Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

A method of forming a micro-structure involves forming a multi-layered structure including i) an oxidizable material layer on a substrate and ii) another oxidizable material layer on the oxidizable material layer. The oxidizable material layer is formed of an oxidizable material having an expansion coefficient, during oxidation, that is more than 1. The method further involves forming a template, including a plurality of pores, from the other oxidizable material layer, and growing a nano-pillar inside each pore. The nano-pillar has a predefined length that terminates at an end. A portion of the template is selectively removed to form a substantially even plane that is oriented in a position opposed to the substrate. A material is deposited on at least a portion of the plane to form a film layer thereon, and the remaining portion of the template is selectively removed to expose the nano-pillars.

An inkjet-based process for programmable deposition of thin films of a user-defined profile. Drops of a pre-cursor liquid organic material are dispensed at various locations on a substrate by a multi-jet. A superstrate is held in a roll-to-roll configuration such that a first contact of the drops is made by a front side of the superstrate thereby initiating a liquid front that spreads outward merging with the drops to form a contiguous film captured between the substrate and the superstrate. A non-equilibrium transient state of the superstrate, the contiguous film and the substrate then occurs after a duration of time. The contiguous film is then cured to crosslink it into a polymer. The superstrate is then separated from the polymer thereby leaving a polymer film on the substrate. In such a manner, non-uniform films can be formed without significant material wastage in an inexpensive manner.

A method for producing micromechanical components is provided. A liquid starting material which can be cured by means of irradiation is applied onto a substrate. A partial volume of the starting material is cured by means of a local irradiation process using a first radiation source in order to produce at least one three-dimensional structure. The three-dimensional structure delimits at least one closed cavity in which at least one part of the liquid starting material is enclosed. Alternatively or in addition, a micromechanical component is provided that contains a liquid starting material, which is partly cured by means of irradiation, and at least one cavity in which the liquid starting material is enclosed.

A device and method utilizes interconnecting layers separated by an insulating layer. A layered structure comprises a first and a second layer of electrically conductive material, and a third layer of electrically insulating material between them. A via trench is fabricated that extends from the second layer through the third layer into the first layer, a surface on the first layer of electrically conductive material forming a bottom surface of the via trench. An ink-jetting set-up for a mixture of liquid carrier and nanoparticles of conductive material is formed, and a specific process period is determined. Capillary flow of nanoparticles to peripheral edges of an ink-jetted blob of said mixture is induced. The mixture is ink-jetted into a blob on the via trench; the layered structure is heated to evaporate the liquid carrier. The interconnection element is higher at a certain point than between opposing side walls.

A method for a capacitive micromachined ultrasound transducer (cMUT) is provided. The method grows and patterns a diffusion barrier layer over a surface of a base layer. The diffusion barrier layer have different areas that allow different levels of diffusion penetration. A diffusion process is performed over the diffusion barrier layer such that a diffusion reactivated material reaches different depths into the base layer below the different areas. A anchor is formed using the diffusion reactivated material. The anchor has a lower portion below a major surface of the base layer and an upper portion above the major surface of the base layer. A cover layer is placed over the anchor and the base layer. At least one of the cover layer and the base layer includes a flexible layer, such that the cMUT electrodes are movable relative to each other to cause a change of the gap width.

Embodiments of the present invention provide systems and methods for depositing materials on either side of a freestanding film using selectively thermally-assisted chemical vapor deposition (STA-CVD), and structures formed using same. A freestanding film, which is suspended over a cavity defined in a substrate, is exposed to a fluidic CVD precursor that reacts to form a solid material when exposed to heat. The freestanding film is then selectively heated in the presence of the precursor. The CVD precursor preferentially deposits on the surface(s) of the freestanding film.

Methods, devices and systems for patterning of substrates using charged particle beams without photomasks and without a resist layer. Material can be removed from a substrate, as directed by a design layout database, localized to positions targeted by multiple, matched charged particle beams. Reducing the number of process steps, and eliminating lithography steps, in localized material removal has the dual benefit of reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Furthermore, highly localized, precision material removal allows for controlled variation of removal rate and enables creation of 3D structures or profiles. Local gas injectors and detectors, and local photon injectors and detectors, are local to corresponding ones of the columns, and can be used to facilitate rapid, accurate, targeted substrate processing.

In a method of printing a transferable component, a stamp including an elastomeric post having three-dimensional relief features protruding from a surface thereof is pressed against a component on a donor substrate with a first pressure that is sufficient to mechanically deform the relief features and a region of the post between the relief features to contact the component over a first contact area. The stamp is retracted from the donor substrate such that the component is adhered to the stamp. The stamp including the component adhered thereto is pressed against a receiving substrate with a second pressure that is less than the first pressure to contact the component over a second contact area that is smaller than the first contact area. The stamp is then retracted from the receiving substrate to delaminate the component from the stamp and print the component onto the receiving substrate. Related apparatus and stamps are also discussed.