Page 350 - Advances in Eco-Fuels for a Sustainable Environment

P. 350

Thermal depolymerization of biogas digestate 305

[8] Camilleri-Rumbau MS, Norddahl B, Wei J, Christensen KV, Søtoft LF. Microfiltration
and ultrafiltration as a post-treatment of biogas plant digestates for producing concentrated
fertilizers. Desalin Water Treat 2014;55(6):1639–53.
[9] Golkowska K, Va ´zquez-Rowe I, Lebuf V, Accoe F, Koster D. Assessing the treatment
costs and the fertilizing value of the output products in digestate treatment systems. Water
Sci Technol 2014;69(3):656–62.
[10] Young D, Scharp R, Cabezas H. The waste reduction (WAR) algorithm: environmental
impacts, energy consumption, and engineering economics. Waste Manag 2000;20:605–15.
[11] Jones S, Zhu Y, Anderson D, Hallen R, Elliot D, Schmidt A, et al. Process design and
economics for the conversion of algal biomass to hydrocarbons: whole algae hydrothermal
liquefaction and upgrading. Springfield; 2014.
[12] Anouti S, Haarlemmer G, D eniel M, Roubaud A. Analys physicochemical properties of
bio-oil from hydrothermal liquefaction of blackcurrant pomace. Energy Fuel
2016;30:398–406.
[13] Maddi B, Panisko E, Wietsma T, Lemmon T, Swita M, Albrecht K. Quantitative charac-
terization of aqueous byproducts from hydrothermal liquefaction of municipal wastes,
food industry wastes, and biomass grown on waste. ACS Sustain Chem Eng
2017;5:2205–14.
[14] Lewis AJ, Ren S, Ye X, Kim P, Labbe N, Borole AP. Hydrogen production from switch-
grass via an integrated pyrolysis-microbial electrolysis process. Bioresour Technol
2015;195:231–41.
[15] Zeng X, Borole AP, Pavlostathis SG. Biotransformation of furanic and phenolic com-
pounds with hydrogen gas production in a microbial electrolysis cell. Environ Sci Technol
2015;49(22):13667–75.
[16] Biller P, Ross AB. Hydrothermal processing of algal biomass for the production of
biofuels and chemicals. Biofuels 2012;3(5):603–23.
[17] Ramos-Tercero EA, Bertucco A, Wim Brilman DWF. Process water recycle in hydrother-
mal liquefaction of microalgae to enhance bio-oil yield. Energy Fuel 2015;29(4):2422–30.
[18] Huang H, Yuan X, Wu G. Liquefaction of biomass for bio-oil products. In: Waste biomass
management—a holistic approach. Switzerland: Springer; 2017. p. 231–51.
[19] Mørup AJ, Becker J, Christensen PR, Houlberg K, Lappa E, Klemmer M, et al. Construc-
tion and commisioning of a continuous reactor for hydrothermal liquefaction. Ind Eng
Chem Res 2015;54(22):5935–47.
[20] Anderson-Glenna M, Morken J. Greenhouse gas emissions from on-farm digestate storage
facilities. Porsgrunn: Tel-Tek; 2013.
[21] Goreau TJ, Kaplan WA, Wofsy SC, Mcelroy MB, Valois FW, Watson SW. Production of
NO 2 - and N 2 O by nitrifying bacteria at reduced concentrations of oxygen. Appl Environ
Microbiol 1980;40(3):526–32.
[22] Watanabe W, Bayer F, Kruse A. Oil formation from glucose with formic acid and cobalt
catalyst in hot-compressed water. Carbohydr Res 2006;341:2891–900.
[23] Nan W, Shende A, Shannon J, Shende R. Insight into catalytic hydrothermal liquefaction
of cardboard for biofuels production. Energy Fuel 2016;30:4933–44.
[24] USEPA. Understanding global warming potentials. Washington: USEPA; 2017.
ˇ ˇ
[25] Pavlovic ˇ I, Knez Z,Skerget M. Hydrothermal reactions of agricultural and food processing
waste in sub and supercritical water. A review of the fundamentals, mechanisms and the
state of research. J Agric Food Chem 2013;61:8003–25.
[26] Elliott CD, Biller P, Ross AB, Schmidt AJ, Jones SB. Hydrothermal liquefaction of
biomass: developments from batch to continuous process. Bioresour Technol
2015;178:147–56.

345 346 347 348 349 350 351 352 353 354 355