The present invention relates to an apparatus (1) for the electroless metallization of a target surface of at least one workpiece (5), having a vessel (10) to accommodate a metallization solution having an inlet (15) and an outlet (16) for the metallization solution, and a holder (20) for accommodating the at least one workpiece (5) and can be arranged within the vessel (10), wherein at least one diffuser plate (30) is provided between the at least one inlet (15) and the holder (20) and has a multitude of diffuser openings (35) spaced apart in a plane of a plate (E), and wherein a movement device (40) is provided, which can move the diffuser plate (30) in at least one spatial direction in the vessel (10). The present invention further relates to a method for the electroless metallization of the target surface of the at least one workpiece (5).

The present invention relates to an apparatus (1) for the electroless metallization of a target surface of at least one workpiece (5), having a vessel (10) to accommodate a metallization solution having an inlet (15) and an outlet (16) for the metallization solution, and a holder (20) for accommodating the at least one workpiece (5) and can be arranged within the vessel (10), wherein at least one diffuser plate (30) is provided between the at least one inlet (15) and the holder (20) and has a multitude of diffuser openings (35) spaced apart in a plane of a plate (E), and wherein a movement device (40) is provided, which can move the diffuser plate (30) in at least one spatial direction in the vessel (10). The present invention further relates to a method for the electroless metallization of the target surface of the at least one workpiece (5).

A process of forming a thin film photoactive layer of an optoelectronic device comprising: providing a substrate having a surface comprising or coated with a metal M selected from at least one of Pb, Sn, Ge, Si, Ti, Bi, or In; and converting the metal surface or metal coating of the substrate to a perovskite layer.

A process of forming a thin film photoactive layer of an optoelectronic device comprising: providing a substrate having a surface comprising or coated with a metal M selected from at least one of Pb, Sn, Ge, Si, Ti, Bi, or In; and converting the metal surface or metal coating of the substrate to a perovskite layer.

A Magnetic Resonance Imaging (MRI) enhancement agent includes a plurality of particles, each particle including: a metal core; a dielectric shell disposed on the metal core comprising at least one MRI contrast agent; and a metal shell disposed on the exterior surface of the dielectric shell that encapsulates the dielectric shell.

A Magnetic Resonance Imaging (MRI) enhancement agent includes a plurality of particles, each particle including: a metal core; a dielectric shell disposed on the metal core comprising at least one MRI contrast agent; and a metal shell disposed on the exterior surface of the dielectric shell that encapsulates the dielectric shell.

The present disclosure is related to jars and containers and, more particularly, to the manufacture of readily recyclable jars and containers.

An exemplary jar is comprised of an aluminum base and a first aluminum inner cup provided with a first cavity defined with the aluminum base. An outer thread is provided about an exterior surface of the aluminum base, and an aluminum lid with a second aluminum inner cup is provided within a second cavity defined within the aluminum lid. An inner thread mateable with the outer thread is provided about an interior surface of the second aluminum inner cup.

A method of manufacturing readily recyclable jars can comprise providing a primary metal material and optionally applying a precoating to the primary metal material. The primary metal material may be formed into a jar with mating threads and a lid with mating threads. The primary metal material may optionally be finished. A liner may optionally be inserted. The lid and jar are then assembled, and a plastic cup may optionally be installed.

A method produces a composite from a conductive structure, a carrier made of non-conductive carrier material made from thermosetting plastic, and at least one electronic component by laser radiation. The non-conductive carrier material having an additive, which is configured to subsequently form a catalytically active species in an electroless metallization bath by irradiation with the laser radiation. The method includes: forming the conductive structure being by irradiation using pulsed laser radiation having a pulse duration of less than 100 picoseconds and subsequent electroless metallization. A pulse repetition rate is set such that consecutive pulses of the pulsed laser radiation in an area of the additive to be activated or an additive area are diverted mutually overlapping onto the additive or the additive area.

A method produces a composite from a conductive structure, a carrier made of non-conductive carrier material made from thermosetting plastic, and at least one electronic component by laser radiation. The non-conductive carrier material having an additive, which is configured to subsequently form a catalytically active species in an electroless metallization bath by irradiation with the laser radiation. The method includes: forming the conductive structure being by irradiation using pulsed laser radiation having a pulse duration of less than 100 picoseconds and subsequent electroless metallization. A pulse repetition rate is set such that consecutive pulses of the pulsed laser radiation in an area of the additive to be activated or an additive area are diverted mutually overlapping onto the additive or the additive area.

Articles prepared by additive manufacturing of preforms that are coated by electrodeposition of nanolaminate materials, and methods of their production are described.