Embodiments of the present disclosure generally relate to materials and methods for producing a wide range of raw materials from plant biomass. In certain embodiments, the present disclosure provides materials and methods for efficient decortication of plant biomass using a thermally regulated process to generate reactive oxygen species in the presence of a catalyst. Embodiments of the present disclosure address the need for improved methods with which to obtain a wide range of raw materials from plant biomass without the need for industrial decortication machines and without producing harmful industrial waste.

Embodiments of the present disclosure generally relate to materials and methods for producing a wide range of raw materials from plant biomass. In certain embodiments, the present disclosure provides materials and methods for efficient decortication of plant biomass using a thermally regulated process to generate reactive oxygen species in the presence of a catalyst. Embodiments of the present disclosure address the need for improved methods with which to obtain a wide range of raw materials from plant biomass without the need for industrial decortication machines and without producing harmful industrial waste.

A production technology for natural bamboo fibers is applied in producing woven bamboo fibers, non-woven bamboo fibers, and reinforcing composite bamboo fibers. The woven bamboo fibers are produced by steps of cutting to a certain length, slicing, flattening, softening, dividing, debonding, rinsing, soaking in oil, drying, and opening. The non-woven bamboo fibers and the reinforcing composite bamboo fibers are produced by steps of cutting to a certain length, slicing, flattening, softening, dividing, debonding (optional), rinsing, and drying.

A production technology for natural bamboo fibers is applied in producing woven bamboo fibers, non-woven bamboo fibers, and reinforcing composite bamboo fibers. The woven bamboo fibers are produced by steps of cutting to a certain length, slicing, flattening, softening, dividing, debonding, rinsing, soaking in oil, drying, and opening. The non-woven bamboo fibers and the reinforcing composite bamboo fibers are produced by steps of cutting to a certain length, slicing, flattening, softening, dividing, debonding (optional), rinsing, and drying.

A method of delinting cotton seeds with an alkanesulfonic acid comprises the steps of applying the alkanesulfonic acid to surfaces of linted cotton seeds, optionally heating the linted cotton seeds, and applying mechanical force to the surfaces of the linted cotton seeds. A composition for delinting cotton seeds comprises an alkanesulfonic acid (e.g. methanesulfonic acid (MSA)), a surfactant, and water.

A method of delinting cotton seeds with an alkanesulfonic acid comprises the steps of applying the alkanesulfonic acid to surfaces of linted cotton seeds, optionally heating the linted cotton seeds, and applying mechanical force to the surfaces of the linted cotton seeds. A composition for delinting cotton seeds comprises an alkanesulfonic acid (e.g. methanesulfonic acid (MSA)), a surfactant, and water.

A system and method for creating mycelium textile materials is disclosed, in which leftover, cutoff, and other materials used to create the textile materials that would otherwise be discarded are further used in a second process to create bonded mycelium boards. The system and method further reuse or recycle materials throughout the process of creating the mycelium textile fabric and bonded mycelium boards, thus keeping waste to a minimum.

A reaction chamber for continuous chemical processing of fibrous material, comprising: an elongate cavity having first and second ends at opposite ends of the elongate cavity and configured to contain the fibrous material and any reagents added to it for chemical processing; an input section at the first end of the elongate cavity, configured to feed fibrous material into the first end of the elongate cavity; an output section at the second end of the elongate cavity, configured to output fibrous material from the second end of the elongate cavity; and a transporter configured to drive fibrous material from the first end to the second end of the elongate cavity.

A reaction chamber for continuous chemical processing of fibrous material, comprising: an elongate cavity having first and second ends at opposite ends of the elongate cavity and configured to contain the fibrous material and any reagents added to it for chemical processing; an input section at the first end of the elongate cavity, configured to feed fibrous material into the first end of the elongate cavity; an output section at the second end of the elongate cavity, configured to output fibrous material from the second end of the elongate cavity; and a transporter configured to drive fibrous material from the first end to the second end of the elongate cavity.

Embodiments of the present disclosure generally relate to materials and methods for producing a wide range of raw materials from plant biomass. In certain embodiments, the present disclosure provides materials and methods for efficient decortication of plant biomass using a thermally regulated process to generate reactive oxygen species in the presence of a catalyst. Embodiments of the present disclosure address the need for improved methods with which to obtain a wide range of raw materials from plant biomass without the need for industrial decortication machines and without producing harmful industrial waste.