More Like this

1. Recycling food waste to agriculture through hydrothermal carbonization sustains food-energy-water nexus

   Hao, Xu; Tong, Chen; Yide, Shan; Kang, Chen; Ning, Ling; Lixuan, Ren; Hongye, Qu; Nicole, Berge; Joseph, Flora; Ramesh, Goel; et al (July 2024, Chemical engineering journal)

   Recycling underutilized resources from food waste (FW) to agriculture through hydrothermal carbonization (HTC) has been proposed to promote a circular economy (CE) in food-energy-water (FEW) nexus. However, most HTC studies on FW were conducted at laboratory scale, and little is known on the efficacy and feasibility of field application of HTC products from FW, i.e. the aqueous phrase (AP) and solid hydrochar (HC), to support agriculture production. An integrated pilot-scale HTC system was established to investigate practical HTC reaction conditions treating FW. A peak temperature of 180 ◦C at a residence time of 60 min with 3 times AP recirculation were recommended as optimal HTC conditions to achieve efficient recovery of nutrients, and desirable AP and HC properties for agriculture application. Dilution of the raw AP and composting of the fresh HC are necessary as post-treatments to eliminate potential phytotoxicity. Applying properly diluted AP and the composted HC significantly improved plant growth and nutrient availability in both greenhouse and field trials, which were comparable to commercial chemical fertilizer and soil amendment. The HTC of FW followed with agricultural application of the products yielded net negative carbon emission of 􀀀 0.28 t CO2e t􀀀 1, which was much lower than the other alternatives of FW treatments. Economic profit could be potentially achieved by valorization of the AP as liquid fertilizer and HC as soil amendment. Our study provides solid evidences demonstrating the technical and economic feasibility of recycling FW to agriculture through HTC as a promising CE strategy to sustain the FEW nexus. 

   more » « less
2. Potential for improving nutrient use efficiencies of human food systems with a circular economy of organic wastes and fertilizer

   https://doi.org/10.1088/1748-9326/ad6617  

   Davis, Sarah_C; Maynard, Finn_G; Jenkins, David; Herman, Tess; Reza, M_Toufiq (August 2024, Environmental Research Letters)

   Abstract Waste from the human food system includes a large quantity of nutrients that pose environmental and human health risks. If these nutrients can be captured and repurposed, they could potentially offset synthetic fertilizer demands. This study reviews several technologies—including anaerobic digestion, hydrothermal carbonization (HTC), and composting—that can be used to process wastes from the human food system. This study also assesses the quantity of nutrient resources that are available from wastes, including food waste, biosolids, manure, and yard waste. Three geographic scales were analyzed. At a national level in the United States, up to 27% of nitrogen and 33% of phosphorus demands for agriculture could be met with wastes from the human food system, primarily from food waste and biosolids. Some rural localities have a greater potential for circular economies of nutrients in the food system, with the potential to meet 100% of nitrogen and phosphorus fertilizer demands using waste nutrients, as in the case of Athens County, Ohio. Benefits of offsetting synthetic fertilizer use with waste nutrients include reduced greenhouse gas (GHG) emissions, with up to 64% reduction in GHG emissions per unit of nitrogen fertilizer produced with HTC. 

   more » « less
3. Comparative Fuel Yield from Anaerobic Digestion of Emerging Waste in Food and Brewery Systems

   https://doi.org/10.3390/en15041538  

   Herman, Tess; Nungesser, Emily; Miller, Kimberley E.; Davis, Sarah C. (February 2022, Energies)

   Food waste (FW), a major part of the US waste stream, causes greenhouse gases within landfills, but there is an opportunity to divert FW to anaerobic digestion (AD) facilities that produce biogas and digestate fertilizer. The composition of FW inputs to AD determines the value of these products. This study provides insight into the effect of waste composition on the quality of AD products by first characterizing the biogas and digestate quality of anaerobically digested FW from four diets (paleolithic, ketogenic, vegetarian, and omnivorous), and then estimating the difference in biogas produced from codigested FW and brewery waste (BW). Waste feedstock mixtures were incubated in lab-scale bioreactors for 21 days with live inoculum. Biogas quality was monitored for 21–30 days in four trials. Samples were analyzed using a gas chromatograph for detection of methane (CH4) and carbon dioxide (CO2). The composition of the waste inputs had a significant impact on the quality of biogas but not on the quality of the digestate, which has implications for the value of post-AD fertilizer products. Wastes with higher proportions of proteins and fats enhanced biogas quality, unlike wastes that were rich in soluble carbohydrates. Codigestion of omnivorous food waste with carbon-rich agricultural wastes (AW) improved biogas quality, but biogas produced from BW does not necessarily improve with increasing amounts of AW in codigestion. 

   more » « less
4. Zero food waste city 2049: Identifying barriers to transition pathways

   https://doi.org/10.56367/OAG-038-10465  

   Black, Daniel; Roderick, Ian; Paytan, Adina; Charlesworth, Sue; Carey, Joy (January 2023, Open Access Government)

   Zero food waste city 2049: Identifying barriers to transition pathways Daniel Black, Ian Roderick, Adina Paytan, Sue Charlesworth and Joy Carey from an Urban Living Lab in the UK have tested newly integrated systems approaches and valuation methods to understand how to reduce the city's food waste. Food waste costs the UK billions of pounds each year and much of it is avoidable. The challenge for the WASTE FEW ULL research project was to produce and test methods for identifying inefficiencies in the food-energy-water (FEW) nexus in urban settings. Looking in particular at Bristol city, which throws away 48,000 tonnes of food waste each year, the team looked into how they could transform Bristol into a sustainable food city. Stakeholder concerns arose including the nutrient overload problem in water systems and the economic recovery of phosphate; the large amount of food waste from the city linked to food security issues; the energy and carbon footprint of the digestate produced from the anaerobic digestors; the economic challenges of reducing food waste; the plastic contamination of waste streams; sewage system blockages; and the difficulties of recycling sewage and wastewater. This research looks at the challenge of phosphorous recapture from sewage through extensive discussions agreed to shift the project focus to residential food waste reduction and processing (and the associated plastic contamination). The team eventually began looking at the critical concept of resilience and economic efficiency, working to substantially reduce inefficiencies in a city-regions FEW nexuses. 

   more » « less
5. Heat and Mass Transfer in the Food, Energy, and Water Nexus—A Review

   https://doi.org/10.1115/1.4047089  

   Derby, Melanie M.; Adams, Allison N.; Chakraborty, Partha P.; Haque, Mohammad Rejaul; Huber, Ryan A.; Morrow, Jordan A.; Riley, Gennifer A.; Ross, Molly; Stallbaumer, Emily M.; Betz, Amy R.; et al (September 2020, Journal of Heat Transfer)

   Abstract Engineering innovations—including those in heat and mass transfer—are needed to provide food, water, and power to a growing population (i.e., projected to be 9.8 × 109 by 2050) with limited resources. The interweaving of these resources is embodied in the food, energy, and water (FEW) nexus. This review paper focuses on heat and mass transfer applications which involve at least two aspects of the FEW nexus. Energy and water topics include energy extraction of natural gas hydrates and shale gas; power production (e.g., nuclear and solar); power plant cooling (e.g., wet, dry, and hybrid cooling); water desalination and purification; and building energy/water use, including heating, ventilation, air conditioning, and refrigeration technology. Subsequently, this review considers agricultural thermal fluids applications, such as the food and water nexus (e.g., evapotranspiration and evaporation) and the FEW nexus (e.g., greenhouses and food storage, including granaries and freezing/drying). As part of this review, over 100 review papers on thermal and fluid topics relevant to the FEW nexus were tabulated and over 350 research journal articles were discussed. Each section discusses previous research and highlights future opportunities regarding heat and mass transfer research. Several cross-cutting themes emerged from the literature and represent future directions for thermal fluids research: the need for fundamental, thermal fluids knowledge; scaling up from the laboratory to large-scale, integrated systems; increasing economic viability; and increasing efficiency when utilizing resources, especially using waste products. 

   more » « less