ADVANTAGES OF BIODEGRADABLE POLYMERS

1.        Compost derived in part from biodegradable plastics increases the soil organic content.

2.        The water and nutrients are retained.

3.        The chemical inputs and plant diseases are suppressed.

4.        Biodegradable shopping and waste bags disposed in a landfill can increase the rate of organic waste degradation in landfills.

5.        Methane harvesting potential is also enhanced.

6.        The landfill space usage is decreased. Biodegradable landfill covers can extend landfill life considerably.

7.        Energy required to synthesize and manufacture biodegradable plastics is much lower for most biodegradable plastics than for non-biodegradable plastics.

8.        Biodegradable plastics also offer important environmental benefits through the use of renewable energy resources and reduced greenhouse gas emissions.

BIODEGRADABLE POLYMER TERMINOLOGY

Many polymers that are claimed to be ‘biodegradable’ are in fact ‘bioerodable’, ‘hydrobiodegradable’ or ‘photo-biodegradable’. These different polymer classes all come under the broader category of ‘environmentally degradable polymers’.

Various classes of biodegradable plastics, considered in terms of the degradation mechanism are:

1.         Biodegradable

2.         Compostable

3.         Hydro- biodegradable

4.         Photo- biodegradable

5.         Bioerodable

6.         Degradable  polymers

7.         Degradation

8.         Disintegration

9.         Elimination

10.       Erosion

BIODEGRADABLE

Biodegradation is degradation caused by biological activity, particularly by enzyme action leading to significant changes in the materials chemical structure. In essence, biodegradable plastics should break down cleanly, in a defined time period, to simple molecules found in the environment such as carbon dioxide and water.

COMPOSTABLE

Compostable biodegradable plastics must be demonstrated to biodegrade and disintegrate in a compost system during the composting process (typically around 12 weeks at temperatures over 50°C).

HYDRO-BIODEGRADABLE

Hydro-biodegradable polymers are broken down in a two-step process - an initial hydrolysis followed by further biodegradation.

PHOTO-BIODEGRADABLE

Photo-biodegradable polymers are broken down in a two-step process - an initial photo-degradation stage, followed by further biodegradation.

BIO-ERODABLE

Many polymers are  ‘bioerodable’. They degrade without the action of micro-organisms. This is also known as abiotic disintegration, and include processes such as dissolution in water, ‘oxidative embrittlement’ (heat ageing) or ‘photolytic embrittlement’

DEGRADABLE POLYMERS

A material is called degradable if it undergoes degradation to a specific extent within a given time measured by specific Standard Test methods.

DEGRADATION

It is an irreversible process leading to a significant change of the structure of a material, typically characterized by a loss of properties (e.g. integrity, molecular weight, structure or mechanical strength) and/ or fragmentation.

DISINTEGRATION

Disintegration means the falling apart into very small fragments of packaging or packaging material caused by degradation mechanisms.

ELIMINATION

It is the excretion and metabolism of polymer and erosion product from mammals.

EROSION

It is the mass loss of a polymer matrix which can be due to the loss of monomers, oligomers or even pieces of non degraded polymers. Erosion can be the result of biological, chemical or physical effect.