Abstract: A method of 3D printing in which a 3D product is built up layer by layer by jetting from print heads includes forming part of a 3D product by a functional binder jetting process; jetting one or more material in a 2D pattern to form a structure on said part; completing the formation of the 3D product by continuing the functional binder jetting process, so that said structure becomes embedded in said product. Functional binder jetting may include: providing a layer of a powder bed; jetting a functional binder onto selected parts of said layer, wherein said functional binder infiltrates into pores in the powder bed and locally fuses particles of the powder bed in situ; sequentially repeating applying a layer of powder on top and selectively jetting functional binder, multiple times, to provide a powder bed bonded at selected locations by printed functional binder.

Abstract: A method of 3D printing a metal or alloy product includes providing a layer of a powder bed which comprises a compound of a first metal, and optionally also said first metal in elemental form and/or optionally other elemental metal(s) which are suitable for alloying with said first metal; jetting a functional binder onto selected parts of said layer, wherein said functional binder infiltrates into pores in the powder bed, reacts with said compound of a first metal to form said first metal in elemental form, and locally fuses elemental metal particles of the powder bed in situ, sequentially repeating said steps of applying a layer of powder on top and selectively jetting functional binder, multiple times, to provide a powder bed bonded at selected locations by printed functional binder and; taking the resultant bound 3D structure out of the powder bed.

Abstract: A method of 3D printing comprises: providing a layer of a powder bed; jetting a functional binder onto selected parts of said layer, wherein said binder infiltrates into pores in the powder bed and locally fuses particles of the powder bed in situ; sequentially repeating said steps of applying a layer of powder on top and selectively jetting functional binder, multiple times, to provide a powder bed bonded at selected locations by printed functional binder; and taking the resultant bound 3D structure out of the powder bed.

Abstract: Coated beads made of a primary matrix material and containing a population of quantum dot nanoparticles. Each bead has a multi-layer surface coating. The layers can be two or more distinct surface coating materials. The surface coating materials may be inorganic materials and/or polymeric materials. A method of preparing such particles is also described. The coated beads are useful for composite materials for applications such as light-emitting devices.

Abstract: Disclosed herein are coated beads made of a primary matrix material and containing a population of quantum dot nanoparticles. Each bead has a multi-layer surface coating. The layers can be two or more distinct surface coating materials. The surface coating materials may be inorganic materials and/or polymeric materials. A method of preparing such particles is also described. The coated beads are useful for composite materials for applications such as light-emitting devices.

Abstract: Disclosed herein are coated beads made of a primary matrix material and containing a population of quantum dot nanoparticles. Each bead has a multi-layer surface coating. The layers can be two or more distinct surface coating materials. The surface coating materials may be inorganic materials and/or polymeric materials. A method of preparing such particles is also described. The coated beads are useful for composite materials for applications such as light-emitting devices.

Abstract: The present invention relates to a process for fabricating a quadrupole mass spectrometer (QMS) component, to a monolithic quadrupole mass spectrometer or a component thereof, to a quadrupole mass filter (QMF) or quadrupole ion trap (QIT) capable of generating a hyperbolic electric field and to a modular quadrupole mass spectrometer (QMS) assembly.

Abstract: The present invention relates to a process for fabricating a quadrupole mass spectrometer (QMS) component, to a monolithic quadrupole mass spectrometer or a component thereof, to a quadrupole mass filter (QMF) or quadrupole ion trap (QIT) capable of generating a hyperbolic electric field and to a modular quadrupole mass spectrometer (QMS) assembly.