The biodegradable composite insulation material is made from date palm leaf fibers and powdered okra. The date palm leaf fibers have a concentration of between 50 wt % and 90 wt % of the biodegradable composite insulation material, and the powdered okra has a concentration of between 10 wt % and 50 wt % of the biodegradable composite insulation material. The biodegradable composite insulation material is prepared by mixing date palm leaf fibers and powdered okra, in the above concentrations, to form a mixture. This mixture is then wetted with water, added to a mold, and heated under pressure to form a compressed article. The compressed article is then dried to form the biodegradable composite insulation material.

A biopolymer is disclosed that comprises a polydeoxyribonucleotide (PDRN), or a derivative or modification thereof, having a molecular weight in the range of 400 kDa to 3200 kDa, and an anionic and ampholytic heteropolysaccharide having sulfate and carboxyl groups and a molecular weight in the range of 14 MDa and 16 MDa, in which the polydeoxyribonucleotide and the heteropolysaccharide are crosslinked by genipin or an analogue or derivative thereof. Furthermore, the invention relates to methods of producing such biopolymer and uses thereof.

The invention concerns a polymer composite comprising:

a. biodegradable polymer in an amount of 5-94.5% by weight of the overall weight;
b. whole grain flour of cereal grass in an amount of at least 5% by weight of the overall weight;
c. plasticizer in an amount from 5-50% w/w of component b);
d. optional filler, and
e. optional additive, wherein
c) is a solid plasticizer with a melting temperature in the range of 70 to 210° . The invention also concerns a process for its preparation, an intermediate, and a solid article comprising the polymer composite.

The present invention relates to the use of an activated carrot fiber for preparing products in the food or non-food area. The invention also relates to products containing the activated carrot fiber.

An anti-biofouling shape-memory composite aerogel includes a unidirectional chitosan aerogel channel, a plant polyphenol coating, and a polyphenol/iron ion chelate. The plant polyphenol coating is evenly distributed on an inner wall of the unidirectional chitosan aerogel channel, and the polyphenol/iron ion chelate is located at a top end of the unidirectional chitosan aerogel channel. The anti-biofouling chitosan-based composite aerogel has an evaporation rate of 1.96 kg.Math.m.sup.−2.Math.h.sup.−1 at an illumination intensity of 1 kW/m.sup.2. The composite aerogel has shape-memory properties, and can quickly restore its original shape in water after extrusion, thereby accelerating the diffusion of substances to complete the modification of inner channels. In this way, desirable anti-biofouling ability is achieved, and excellent structural stability as well as continuous and efficient photothermal water evaporation are guaranteed in a complex water environment.

The disclosure provides eco-friendly synthetic wood containing coffee grounds, which uses, as main components, coffee grounds and waste gypsum, which are waste resources, and PETG recycled from waste plastic, thereby contributing to protection of the environment, and which enhances formability, post-processability, and a weather resistance of the synthetic wood by reducing a ratio of shrinking-swelling and a water absorption factor of the synthetic wood, and a manufacturing method thereof.

The invention concerns a polymer composite comprising:

a. biodegradable polymer in an amount of 5-94.5% by weight of the overall weight;

b. flour of pulse in an amount of at least 5% by weight of the overall weight;

c. plasticizer in an amount from 5-50% w/w of component b);

d. optional filler, and

e. optional additive,

wherein

c) is a solid plasticizer with a melting temperature in the range of 70 to 210°. The invention also concerns a process for its preparation, an intermediate, and a solid article comprising the polymer composite.

A composite material includes a polymer matrix with a polymer having D-glucosamine monomer units and 50% or fewer N-acetyl-D-glucosamine monomer units. A salt can be disposed in the polymer matrix. A dispersed phase is disposed in the polymer matrix with the salt, and the dispersed phase and the polymer matrix form a porous composite foam. The porous composite foam includes, by weight, 0.5-3 times the dispersed phase to the polymer matrix, and the porous composite foam has a density of less than 1 g/cm.sup.3.

Provided herein are mycelium materials and methods for production thereof. In some embodiments, a mycelium material includes: a cultivated mycelium material including one or more masses of branching hyphae, wherein the one or more masses of branching hyphae may be disrupted or pressed and/or a bonding agent may be combined with the cultivated mycelium material. Methods of producing a mycelium material are also provided.

Provided herein are mycelium materials and methods for production thereof. In some embodiments, a mycelium material includes: a cultivated mycelium material including one or more masses of branching hyphae, wherein the one or more masses of branching hyphae may be disrupted or pressed and/or a bonding agent may be combined with the cultivated mycelium material. Methods of producing a mycelium material are also provided.