The invention provides methods for making substantially monodisperse populations of substantially spherical particles of polyarylketone polymers or of thio-analogues of such polymers, of selected sizes. Populations of such particles can be used, for example, to form porous devices with greater control of porosity than previously available. In some embodiments, the porous devices are frits, filters, membranes or monoliths.

A method for desalinating a salt-containing polymer is provided. The salt-containing polymer contains a polyaryl ether and a salt. The method includes the steps of mechanically increasing the surface area of the salt-containing polymer to obtain a salt-containing polymer of increased surface area, and contacting the salt-containing polymer of increased surface area with an extractant to obtain a desalinated polymer containing the polyaryl ether, and a salt-containing extractant containing the extractant and the salt.

A method for desalinating a salt-containing polymer (SP) comprising a polyaryl ether having a softening temperature T.sub.S and a salt (S), comprising the steps of a) providing the salt-containing polymer (SP) at a first temperature T.sub.1 above the softening temperature T.sub.S of the polyaryl ether, b) contacting the salt-containing polymer (SP) provided in step a) with an extractant (E) to obtain a desalinated polymer (DP) comprising the polyaryl ether, and a salt-containing extractant (SE) comprising the extractant (E) and the salt (S).

A method for desalinating a salt-containing polymer (SP) comprising a polyaryl ether having a softening temperature T.sub.S and a salt (S), comprising the steps of a) providing the salt-containing polymer (SP) at a first temperature T.sub.1 above the softening temperature T.sub.S of the polyaryl ether, b) contacting the salt-containing polymer (SP) provided in step a) with an extractant (E) to obtain a desalinated polymer (DP) comprising the polyaryl ether, and a salt-containing extractant (SE) comprising the extractant (E) and the salt (S).

A substantially biobased prepolymer mixture including 31.80 to 67.95 percent biogenic carbon content by weight, wherein the mixture is a combination of: an isocyanate; and a cleaned biobased polyoxyalkylene glycol polyol, wherein the cleaned biobased polyoxyalkylene glycol polyol is completely primary hydroxyl-tipped or primary hydroxyl end-grouped, further wherein said cleaned biobased polyoxyalkylene glycol polyol is polymerized from 100% biobased ethylene oxide, further wherein the cleaned biobased polyoxyalkylene glycol polyol comprises less than 15 ppm sodium and potassium metals, and further wherein the cleaned biobased polyoxyalkylene glycol polyol comprises less than 0.5% water by weight.

A crosslinked biobased hydrophilic foam comprising a reaction product of: a cleaned biobased polyoxyalkylene glycol polyol with an ethylene oxide content of at least 40 mole percent, constituting 31.80 to 67.95 percent biogenic carbon content by weight, constituting less than 15 ppm combined sodium and potassium metals, and comprising less than 0.5% water by weight; an isocyanate, wherein the isocyanate and the cleaned biobased polyoxyalkylene glycol polyol are premixed to create a prepolymer mixture with the cleaned biobased polyoxyalkylene glycol polyol of the prepolymer mixture; and water, wherein the water is admixed with the prepolymer mixture to yield the crosslinked biobased hydrophilic foam.

A crosslinked biobased hydrophilic foam comprising a reaction product of: a cleaned biobased polyoxyalkylene glycol polyol with an ethylene oxide content of at least 40 mole percent, constituting 31.80 to 67.95 percent biogenic carbon content by weight, constituting less than 15 ppm combined sodium and potassium metals, and comprising less than 0.5% water by weight; an isocyanate, wherein the isocyanate and the cleaned biobased polyoxyalkylene glycol polyol are premixed to create a prepolymer mixture with the cleaned biobased polyoxyalkylene glycol polyol of the prepolymer mixture; and water, wherein the water is admixed with the prepolymer mixture to yield the crosslinked biobased hydrophilic foam.

The present invention generally relates to a powder comprising a PEEK-PEoEK copolymer, wherein the PEEK-PEoEK copolymer having R.sub.PEEK and R.sub.PEoEK repeat units in a molar ratio R.sub.PEEK/R.sub.PEoEK ranging from 95/5 to 5/95. The present invention also relates to a method of preparing the powder, as well as to the uses of the powder for coating, compression molding and to prepare a three-dimensional (3D) object.

The present invention generally relates to a powder comprising a PEEK-PEoEK copolymer, wherein the PEEK-PEoEK copolymer having R.sub.PEEK and R.sub.PEoEK repeat units in a molar ratio R.sub.PEEK/R.sub.PEoEK ranging from 95/5 to 5/95. The present invention also relates to a method of preparing the powder, as well as to the uses of the powder for coating, compression molding and to prepare a three-dimensional (3D) object.

An object of the present invention is to provide a polyphenylene ether melt extrusion formed body which can be obtained by melt forming without mixing other resin components and has excellent properties such as mechanical strength, and a method for producing the same. The present invention relates to a polyphenylene ether melt extrusion formed body comprising a polyphenylene ether component which has a rearrangement structure having a continuous structure bonded at an ortho-position in a repeating unit continuously bonded at a para-position.