Rigid and film bioplastics degradation under suboptimal composting conditions: A kinetic study.

The present research investigates the degradation rate of bioplastics under various composting conditions, including suboptimal ones. Lab-scale tests were carried out setting three variables: temperature (37°C-58°C), humidity (30%-60%) and duration of the thermophilic and the maturation phases (15-60 days). The composting tests were carried out following modified guideline ISO 20200:2015 and lasted for 60 days. Bioplastics in the synthetic waste matrix consisted of Mater-Bi® film biobags and PLA rigid teaspoons. A kinetic study was performed, resulting in faster degradation rates for film bioplastics (first-order kinetics with k = 0.0850-0.1663 d-1) than for rigid (0.0018-0.0136 d-1). Moreover, film bioplastics reached a complete degradation within the 60 days of the test. Concerning the rigid products, 90% degradation would be achieved in 2-3 years for mesophilic conditions. Finally, in the undersieve of 0.5 mm some microplastics were identified with the ImageJ software, mainly relatable to rigid (PLA) bioplastics. Overall, the results disclosed that the combination of mesophilic temperatures and absence of moistening slowed down both the degradation and the disintegration process of bioplastics.

A highly efficient multi-step methodology for the quantification of micro-(bio)plastics in sludge.

The present study develops a multi-step methodology for identification and quantification of microplastics and micro-bioplastics (together called in the current work micro-(bio)plastics) in sludge. In previous studies, different methods for the extraction of microplastics were devised for traditional plastics, while the current research tested the methodology on starch-based micro-bioplastics of 0.1-2 mm size. Compostable bioplastics are expected to enter the anaerobic or aerobic biological treatments that lead to end-products applicable in agriculture; some critical conditions of treatments (e.g. low temperature and moisture) can slow down the degradation process and be responsible for the presence of microplastics in the end-product. The methodology consists of an initial oxidation step, with hydrogen peroxide 35% concentrated to clear the sludge and remove the organic fraction, followed by a combination of flotation with sodium chloride and observation of the residues under a fluorescence microscope using a green filter. The workflow revealed an efficacy of removal from 94% to 100% and from 92% to 96% for plastic fragments, 0.5-2 mm and 0.1-0.5 mm size, respectively. The methodology was then applied to samples of food waste pulp harvested after a shredding pre-treatment in an anaerobic digestion (AD) plant in Italy, where polyethylene, starch-based Mater-Bi® and cellophane microplastics were recovered in amounts of 9 ± 1.3/10 g <2 mm and 4.8 ± 1.2/10 g ⩾2 mm. The study highlights the need to lower the threshold size for the quantification of plastics in organic fertilizers, which is currently set by legislations at 2 mm, by improving the background knowledge about the fate of the micro-(bio)plastics in biological treatments for the organic waste.

Methodologies to assess biodegradation of bioplastics during aerobic composting and anaerobic digestion: A review.

Bioplastics are emerging on the market as sustainable materials which rise to the challenge to improve the lifecycle of plastics from the perspective of the circular economy. The article aims at providing a critical insight of research studies carried out in the last 20 years on the degradation of bioplastics under aerobic composting and anaerobic digestion conditions. It mainly focuses on the various and different methodologies which have been proposed and developed to monitor the process of biodegradation of several bioplastic materials: CO2 and CH4 measurements, mass loss and disintegration degree, spectroscopy, visual analysis and scanning electron microscopy. Moreover, across the wide range of studies, the process conditions of the experimental setup, such as temperature, test duration and waste composition, often vary from author to author and in accordance with the international standard followed for the test. The different approaches, in terms of process conditions and monitoring methodologies, are pointed out in the review and highlighted to find significant correlations between the results obtained and the experimental procedures. These observed correlations allow critical considerations to be reached about the efficiency of the methodologies and the influence of the main abiotic factors on the process of biodegradation of bioplastics.

Monitoring of degradation of starch-based biopolymer film under different composting conditions, using TGA, FTIR and SEM analysis.

This paper presents the results of a composting lab-scale test carried out on Mater-Bi® film, a starch-based biopolymer. The test material is composed by starch, additives and polybutylene adipate terephthalate (PBAT). The test lasted for 45 days and was developed in three replicates under different temperature and moisture conditions, with the aim to assess the influence on Mater-Bi® degradation of less favourable composting conditions as short thermophilic phase, absence of moistening, and a combination of the two factors. The chemical nature and the morphology of the material and of its single components have been investigated before, during and at the end of the composting process, by means of different analytical techniques. ThermoGravimetric Analysis (TGA) allowed to obtain activation energy and weight loss; Fourier Transform InfraRed spectroscopy (FTIR) and Scanning Electron Microscopy (SEM) were used to study changes in the polymeric and morphological structure, and visual analysis provided information on the size of the Mater-Bi® particles. The results show that the biodegradation of PBAT is strongly influenced by the environmental conditions (temperature and moisture); on the contrary, in all the three replicates, both starch and additives are completely biodegraded within the first days of the process.