilst on the other hand, Fe3O4 NPs exhibited a 0.5-fold increase in the osteoconduction of hADMSCs. However, SCB-H@Fe3O4 demonstrated an excellent enhancement in osteoconduction of a 3-fold increase over the control, and a 2.5-fold increase over the bare Fe3O4 NPs. Correspondingly, the expression patterns assessment of osteoconduction marker genes (ALP, OCN, and RUNX2) confirmed the osteoconductive enhancement by SCB-H@Fe3O4. In the proposed mechanism, the surface of SCB-H@Fe3O4 might provide a unique topology, and anchoring to receptors of hADMSCs leads to accelerated osteogenesis. In conclusion, agriculture waste-derived sustainable materials like “SCB-H@Fe3O44” can be potentially applied in highly valued medicinal applications of stem cell differentiation.

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Biohythane production from sugarcane bagasse and water hyacinth: A way towards promising green energy production

Cited by 59 publications

References 51 publications

Present scenario and future scope of food waste to biofuel production

Present scenario and future scope of food waste to biofuel production

Bio-hydrogen and Methane Production from Lignocellulosic Materials

Supermagnetic Sugarcane Bagasse Hydrochar for Enhanced Osteoconduction in Human Adipose Tissue-Derived Mesenchymal Stem Cells

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