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Abstract Waste plastic presently accumulates in landfills or the environment. While natural microbial metabolisms can degrade plastic polymers, biodegradation of plastic is very slow. This study demonstrates that chemical deconstruction of polyethylene terephthalate (PET) with ammonium hydroxide can replace the rate limiting step (depolymerization) and by producing plastic-derived terephthalic acid and terephthalic acid monoamide. The deconstructed PET (DCPET) is neutralized with phosphoric acid prior to bioprocessing, resulting in a product containing biologically accessible nitrogen and phosphorus from the process reactants. Three microbial consortia obtained from compost and sediment degraded DCPET in ultrapure water and scavenged river water without addition ofmore » nutrients. No statistically significant difference was observed in growth rate compared to communities grown on DCPET in minimal culture medium. The consortia were dominated by Rhodococcus spp., Hydrogenophaga spp., and many lower abundance genera. All taxa were related to species known to degrade aromatic compounds. Microbial consortia are known to confer flexibility in processing diverse substrates. To highlight this, we also demonstrate that two microbial consortia can grow on similarly deconstructed polyesters, polyamides, and polyurethanes in water instead of medium. Our findings suggest that microbial communities may enable flexible bioprocessing of mixed plastic wastes when coupled with chemical deconstruction.« less

The program reads a near infrared reflectance (NIR) spectrum from an item of plastic waste, and identifies the type of plastic using an AI model. The spectra and results are displayed to the operator, and recorded in a database.

Early reports coming from stover-fed biorefineries have indicated that the feedstock is damaging equipment due to wear caused by the feedstock. It is suspected that biomass ash, both physiological and introduced ash, is responsible for the accelerated rates of wear being observed. Biomass ash can contain several different types of minerals, some of which are very hard. To simulate biomass wear on material handling equipment, a sandblaster was modified to shoot ground biomass at a metal coupon. The angle of impingement was set at 90°, 65.5°, or 45° by rotating the coupon. The coupon was weighed before and after shootingmore » a known quantity of biomass to determine mass loss, and the surface characteristics of the blasted coupon were analyzed using laser microscopy. Coupon mass loss was positively correlated with ash content. Coupons blasted with loblolly pine (0.58% ash) lost 2.2mg±0.3mg per kg biomass shot, while high-ash stover (12.56% ash) coupons lost 104.7±2.1mg per kg biomass shot. Coupons blasted with NaOH leached low-ash stover (4.01% ash) lost 10.1±2.7mg per kg biomass shot. Decreasing the angle of impingement (90° to 45°) increased mass loss by about 17%. The concentrations of soil elements (silicon, aluminum, iron, titanium, sodium) were positively correlated with coupon mass loss, indicating that introduced ash is likely the primary source of wear to equipment. Future studies will identify mineral forms of ash present in biomass to further characterize biomass wear properties and to identify strategies to improve biomass quality.« less

Not all biomass is created equal, and the low quality of many sources of biomass precludes their use in many conversion processes. As we work to achieve the Billion Ton vision, more of these low quality biomass sources will need to be integrated into the feedstock supply chain and their quality issues must be dealt with to make them usable. Many of these feedstocks suffer from elevated concentrations of ash, which can interfere with thermochemical conversion reactions, catalysts, and conversion products. In this study, the cost of incremental reductions in ash concentrations was investigated in three potential biomass feedstocks: loggingmore » residues, corn stover, and construction and demolition waste. Air classification (AC) is a mechanical separations method that has been shown to concentrate ash into the lighter fractions, and ash content can be decreased by discarding these fractions. However, the cost of disposal and replacement of the discarded fraction make this strategy unaffordable (= $11.04 ton-1). Alternatively, the lightest AC fraction can be acid-leached to remove ash and recombined with the remainder of the sample. Using this approach, ash content can be decreased in logging residues from 1.1% to 0.83% for $1.95 ton-1. Ash concentrations could be further decreased with the combined strategy to 0.67% (a 40% reduction) for $3.88 per ton. This approach costs between $0.07 and $0.10 percent-1 ton-1 for the removal of up to 40% of the ash in the feedstock. This separate-treat-recombine method is an effective way to introduce lower quality feedstocks into the biomass feedstock supply chain.« less

There is growing interest internationally to produce fuels from renewable biomass resources. Inorganic components of biomass feedstocks, referred to collectively as ash, damage equipment and decrease yields in thermal conversion processes, and decrease feedstock value for biochemical conversion processes. Decreasing the ash content of feedstocks improves conversion efficiency and lowers process costs. Because physiological ash is unevenly distributed in the plant, mechanical processes can be used to separate fractions of the plant based on ash content. This study focuses on the ash separation that can be achieved by separating corn stover by particle size and anatomical fraction. Baled corn stovermore » was hand-separated into anatomical fractions, ground to <19.1 mm, and size separated using six sieves ranging from 9.5 to 0.150 mm. Size fractions were analyzed for total ash content and ash composition. Particle size distributions observed for the anatomical fractions varied considerably. Cob particles were primarily 2.0 mm or greater, while most of the sheath and husk particles were 2.0 mm and smaller. Particles of leaves greater than 0.6 mm contained the greatest amount of total ash, ranging from approximately 8 to 13% dry weight of the total original material, while the fractions with particles smaller than 0.6 mm contained less than 2% of the total ash of the original material. As a result, based on the overall ash content and the elemental ash, specific anatomical and size fractions can be separated to optimize the feedstocks being delivered to biofuels conversion processes and minimize the need for more expensive ash reduction treatments.« less