Bioplastic is a biodegradable material that come from renewable sources and can be used to reduce the problem of plastic waste that is suffocating the planet and polluting the environment.

POLYMERHEMP

PolymerHemp is a polymer science technology focused on composites made from renewable sources.

A biocomposite is formed by a base matrix (resin) and reinforced by natural hemp fibers.

Why Bio-Plastic?

Bioplastics are biodegradable materials that come from renewable sources and can be used to reduce the problem of plastic waste that is suffocating the planet and contaminating the environment.

Does it make any sense to continue using packaging that can take centuries to disappear to pack products that only last days or months.

Bioplastic: An alternative to traditional plastic

As an alternative, the use of bioplastics is being promoted, consisting in obtaining natural polymers from agricultural, cellulose or potato and corn starch waste.

These are 100% degradable, equally resistant and versatile, already used in agriculture, textile industry, medicine and, over all, in the container and packaging market, and biopolymers are already becoming popular in cities throughout Europe and the United States for ecological reasons: they are known as PHA.

Advantages of bioplastics

  • They reduce carbon footprint
  • They providing energy savings in production
  • They do not involve the consumption of non-renewable raw materials
  • Their production reduces non-biodegradable waste that contaminates the environment
  • They do not contain additives that are harmful to health, such as phthalates or bisphenol A
  • They do not change the flavor or scent of the food contained

Uses of bioplastics:

It is expanding its use in various sectors: medical (prostheses, sutures …) in food (catering products, disposable containers …), toys, and even in the world of fashion (Versace has a clothing line Ingeo, made ​​from corn) and, of course, biodegradable bags.

Bioplastics are a large family of different materials

Bioplastics are not just one single material. They comprise of a whole family of materials with different properties and applications. According to European Bioplastics, a plastic material is defined as a bioplastic if it is either biobased, biodegradable, or features both properties.

‘Biobased’ does not equal ‘biodegradable’

The property of biodegradation does not depend on the resource basis of a material but is rather linked to its chemical structure. In other words, 100 percent biobased plastics may be non-biodegradable, and 100 percent fossil based plastics can biodegrade.

Benefits of bioplastics

Bioplastics are driving the evolution of plastics. There are two major advantages of biobased plastic products compared to their conventional versions: they save fossil resources by using biomass which regenerates (annually) and provides the unique potential of carbon neutrality.

Furthermore, biodegradability is an add-on property of certain types of bioplastics. It offers additional means of recovery at the end of a product’s life.

Types of Bioplastic

Bioplastics are currently used in disposable items like packaging, containers, straws, bags and bottles, and in non-disposable carpet, plastic piping, phone casings,

3D printing, car insulation and medical implants. The global bioplastic market is projected to grow from $17 billion this year to almost $44 billion in 2022.

From Wastewater to Bioplastic

Kartik Chandran and Columbia students are developing systems to produce biodegradable bioplastic from wastewater and solid waste. Chandran uses a mixed microbe community that feeds on carbon in the form of volatile fatty acids, such as acetic acid found in vinegar.

His system works by feeding wastewater into a bioreactor. Inside, microorganisms (distinct from the plastic-producing bacteria) convert the waste’s organic carbon into volatile fatty acids.

Full Cycle Bioplastics

Full Cycle Bioplastics in California is also producing PHA from organic waste such as food waste, crop residue such as stalks and inedible leaves, garden waste, and unrecycled paper or cardboard.

Used to make bags, containers, cutlery, water and shampoo bottles, this bioplastic is compostable, marine degradable (meaning that if it ends up in the ocean, it can serve as fish or bacteria food) and has no toxic effects. Full Cycle can process the PHA at the end of its life, and use it to make virgin plastic again.

Environmental impact of plastic

Environmental plastic pollution has become a priority of major global entities, including the UN15,16, the World Economic Forum (WEF)17, the World Health Organization18 and the European Union (EU)19. The plastics industry has traditionally implemented mostly linear processes focused on extracting raw materials and converting them into useful products, rather than recycling or reusing products2,20. The overall production of non-fibre plastics since 1950 has been dominated by PE (36.4%), polypropylene (PP; 21%) and polyvinylchloride (PVC; 12%), while the fibres market largely comprises polyethylene terephthalate (PET; 70%).

Climate change

Human activity has driven warming of the planet and increased extreme weather conditions, mainly rooted in the emission of GHGs through exploitation of fossil resources, such as CO2 and CH4. Plastic production consumes ~5–7% of the global oil supply and released >850 million tonnes of CO2 into the atmosphere in 2019, representing 2% of the global CO2 output. The majority of plastic-related CO2 emissions are incurred by raw material extraction (61%) and polymer production (30%), while only 9% is associated with the EOL stage, mainly incineration. Undocumented open burning of plastic waste might add >1 Gt of CO2 equivalent emissions to these numbers.

A Brief History of Bioplastics

Bioplastics are not as recent an invention as one might think. The Hyatt brothers had already developed celluloid – a thermoplastic polymer based on cellulose, the main component of most plants – as far back as 1869. The material was subsequently used to make camera film, spectacle frames and toys. Known as ‘cellophane’ since 1923, it is still used for packaging today. In fact, until the 1930s, plastics were almost exclusively produced from renewable sources. The use of fossil resources to make plastics only really started after the end of the Second World War.

Bioplastics often end up being thrown away with conventional plastic waste

In 2019, the EU produced a total of 79.6 million tonnes of packaging waste. At 15.4 million tonnes, the short-lived plastics used in packaging films, bags and single-use tableware were the second most significant material that was being tossed away, just behind cardboard in first place. This is an area where bioplastics offer huge potential. Technically speaking, compostable plastics should be disposed of in the organic waste bin. However, with consumers finding it difficult to distinguish between bioplastics and conventional plastics, bioplastics frequently end up in the general rubbish or plastic recyclables bins.