A Study on Degradation of Composite Material PBS/PCL

Huang, Jitao; Cui, Chunna; Yan, Guiyang; Huang, Jianhua; Zhang, Min

doi:10.1177/096739111602400209

Cited by 11 publications

(10 citation statements)

References 18 publications

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“…The reason for a slight increase in crystallinity after biodegradation could be due to changes in amorphous part (low density area) which is more prone to biodegradation first than the crystalline part of the composite. [29]. The overlay comparison of XRD scans before and after biodegradation of 45 days for 40 wt% untreated and 40 wt% alkali treated fiber for both PP/Banana peel and PP/Pigeon pea stalk composites have been shown in Fig.…”

Section: X-ray Diffraction (Xrd)mentioning

confidence: 99%

Biodegradation studies of polypropylene/natural fiber composites

et al. 2020

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Polypropylene composites were prepared using natural fibers such as pigeon pea stalk fibers and banana peel. Aerobic biodegradation studies in compost have been carried out as per ASTM with composites prepared where cellulose and polypropylene has been taken as positive and negative reference respectively. Various analytical tools like SEM, TGA, XRD, DSC and Color have been used to study the change after biodegradation in composites. Highest fiber loaded composites i.e. 40 wt% depicted highest biodegradation in comparison to 10 and 20 wt% loading of untreated fiber in polypropylene. In comparison to untreated fiber composites, maximum biodegradation was observed in treated fiber composites with same amount of the fiber loading.

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Section: X-ray Diffraction (Xrd)mentioning

confidence: 99%

Biodegradation studies of polypropylene/natural fiber composites

et al. 2020

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“…Notably, PBS and PCL significantly suppressed E. sativa growth by reducing aboveground biomass and leaf number. Studies have shown that PBS and PCL degrade more rapidly than PBAT (Huang et al 2016;Liu et al 2022aLiu et al , 2022b. Tamayo-Belda et al (2022) confirmed that PCL degrades rapidly (ca.…”

Section: Discussionmentioning

confidence: 98%

“…in 14 days), resulting in considerable release of nanoparticles. Additionally, PBS had degradation rate of nearly 30% by day 50 (Huang et al 2016;Sun et al 2022). Consequently PBS and PCL microplastics are more likely to become nanoplastics during a short experiment period (14-50 days).…”

Section: Discussionmentioning

confidence: 98%

The effects of microplastics on crop variation depend on polymer types and their interactions with soil nutrient availability and weed competition

Ma,

Fu,

Liu

2024

Plant Biol J

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Microplastics pollution of agricultural soil is a global environmental concern because of its potential risk to food security and human health. Although many studies have tested the direct effects of microplastics on growth of Eruca sativa Mill., little is known about whether these effects are regulated by fertilization and weed competition in field management practices. Here, we performed a greenhouse experiment growing E. sativa as target species in a three‐factorial design with two levels of fertilization (low versus. high), two levels of weed competition treatments (weed competition versus no weed competition) and five levels of microplastic treatments (no microplastics, Polybutylene adipate‐co‐terephthalate [PBAT], Polybutylene succinate [PBS], Polycaprolactone [PCL] or Polypropylene [PP]). Compared to the soil without microplastics, PBS and PCL reduced aboveground biomass and leaf number of the E. sativa. PBS also resulted in increased root allocation and thicker roots in E. sativa. In addition, fertilization significantly mitigated the negative effects of PBS and PCL on aboveground biomass of E. sativa, but weed competition significantly promoted these effects. Although fertilization alleviated the negative effect of PBS on aboveground biomass, such alleviation became weaker under weed competition than when E. sativa grew alone. The results indicate that the effects of specific polymer types on E. sativa growth could be regulated by fertilization, weed management, and even their interactions. Therefore, reasonable on‐farm management practices may help in mitigating the negative effects of microplastics pollution on E. sativa growth in agricultural fields.

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Section: Organic Recycling Of Bio-based Materials With the Use Of Mos...mentioning

confidence: 99%

“…The biodegradation of bio-based products may be affected by changes in their composition. For example, in composting conditions, a composite of PBS and PCL degraded faster than pure PBS and PCL (Huang et al, 2016), whereas pure PHB and PLA disintegrated faster than a blend of these substances and PBAT (Tabasi and Ajji, 2015). Cadar et al (2012) reported that, under controlled composting conditions, the biodegradation degree of PLA copolymer increased as the amount of LA in the material was increased.…”

Section: Aerobic Conditions/compostingmentioning

confidence: 99%

The development of recycling methods for bio-based materials – A challenge in the implementation of a circular economy: A review

Zaborowska

Bernat

2022

Waste Manag Res

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This review focuses on the characteristics of the most widely used biopolymers that contain starch, polylactic acid, cellulose and/or polybutylene succinate. Because worldwide production of bio-based materials has grown dynamically, their waste is increasingly found in the existing waste treatment plants. The development of recycling methods for bio-based materials remains a challenge in the implementation of a circular economy. This article summarizes the recycling methods for bio-based materials, which, in the hierarchy of waste management, is much more desirable than landfilling. Several methods of recycling are available for the end-of-life management of bio-based products, which include mechanical (reuse of waste as a valuable raw material for further processing), chemical (feedstock recycling) and organic (anaerobic digestion or composting) ones. The use of chemical or mechanical recycling is less favourable, more costly and requires the improvement of systems for separation of bio-based materials from the rest of the waste stream. Organic recycling can be a sustainable alternative to those two methods. In organic recycling, bio-based materials can be biologically treated under aerobic or anaerobic conditions, depending on the characteristics of the materials. The choice of the recycling method to be implemented depends on the economic situation and on the properties of the bio-based products and their susceptibility to degradation. Thus, it is necessary to label the products to indicate which method of recycling is most appropriate.

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A Study on Degradation of Composite Material PBS/PCL

Cited by 11 publications

References 18 publications

Biodegradation studies of polypropylene/natural fiber composites

Biodegradation studies of polypropylene/natural fiber composites

The effects of microplastics on crop variation depend on polymer types and their interactions with soil nutrient availability and weed competition

The development of recycling methods for bio-based materials – A challenge in the implementation of a circular economy: A review

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