Bio-SAH™ 322Liquid
Polylactic acid (PLA) is a biodegradable and bioactive thermoplastic derived from renewable resources, such as corn starch or sugarcane. PLA is generally more susceptible to hydrolysis than some traditional plastics, and the use of anti-hydrolysis agents is one approach to mitigate its degradation when exposed to moisture.
Here are some types of anti-hydrolysis agents that can be used with PLA:
Phosphite Stabilizers:
Certain phosphite-based stabilizers are effective anti-hydrolysis agents. They act as antioxidants, helping to prevent the breakdown of PLA chains due to hydrolysis.
Polymeric Stabilizers:
Some polymeric stabilizers are designed for use with biodegradable polymers like PLA. These stabilizers can offer multifunctional benefits, including anti-hydrolysis properties.
Phenolic Antioxidants:
Phenolic antioxidants are commonly used to enhance the thermal and oxidative stability of polymers. In some cases, they may also provide anti-hydrolysis protection to PLA.
HALS (Hindered Amine Light Stabilizers):
HALS are additives that provide protection against the effects of light exposure, but they can also contribute to the overall stability of PLA, including anti-hydrolysis properties.
UV Absorbers:
Ultraviolet (UV) absorbers may indirectly contribute to anti-hydrolysis performance by reducing the impact of environmental factors, including UV radiation, which can accelerate the hydrolytic degradation of PLA.
Custom Formulations:
Some manufacturers may use proprietary formulations that combine various additives to achieve anti-hydrolysis properties. Custom formulations can be tailored to specific processing conditions and end-use requirements.
It's important to note that the choice of anti-hydrolysis agent depends on factors such as the intended application of PLA, the processing conditions, and the environmental conditions to which the material will be exposed. Additionally, the effectiveness of these agents may vary based on the specific formulation and processing methods.
For detailed and application-specific guidance, it is recommended to consult with polymer formulation experts or material suppliers who specialize in biodegradable polymers like PLA. They can provide tailored recommendations based on your specific requirements and processing conditions.
Polylactic acid (PLA) is a biodegradable and bioactive thermoplastic derived from renewable resources, such as corn starch or sugarcane. PLA is generally more susceptible to hydrolysis than some traditional plastics, and the use of anti-hydrolysis agents is one approach to mitigate its degradation when exposed to moisture.
Here are some types of anti-hydrolysis agents that can be used with PLA:
Phosphite Stabilizers:
Certain phosphite-based stabilizers are effective anti-hydrolysis agents. They act as antioxidants, helping to prevent the breakdown of PLA chains due to hydrolysis.
Polymeric Stabilizers:
Some polymeric stabilizers are designed for use with biodegradable polymers like PLA. These stabilizers can offer multifunctional benefits, including anti-hydrolysis properties.
Phenolic Antioxidants:
Phenolic antioxidants are commonly used to enhance the thermal and oxidative stability of polymers. In some cases, they may also provide anti-hydrolysis protection to PLA.
HALS (Hindered Amine Light Stabilizers):
HALS are additives that provide protection against the effects of light exposure, but they can also contribute to the overall stability of PLA, including anti-hydrolysis properties.
UV Absorbers:
Ultraviolet (UV) absorbers may indirectly contribute to anti-hydrolysis performance by reducing the impact of environmental factors, including UV radiation, which can accelerate the hydrolytic degradation of PLA.
Custom Formulations:
Some manufacturers may use proprietary formulations that combine various additives to achieve anti-hydrolysis properties. Custom formulations can be tailored to specific processing conditions and end-use requirements.
It's important to note that the choice of anti-hydrolysis agent depends on factors such as the intended application of PLA, the processing conditions, and the environmental conditions to which the material will be exposed. Additionally, the effectiveness of these agents may vary based on the specific formulation and processing methods.
For detailed and application-specific guidance, it is recommended to consult with polymer formulation experts or material suppliers who specialize in biodegradable polymers like PLA. They can provide tailored recommendations based on your specific requirements and processing conditions.
