The present invention provides a chitosan-based composition that can be converted into a self-supporting casted object having good tensile and compressive strength that can also biodegrade at the end of its lifecycle. The composition comprises entirely bio-based or bio-sourced reagents that can be converted to the final product via a polymerization process that does not require the addition of inorganic catalysts, synthetic materials, or otherwise hazardous chemicals to strengthen or modify its water resistance.

The present invention provides a chitosan-based composition that can be converted into a self-supporting casted object having good tensile and compressive strength that can also biodegrade at the end of its lifecycle. The composition comprises entirely bio-based or bio-sourced reagents that can be converted to the final product via a polymerization process that does not require the addition of inorganic catalysts, synthetic materials, or otherwise hazardous chemicals to strengthen or modify its water resistance.

The present application discloses improved lignocellulosic composite materials comprising a lignocellulosic component, a bis-electrophile, and a polynucleophile. Exemplary embodiments comprise a dianhydride and a polyol.

The present application discloses improved lignocellulosic composite materials comprising a lignocellulosic component, a bis-electrophile, and a polynucleophile. Exemplary embodiments comprise a dianhydride and a polyol.

A system, controller, and method for decortication processing on one or more input units of hemp into one or more resultant products. The method includes: analyzing one or more characteristics of the input units; cutting the input units into a predetermined size; opening the cut input units; performing decortication on the opened input units to separate the hemp into components, the components including bast, fibre, and hurd; densifying the fibre into bales; pulverizing the hurd and bast; combining the pulverized hurd and bast with thermoplastic polymers into a resultant product; receiving analyzer data from at least one of the decortication, the densifying, the pulverizing, and the combining; training a machine learning model based on the analyzer data; using the trained machine learning model to adjust one or more aspects to achieve a desired resultant product.

A system, controller, and method for decortication processing on one or more input units of hemp into one or more resultant products. The method includes: analyzing one or more characteristics of the input units; cutting the input units into a predetermined size; opening the cut input units; performing decortication on the opened input units to separate the hemp into components, the components including bast, fibre, and hurd; densifying the fibre into bales; pulverizing the hurd and bast; combining the pulverized hurd and bast with thermoplastic polymers into a resultant product; receiving analyzer data from at least one of the decortication, the densifying, the pulverizing, and the combining; training a machine learning model based on the analyzer data; using the trained machine learning model to adjust one or more aspects to achieve a desired resultant product.

The present invention includes methods of making a nanocellulosic composition comprising one or more nanocellulosic components, wherein the one or more nanocellulosic components comprise a micron-scale cellulose or cellulose nanofibrils (CNF), the method comprising the steps of: creating a nanocellulosic slurry by combining the one or more of nanocellulosic components with a liquid component; and exposing the nanocellulosic slurry to a drying condition, wherein the drying condition comprises microwave radiation, thereby creating a nanocellulosic composition. The present invention also includes compositions comprising cellulose (nanocellulosic compositions), wherein the nanocellulosic compositions have an internal void space of about 5% to about 95% by volume.

The present invention includes methods of making a nanocellulosic composition comprising one or more nanocellulosic components, wherein the one or more nanocellulosic components comprise a micron-scale cellulose or cellulose nanofibrils (CNF), the method comprising the steps of: creating a nanocellulosic slurry by combining the one or more of nanocellulosic components with a liquid component; and exposing the nanocellulosic slurry to a drying condition, wherein the drying condition comprises microwave radiation, thereby creating a nanocellulosic composition. The present invention also includes compositions comprising cellulose (nanocellulosic compositions), wherein the nanocellulosic compositions have an internal void space of about 5% to about 95% by volume.

Provided are a rubber composition for tires and a pneumatic tire, which are excellent in braking performance on ice and failure properties. The rubber composition for tires includes, per 100 parts by mass of a solid rubber component, 1 to 20 parts by mass of a liquid polybutadiene having a glass transition temperature of −80° C. or less and 1 to 30 parts by mass of vegetable granules having a particle size of 0.1 to 500 μm.

Provided are a rubber composition for tires and a pneumatic tire, which are excellent in braking performance on ice and failure properties. The rubber composition for tires includes, per 100 parts by mass of a solid rubber component, 1 to 20 parts by mass of a liquid polybutadiene having a glass transition temperature of −80° C. or less and 1 to 30 parts by mass of vegetable granules having a particle size of 0.1 to 500 μm.