Violette Bourg scite author profile

Violette Bourg

3Publications

51Citation Statements Received

200Citation Statements Given

How they've been cited

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204

193

Affiliations

Nestlé (Switzerland), University of Montpellier, Agropolymerpolymer Engineering and Emerging Technologies

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Chitin- and cellulose-based sustainable barrier materials: a review

Bourg

et al. 2020

emergent mater.

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The accumulation of synthetic plastics used in packaging applications in landfills and the environment is a serious problem. This challenge is driving research efforts to develop biodegradable, compostable, or recyclable barrier materials derived from renewable sources. Cellulose, chitin/chitosan, and their combinations are versatile biobased packaging materials because of their diverse biological properties (biocompatibility, biodegradability, antimicrobial properties, antioxidant activity, non-toxicity, and less immunogenic compared to protein), superior physical properties (high surface area, good barrier properties, and mechanical properties), and they can be assembled into different forms and shapes (powders, fibers, films, beads, sponges, gels, and solutions). They can be either assembled into packaging films or used as fillers to improve the properties of other biobased polymers. Methods such as preparation of composites, multilayer coating, and alignment control are used to further improve their barrier, mechanical properties, and ameliorate their moisture sensitivity. With the growing application of cellulose and chitin-based packaging materials, their biodegradability and recyclability are also discussed in this review paper. The future trends of these biobased materials in packaging applications and the possibility of gradually replacing petroleum-based plastics are analyzed in the “Conclusions” section.

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Shear and Extensional Rheology of Linear and Branched Polybutylene Succinate Blends

Bourg

Valette

Moigne³

et al. 2021

Polymers

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The molecular architecture and rheological behavior of linear and branched polybutylene succinate blends have been investigated using size-exclusion chromatography, small-amplitude oscillatory shear and extensional rheometry, in view of their processing using cast and blown extrusion. Dynamic viscoelastic properties indicate that a higher branched polybutylene succinate amount in the blend increases the relaxation time due to an increased long-chain branching degree. Branched polybutylene succinate exhibits pronounced strain hardening under uniaxial elongation, which is known to improve processability. Under extensional flow, the 50/50 wt % blend exhibits the same behavior as linear polybutylene succinate.

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Modeling of internal residual stress in linear and branched polyethylene films during cast film extrusion: Towards a prediction of heat-shrinkability

Bourg

Ienny

Caro-Bretelle

et al. 2019

Journal of Materials Processing Technology

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Violette Bourg

Chitin- and cellulose-based sustainable barrier materials: a review

Shear and Extensional Rheology of Linear and Branched Polybutylene Succinate Blends

Modeling of internal residual stress in linear and branched polyethylene films during cast film extrusion: Towards a prediction of heat-shrinkability

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