- Văn bản
- Lịch sử
Kinetics of nano-catalysed dark fer
Kinetics of nano-catalysed dark fermentative biohydrogen production from molasses-based distillery wastewater has been
reported. Iron oxide nanoparticle was supplemented (10-200 mgL-1) to the wastewater to enhance the biohydrogen production.
Andrew’s inhibition model was employed to evaluate the rate of hydrogen production (RH2) and hydrogen yield at different
concentration of iron oxide nanoparticles. The maximum RH2 and specific hydrogen yield (SHY) for the fermentative hydrogen
production system at different concentration of iron oxide nanoparticle were found to be 80.7ml/hr and 44.28ml H2/g COD.
Michaelis-Menton equation was applied to determine the rate of hydrogen production (RH2) and yield of H2 (SHY) at different
initial pH (5, 6 & 7). Andrew’s inhibition model has been used to describe the inhibitory effect of substrate concentration on the
rate of H2 production (RH2). RH2 decreased with the increase in substrate concentration but SHY first decreased with substrate
concentration and it is maximum at higher substrate concentration of 110 gL-1. Monod model has been used to determine the
growth kinetic parameters. The values of maximum rates of microbial growth (μm) and substrate utilization (Rsu) were 0.1 g
biomass/g biomass/day and 14.03 g COD/g biomass/day respectively at different iron oxide nanoparticles concentration
reported. Iron oxide nanoparticle was supplemented (10-200 mgL-1) to the wastewater to enhance the biohydrogen production.
Andrew’s inhibition model was employed to evaluate the rate of hydrogen production (RH2) and hydrogen yield at different
concentration of iron oxide nanoparticles. The maximum RH2 and specific hydrogen yield (SHY) for the fermentative hydrogen
production system at different concentration of iron oxide nanoparticle were found to be 80.7ml/hr and 44.28ml H2/g COD.
Michaelis-Menton equation was applied to determine the rate of hydrogen production (RH2) and yield of H2 (SHY) at different
initial pH (5, 6 & 7). Andrew’s inhibition model has been used to describe the inhibitory effect of substrate concentration on the
rate of H2 production (RH2). RH2 decreased with the increase in substrate concentration but SHY first decreased with substrate
concentration and it is maximum at higher substrate concentration of 110 gL-1. Monod model has been used to determine the
growth kinetic parameters. The values of maximum rates of microbial growth (μm) and substrate utilization (Rsu) were 0.1 g
biomass/g biomass/day and 14.03 g COD/g biomass/day respectively at different iron oxide nanoparticles concentration
0/5000
Kinetics of nano-catalysed dark fermentative biohydrogen production from molasses-based distillery wastewater has beenreported. Iron oxide nanoparticle was supplemented (10-200 mgL-1) to the wastewater to enhance the biohydrogen production.Andrew’s inhibition model was employed to evaluate the rate of hydrogen production (RH2) and hydrogen yield at differentconcentration of iron oxide nanoparticles. The maximum RH2 and specific hydrogen yield (SHY) for the fermentative hydrogenproduction system at different concentration of iron oxide nanoparticle were found to be 80.7ml/hr and 44.28ml H2/g COD.Michaelis-Menton equation was applied to determine the rate of hydrogen production (RH2) and yield of H2 (SHY) at differentinitial pH (5, 6 & 7). Andrew’s inhibition model has been used to describe the inhibitory effect of substrate concentration on therate of H2 production (RH2). RH2 decreased with the increase in substrate concentration but SHY first decreased with substrateconcentration and it is maximum at higher substrate concentration of 110 gL-1. Monod model has been used to determine thegrowth kinetic parameters. The values of maximum rates of microbial growth (μm) and substrate utilization (Rsu) were 0.1 gbiomass/g biomass/day and 14.03 g COD/g biomass/day respectively at different iron oxide nanoparticles concentration
đang được dịch, vui lòng đợi..
Các ngôn ngữ khác
Hỗ trợ công cụ dịch thuật: Albania, Amharic, Anh, Armenia, Azerbaijan, Ba Lan, Ba Tư, Bantu, Basque, Belarus, Bengal, Bosnia, Bulgaria, Bồ Đào Nha, Catalan, Cebuano, Chichewa, Corsi, Creole (Haiti), Croatia, Do Thái, Estonia, Filipino, Frisia, Gael Scotland, Galicia, George, Gujarat, Hausa, Hawaii, Hindi, Hmong, Hungary, Hy Lạp, Hà Lan, Hà Lan (Nam Phi), Hàn, Iceland, Igbo, Ireland, Java, Kannada, Kazakh, Khmer, Kinyarwanda, Klingon, Kurd, Kyrgyz, Latinh, Latvia, Litva, Luxembourg, Lào, Macedonia, Malagasy, Malayalam, Malta, Maori, Marathi, Myanmar, Mã Lai, Mông Cổ, Na Uy, Nepal, Nga, Nhật, Odia (Oriya), Pashto, Pháp, Phát hiện ngôn ngữ, Phần Lan, Punjab, Quốc tế ngữ, Rumani, Samoa, Serbia, Sesotho, Shona, Sindhi, Sinhala, Slovak, Slovenia, Somali, Sunda, Swahili, Séc, Tajik, Tamil, Tatar, Telugu, Thái, Thổ Nhĩ Kỳ, Thụy Điển, Tiếng Indonesia, Tiếng Ý, Trung, Trung (Phồn thể), Turkmen, Tây Ban Nha, Ukraina, Urdu, Uyghur, Uzbek, Việt, Xứ Wales, Yiddish, Yoruba, Zulu, Đan Mạch, Đức, Ả Rập, dịch ngôn ngữ.
- Tôi không biết tôi sẽ cố được bao lâu nữ
- Examples: Sweden and USA Multiple Buildi
- Đây là chức năng đầu tiên và cũng là cơ
- What are you going to do today
- 私はいつもこの場所を覚えているだろう
- nhưng tôi sợ gặp hải quan
- Có thể với thế giới, bạn chỉ là một ngườ
- Why you like it
- Có thể với thế giới, bạn chỉ là một ngườ
- Cloning and sequencingof rDNA amplicons
- Có thể với thế giới, bạn chỉ là một ngườ
- Cloning and sequencingof rDNA amplicons
- Bộ trưởng Bộ Ngoại giao
- How often you go shopping
- Tôi không biết tôi sẽ chịu đựng được bao
- Nói về chức năng định hướng, còn một khí
- good thing you no come on 8 May
- Who you often goes with
- ai đến nhà sớm nhất?
- kiểm toán viên nhận định yếu tố
- Example: Brazil Industrial ProcessesInd
- Tôi không biết tôi sẽ chịu được bao lâu
- Tôi ở khách sạn cùng bạn
- Tôi không biết tôi sẽ cố được bao lâu nữ
