Innovation in the plastics industry: how graphene masterbatches are changing the game

Innovation in the plastics industry:

how graphene masterbatches are changing the game

Graphene has extraordinary electrical, optical, thermal properties and high mechanical resistance. The properties of graphene are attributed to its structure in the form of two-dimensional (2D) sheets, formed by hexagonal bonded carbon atoms and a thickness of one carbon atom.

Today, graphene is the most promising nanotechnological additive in the plastics industry. The incorporation of graphene and its derivatives (graphene oxide, GO) in different polymer matrices (masterbatches), have great potential for a wide range of applications. The graphene masterbatch can act as a mechanical reinforcement or conductive additive for both thermoplastic and thermosetting materials. They can be used in the automotive, aerospace, electronics or packaging sectors.

Graphene-based polymeric compounds have shown significant improvements in properties such as elastic modulus, tensile strength, impact resistance, electrical conductivity, resistance to UV radiation, thermal stability, antimicrobial property, impermeability or barrier effect (it does not allow the diffusion of moisture or other molecules).

Currently Energeia – Graphenemex®, a leading Mexican company in Latin America in research and production of graphene materials for the development of applications at an industrial level, through its Graphenergy Masterbatch line, has developed and sells a wide range of masterbatches with graphene, based on various polymers, such as PP, HDPE, LDPE, PET and PA6.

Our Masterbatches are granular materials that act as multifunctional additives. The incorporation of graphene in different polymer matrices has shown important effects on the properties and processing conditions of plastics, among which are:

  • Increased resistance to tension, deformation and impact
  • Increased resistance to ultraviolet rays
  • Excellent dispersion
  • Improves processing conditions (thermal stability)
  • Acts as a nucleating agent (modification of the crystallization temperature of the polymer)

In this sense, it has been found that the incorporation of graphene and its derivatives, as well as the concentration, can modify the physicomechanical properties of the polymer to be processed. The addition of masterbatch to different polymers has improved the final characteristics of the material to a lesser or greater extent, for example:

  • Additivation of Polypropylene (PP) with polypropylene-graphene masterbatch (MB-PP/GO), increases tensile strength (8%) and rupture percentage (29%).
  • Additivation of Polyethylene (PE) with polyethylene-graphene masterbatch (MB-PE/GO), improves tensile strength (17%), flexural strength and rupture strength (66%).
  • Additivation of Polyethylene terephthalate (PET) with polyethylene terephthalate-graphene masterbatch (MB-PET/GO), improves resistance to humidity, increases tensile strength (72.2%) and improves impact resistance.
  • Additivation of Polycarbonate (PC) with polycarbonate-graphene masterbatch (MB-PC/GO), improves resistance to humidity and improves resistance to rupture (276%).

On the other hand, graphene masterbatches can also be incorporated into recycled polymers. Currently, the reuse and recycling of plastic materials are of vital importance in the transition path towards a circular economy. In this regard, the constant washing, pelletizing and reprocessing can cause the loss of physicomechanical properties of recycled plastics, therefore, by adding graphene, these properties can be restored or improved. In agricultural applications, mulch films with increased resistance to ultraviolet radiation can be produced.

References

  1. Fang, M., et al., Covalent polymer functionalization of graphene nanosheets and mechanical properties of composites. Journal of Materials Chemistry. 19(38): p. 7098-7105.
  2. Kim, H., A.A. Abdala, and C.W. Macosko, Graphene/Polymer Nanocomposites. Macromolecules. 43(16): p. 6515-6530.
  3. Balandin, A.A., et al., Superior Thermal Conductivity of Sin gle-Layer Graphene. Nano Letters, 8(3): p. 902-907.
  4. Nabira Fatima, Umair Yaqub Qazi, Asim Mansha., Recent developments for antimicrobial applications of graphene-based polymeric composites: A review, https://doi.org/10.1016/j.jiec.2021.04.050

Graphene and its impact on the packaging industry

Graphene

and its impact on the packaging industry

According to data from the World Bank, every year in Mexico 24 million tons of food are wasted. This means that 34% of the country’s production is not only NOT consumed, but also generates an average expense of 491 billion pesos.

This impact is not only economic, but it is a problem that extends to the social sphere, due to the well-known food crisis and to the environment, due to the high water requirements for food production processes that will not be used and whose decomposition will contribute considerable CO2 emissions that contribute to global warming.

According to the Food and Agriculture Organization of the United Nations, the loss and food waste exceeds 1,300 million tons per year.

Within this multifactorial problem, the container and packaging industry, also known as “packing”, is a crucial actor considering that there are unavoidable conditions such as temperature, humidity, lighting, oxygen and numerous handling practices throughout the entire supply chain. production of food, which affect its quality, shelf life and acceptability by consumers.

In the search for solutions to improve the quality of packing products and, consequently, their content, nanotechnology has been a great ally. For example, to avoid microbial contamination, nanoparticles of silver, titanium dioxide, copper oxide, carbon nanotubes or magnesium oxide are used; to improve the mechanical or barrier properties, it is common to use nanoparticles of silicate, clay, polyamide, iron or iron oxides, cellulose nanofibers and for other needs there are nanoparticles of tungsten, molybdenum, barium sulfate, barium titanate , chitosan, zeolites, activated carbon, etc.

Graphene nanoparticles are mainly made up of carbon, like graphite and diamond, but with multifunctional characteristics. This means that they do not have a single function, but rather, unlike other nanoparticles, Graphene, due to its extraordinary physical and chemical properties, can be used for different purposes, for example, to design lighter and more resistant products, with greater impermeability against liquids and gases, in addition to protecting against microbial contamination and against UV radiation, among other properties that substantially improve the performance of the compounds with which it is combined.

“Graphene has crossed the limits of laboratories to reach commercial applications to combat the main enemies of food”, these are some examples of what is being developed for the Packing industry:

Tetra Pak
The Swedish company Tetra Pak, leader in research and development in the packaging sector, through the European Graphene Flagship project, studies the use of Graphene for the manufacture of products with low environmental impact to reduce the carbon footprint, improve the performance of materials, add properties and optimize recyclability.

Applynano
The Spanish company Applynano uses nanomaterials, including graphene oxide, to promote the durability and recyclability of plastics, as well as to improve antimicrobial, thermal, and electrical properties, among others.

Plastic Technology Center (Andaltec)
The Technological Center of Plastic (Andaltec) within the European project Grafood, had the initiative to use derivatives of Graphene for the development of active packaging to increase the shelf life of food and reduce food waste.

Energeia – Graphenemex®
The Mexican company Energeia – Graphenemex®, through the polymer division Graphenergy Advanced Graphenic Solutions, promotes the use of Graphene and its derivatives as nano-reinforcement of plastic for different industries. Among the benefits it offers for the packing industry are mechanical resistance and resistance to degradation by UV radiation, greater barrier effect and interesting antimicrobial properties, highly promising for prolonging the life of products and their contents. Likewise, in addition to adding value to its developments with the multifunctional properties of Graphene and its derivatives, the company also aims to support other innovation projects with graphene nanotechnology, while seeking to collaborate with the circular economy to improve the quality of new and recycled plastic materials, to reduce the consumption of single-use products.

Polymeric nanocomposites with graphene: the future of the industry

Polymeric nanocomposites with graphene:

the future of the industry

Mexico City – Thanks to the extraordinary properties, innumerable investigations and business promises around Graphene in the world, in 2021 its market was valued at 127.12 million dollars, forecasting an annual growth rate of more than 70% in the period from 2022 to 2027. However, 18 years after its isolation and despite the enormous competition from companies to develop applications with this nanomaterial, there are still relatively few products available on the market that contain it and take advantage of its benefits. This is mainly due to the investment and complexity for the transformation of graphite into graphene or in any of its variants (graphene oxide and reduced graphene oxide), the difficulty of producing it on an industrial scale to have it available as the fundamental raw material in the transformation of new compounds, as well as the need for scientific-industrial knowledge for the creation of efficient and economically viable applications.

The Mexican company Energeia Fusion S.A. de C.V., has focused on solving the most representative obstacles that Graphene has faced to reach the market, working hard on the creation and standardization of its own methods and processes that today allow it to optimize resources for product development. quality in a short time.

Polymeric nanocomposites with graphene oxide

The polymer division of the Graphenergy Advanced Graphenic Solutions line is part of a new line of highly effective nanotechnological additives for the plastics industry that, in addition to the added value represented by the multifunctional properties that graphene provides to polymers (mechanical strength, impermeability, resistance to UV radiation and/or antimicrobial activity), it also adds value for the circular economy, since it allows the use, reuse and recycling of plastic products, reducing the exploitation of natural resources and reducing the generation of waste, resulting in significant social, economic and environmental impacts.

What is the science of Graphene for reinforcing materials?

  1. Las fuertes interacciones entre la región interfacial de la matriz polimérica y las partículas nanométricas del grafeno son decisivas para mejorar las propiedades de los materiales,
  2. La correcta integración del grafeno con los materiales poliméricos mejora la organización en su estructura, haciendola más densa y compacta y por lo tanto mejora las propiedades mecánicas.
  3. Mejora las propiedades de barrera contra líquidos y gases, aumenta el tiempo de vida útil del producto y permite tener diversas propiedades en un solo material, como: conductividad, resistencia a la radiación ultravioleta, impermeabilidad, flexibilidad, ligereza, actividad antimicrobiana, etc.

“Las propiedades del Grafeno son tan numerosas como las variables asociadas, por eso es difícil definir una fórmula estándar que satisfaga todas sus expectativas. El reto está en encontrar el equilibrio entre sus propiedades”.

A continuación, se describen algunos de los innumerables efectos y potenciales usos de los materiales grafénicos sobre distintas matrices poliméricas:

Mechanical strength

Graphene materials cause changes in the viscoelastic behavior of polymers, showing greater resistance to elongation, an interesting property for the design of products that are more resistant to deformation, such as sealing products, cushioning, transport or tires, footwear, sports, etc. In addition to increasing the elastic modulus, it also improves the impact resistance of polymers in the range of 20 to 200%, with weight reductions of up to 35%, this property is of interest for the manufacture of lighter products with equal or greater resistance than conventional plastics, opening the possibility of reducing or substituting the use of metal parts for plastic parts for the automotive, construction, and security industries, among others.

Resistance to degradation

On the other hand, this nanomaterial has also shown other interesting contributions, for example, in accelerated weathering tests carried out on plastics reinforced with graphene and/or derivatives, it has been identified that the use of low concentrations can increase its resistance to extreme conditions up to 7 times. of humidity, temperature and ultraviolet radiation. Furthermore, if we consider that when plastic is exposed to UV radiation, it emits greenhouse gases (methane and ethylene). Therefore, by increasing the resistance to degradation, we could also favor the reduction of these emissions, without affecting the ability of PET to be reused or recycled, but, on the contrary, using graphene offers it more opportunities to be recycled.

Fire resistance

Another recognized property of graphene is that it is an excellent thermal conductor. In tests carried out on different polymers, those modified with graphene oxide, in addition to improving their mechanical properties, also improved flame retardancy. Being the polypropylene the most benefited when identifying a self-extinguishing behavior. This contribution is attractive for its application in electrical cable and wire coatings or plastic materials in general that require thermal resistance.

These are just some of the multiple properties that graphene and its derivatives can offer the plastics industry and all those who benefit from it and that, despite efforts to reduce the circulation of plastic due to environmental impacts, the advantages offered by graphene can be well focused to make the use, reuse and recycling of plastic more efficient.

Some of the plastic products with graphene that have been commercialized are described below:

  1. Energeia Fusion-Graphenemex through its polymer division develops Masterbatches with graphene oxide for the production of personal protection equipment such as face shields and non-woven fabrics for face masks. Likewise, it has developed modified polymers for hydraulic concrete and asphalt concrete, in addition to the Graphenergy line of coatings for anticorrosive and antimicrobial protection (Mexico),
  2. Directa Plus designed a face mask with graphene for the fight against the pandemic caused by SARS-COV2 (United Kingdom),
  3. The international wheel producer Vittoria developed the bicycle wheels called Qurano (Italy),
  4. Progress, with its Progress Atom LTD model, provides better performance in terms of wear resistance, greater grip, greater impermeability, more efficient heat dissipation and greater lateral rigidity, with less weight (Spain),
  5. Dassi Bikes built the world’s first bicycle made from graphene (UK),
  6. FiiO Electronics launched headphones with a graphene-enhanced diaphragm driver (China),
  7. NanoCase created smartphone cases for better heat dissipation (China),
  8. Catlike uses graphene to produce cycling helmets (Spain).

References