A cellulose saccharification method including an introduction step of introducing water, a raw material containing cellulose, and a surfactant into a saccharification vessel so as to obtain a liquid mixture, an agitation step of agitating the liquid mixture due to rotation of an impeller portion, and a detection step of detecting a torque sensed by the impeller portion, wherein regarding the agitation step, after agitation is performed until an amount of the torque changed in a unit time period becomes less than or equal to a predetermined value, when the torque is more than or equal to a threshold value, the surfactant is additionally introduced into the liquid mixture, or when the torque is less than the threshold value, a pH adjuster and an enzyme are introduced into the liquid mixture.

Provided is fibrous cellulose used for producing a concrete-pump pressure-feeding primer containing calcium carbonate powder, which is excellent in a dispersion stability and a pressure-feeding property. The fibrous cellulose is used for producing the concrete-pump pressure-feeding primer through mixing with the calcium carbonate powder. The fibrous cellulose contains ultrafine fibrous modified cellulose which has an ionic group and has a fiber width of 1,000 nm or less.

The present invention describes a method for the production of a spinning dope composition, said method comprising a homogenization involving vigorous mixing of a cellulosic pulp material in alkali solution, vigorous mixing implying supplying a power density to agitators used in the homogenization step of at least 150 kW/m.sup.3 (kW supplied to agitators per mixed unit of liquid volume), and thereafter a dissolution involving mixing of the cellulosic pulp material in the alkali solution to obtain a spinning dope composition, wherein the power density supplied to agitators used in the dissolution step is maximum 75 kW/m.sup.3 (kW supplied to agitators per mixed unit of liquid volume); and wherein the cellulosic pulp material in alkali solution is kept at a temperature of less than 0° C. during the homogenization and during at least part of the dissolution. The present invention is also directed to a system intended for the production of a spinning dope composition.

The present disclosure describes a method for the production of a spinning dope composition, said method comprising a homogenization involving mixing a cellulosic pulp material in alkali solution, mixing implying supplying a power density to agitators used in the homogenization of at least 150 kW/m.sup.3 (kW supplied to agitators per mixed unit of liquid volume), and thereafter a dissolution involving mixing of the cellulosic pulp material in the alkali solution to obtain a spinning dope composition, wherein the power density supplied to agitators used in the dissolution step is maximum 75 kW/m.sup.3 (kW supplied to agitators per mixed unit of liquid volume); and wherein the cellulosic pulp material in alkali solution is kept at a temperature of less than 0° C. during the homogenization and during at least part of the dissolution. The present disclosure is also directed to a system intended for the production of a spinning dope composition.

Disclosed is a process for solubilising cellulose and coagulating the resulting solution to form a cellulose-containing material. The process comprises contacting a cellulose source with a solvent comprising zinc ions and formic acid to provide a solution, coagulating the solution to provide a solid material, and isolating the solid material after treatment, to provide the cellulose-containing material. The process further involves a method of stabilising the solid material, such as treating the solid material with a reducing agent, treating the solid material in water at an elevated temperature, treating the solid material with an organic solvent, pre-treating the cellulose-containing solution with a freeze-thaw cycle and/or isolating a cellulose formate intermediate. The process can further comprise solubilising protein and coagulating the resulting solution to form a cellulose/protein-containing material.

The present invention relates to a web of fibrous cellulosic material derived from wood pulp, said web being suitable for three-dimensional moulding to form a packaging product, wherein the web comprises >40 wt % of soft wood chemical pulp and at least one strength enhancement agent, wherein the web has a grammage less than 400 g/m.sup.2, and wherein the cellulose fibers of said soft wood chemical pulp comprise a fiber curl of >9%.

Cellulose derivative particles including an alkoxy group having 2 or more carbons or an acyl group having 3 or more carbons, wherein the cellulose derivative particles have an average particle size of 80 nm or greater and 100 μm or less, a sphericity of 70% or greater and 100% or less, and a surface smoothness of 80% or greater and 100% or less; and a total substitution degree of the cellulose derivative is 0.7 or greater and 3 or less.

The disclosure discloses a multi-response cellulose nanocrystals-composite film and a preparation method thereof, belonging to the technical field of functional materials. The multi-response cellulose nanocrystals-composite film of the disclosure includes cellulose nanocrystals, a deep eutectic solvent and anthocyanins. The deep eutectic solvent is composed of choline chloride and biological sugar. A mass ratio of the choline chloride to the biological sugar is 1-20:1-6. A mass ratio of the cellulose nanocrystals to the deep eutectic solvent to the anthocyanins is 10:0-10:1, and the amount of the deep eutectic solvent is not 0. The preparation method of the composite film of the disclosure is simple and easy to operate, and has the advantages of mild conditions and short time consumption. The multi-response film prepared in the disclosure has humidity and pH detection functions, has the advantages of good flexibility, good reversibility, excellent stability, etc., and can be used as a flexible humidity and pH sensor.

A process for producing a cellulosic functional fiber having high ion exchange capacity, a cellulosic functional fiber produced by said process, a textile product comprising said cellulosic functional fiber, and a garment or piece of furniture comprising said cellulosic functional fiber and/or said textile product. The cellulosic functional fiber produced is characterized in that it comprises an extracted plant material with polymer-bound uronic acids contained therein.

Provided is a cellulose solution (a composition) in which decomposition of cellulose does not easily proceed even if heated. Further, provided is a method for producing a cellulose fiber excellent in mechanical strength. The composition includes cellulose and a compound represented by the following formula (1), a concentration of 1-methylimidazolium chloride being 300 ppm or less on a mass basis with respect to the compound represented by the formula (1).

In the formula (1), R is an alkyl group having 2 to 6 carbon atoms, and Me is a methyl group.

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