Abstract: A device and a method for bonding elements are described. A first solder ball is produced on a main surface of a first element. A second solder ball is produced on a main surface of a second element. Contact is provided between the first solder ball and the second solder ball. The first and second elements are bonded by applying a reflow act whereby the solder balls melt and form a joined solder ball structure. Prior to the bonding, the first solder ball is laterally embedded in a first layer of non-conductive material and the second solder ball is laterally embedded in a second layer of non-conductive material, such that the upper part of the first solder ball and upper part of the second solder ball are not covered by the non-conductive material. A third solder volume is applied on one or both of the embedded first or second solder balls, prior to the bonding.

Abstract: A device and a method are presented for generating an intermitted oscillating signal comprising a plurality of oscillating portions separated from each other in time. The device and method are suited for communication systems, in particular for Ultra-Wide Bandwidth (UWB) applications. The device comprises a variable oscillator for generating the oscillating portions; switching circuitry for switching on/switching off the variable oscillator at the beginning/end of each oscillating portion; and circuitry for setting initial conditions in the variable oscillator to impose a predefined transient and a characterizing frequency upon each start-up.

Abstract: A tuneable film bulk acoustic resonator (FBAR) device. The FBAR device includes a bottom electrode, a top electrode and a piezoelectric layer in between the bottom electrode and the top electrode. The piezoelectric layer has a first overlap with the bottom electrode, where the first overlap is defined by a projection of the piezoelectric layer onto the bottom electrode in a direction substantially perpendicular to a plane of the bottom electrode. The FBAR device also includes a first dielectric layer in between the piezoelectric layer and the bottom electrode and a mechanism for reversibly varying an internal impedance of the device, so as to tune a resonant frequency of the FBAR device.

Abstract: A method of manufacturing a semiconductor device comprising a dual gate field effect transistor is disclosed, in which method a semiconductor body with a surface and of silicon is provided with a source region and a drain region of a first conductivity type and with a channel region of a second conductivity type, opposite to the first conductivity type, between the source region and the drain region and with a first gate region separated from the channel region by a first gate dielectric and situated on one side of the channel region and with a second gate region separated from the channel region by a second gate dielectric and situated on an opposite side of the channel region, and wherein both gate regions are formed within a trench formed in the semiconductor body.

Abstract: A semiconductor device is disclosed that comprises a fully silicided electrode formed of an alloy of a semiconductor material and a metal, a workfunction modulating element for modulating a workfunction of the alloy, and a dielectric in contact with the fully silicided electrode. At least a part of the dielectric which is in direct contact with the fully silicided electrode comprises a stopping material for substantially preventing the workfunction modulating element from implantation into and/or diffusing towards the dielectric. A method for forming such a semiconductor device is also disclosed.

Abstract: A method for selective deposition of self-assembled monolayers to the surface of a substrate for use as a diffusion barrier layer in interconnect structures is provided comprising the steps of depositing a first self-assembled monolayer to said surface, depositing a second self-assembled monolayer to the non-covered parts of said surface and subsequently heating said substrate to remove the first self-assembled monolayer. The method of selective deposition of self-assembled monolayers is applied for the use as diffusion barrier layers in a (dual) damascene structure for integrated circuits.

Abstract: An interconnect module and a method of manufacturing the same. The method of making an interconnect module on a substrate comprises forming an interconnect section on the substrate. The interconnect section comprises at least two metal interconnect layers separated by a dielectric layer. The method further comprises forming a passive device on the substrate at a location laterally adjacent to the interconnect section. The passive device comprises at least one moveable element comprising a metal layer. The method further comprises forming the metal layer and one of the at least two metal interconnect layers from substantially the same material.

Abstract: A method for selective deposition of self-assembled monolayers to the surface of a substrate for use as a diffusion barrier layer in interconnect structures is provided comprising the steps of depositing a first self-assembled monolayer to said surface, depositing a second self-assembled monolayer to the non-covered parts of said surface and subsequently heating said substrate to remove the first self-assembled monolayer. The method of selective deposition of self-assembled monolayers is applied for the use as diffusion barrier layers in a (dual) damascene structure for integrated circuits.

Abstract: A method of manufacturing a semiconductor device with at least a first dielectric material and a second dielectric material is disclosed. In one aspect, the method comprises providing a first dielectric material on a substrate. The method further comprises providing a patterned sacrificial layer covering the first dielectric material in at least a first region of the substrate. The method further comprises providing a second dielectric material covering the patterned sacrificial layer in the first region and covering the first dielectric material in at least a second region, the second region being different from the first region. The method further comprises patterning the second dielectric material such that the patterned second dielectric material covers the first dielectric material in the second region but not the patterned sacrificial layer in the first region. The method further comprises removing the patterned sacrificial material.

Abstract: The present disclosure is related to a method for determining time to failure characteristics of a microelectronics device. A test structure, being a parallel connection of a plurality of such on-chip interconnects, is provided. Measurements are performed on the test structure under test conditions for current density and temperature. The test structure is arranged such that failure of one of the on-chip interconnects within the parallel connection changes the test conditions for at least one of the other individual on-chip interconnects of the parallel connection. From these measurements, time to failure characteristics are determined, whereby the change in the test conditions is compensated for.

Abstract: A method is disclosed for the selective removal of rare earth based high-k materials such as rare earth scandate high-k materials (e.g. DyScO3) over silicon or silicon dioxide. As an example Dy and Sc comprising high-k materials are used as a high-k material in gate stacks of a semiconductor device. The selective removal and etch of this high-k material is very difficult since Dy and Sc (and their oxides) are difficult to etch. The etching could however be easily stopped on them. For patterning of the metal gates comprising TiN and TaN on top of rare earth based high-k layer a chlorine-containing gases (Cl2 and BCl3) can be used since titanium ant tantalum chlorides are volatile and reasonable selectivity to other material present on the wafer (Si, SiO2) can be obtained. The Dy and Sc chlorides are not volatile, but they are water soluble.

Abstract: A method is provided for the patterning of a stack comprising elements that do not form volatile compounds during conventional reactive ion etching. More specifically the element(s) are Lanthanide elements such as Ytterbium (Yb) and the patterning preferably relates to the dry etching of silicon and/or germanium comprising structures (e.g. gates) doped with a Lanthanide e.g. Ytterbium (Yb doped gates). In case the silicon and/or germanium comprising structure is a gate electrode the silicon and/or germanium is doped with a Lanthanide (e.g. Yb) for modeling the work function of a gate electrode.

Abstract: A method of manufacturing a semiconductor device with precision patterning is disclosed. A structure of a small dimension is created in a material, such as a semiconductor material, using a first and a second pattern, the patterns being identical but displaced over a distance with respect to each other. Two mask layers are used, wherein the first pattern is etched into the upper mask layer with a selective etch, and the second pattern is created on the upper mask layer or on the lower mask layer at locations where the upper mask layer has been removed. A part of the lower mask layer and/or the upper mask layer is etched according to the second pattern, resulting in a mask formed by remaining parts of the lower and upper mask layers, the mask having a structure with a dimension determined by a displacement of the second pattern with respect to the first pattern.

Abstract: A method for removing a resist layer from a substrate is described. The method for removing a resist layer from a substrate, wherein the resist layer comprises bulk resist contacting the substrate and a resist crust being present at the outer surface of the resist layer, includes providing at least locally a liquid organic solvent on the resist layer contacting the substrate, for which the bulk resist is soluble in the organic solvent and the resist crust is substantially insoluble in the organic solvent. The method further includes stripping the resist layer from the substrate by providing megasonic energy to the organic solvent, creating organic solvent cavitations for fracturing the resist crust, and dissolving the bulk resist in the organic solvent.

Abstract: A method and a device for transmission and/or reception of digital signals are disclosed. In one embodiment, the method comprises quantizing a source digital signal to generate with different quantizations at least a first and a second bit-stream, of which at least one bit-stream is generated by an embedded quantization, transmitting at least one of the at least first and second bit-streams and generating a dequantized digital signal from at least parts of one of the transmitted at least first and second bit streams, whereby if in the generation of the dequantized digital signal the parts of the at least first and second bit-streams are combined, the combined dequantized signal is generated by an embedded dequantizer having at least two quantization levels and having at least one quantization interval at each quantization level which is finer than quantization intervals for dequantizing any of the at least first and second bit-streams.

Abstract: A projection system comprising a light source is disclosed, wherein the light source comprises at least two light emitters arranged to be optically positionable alternately in a first position and a second position by an optical positioning means wherein said optical positioning means is arranged to change the light emission from said light emitters to a preferred optical path being said first position, a power source arranged to empower said light emitters, wherein the light emitter optically positioned in said first position is empowered by said power source and the light emitter optically positioned in said second position is not empowered.

Abstract: Tunnel field-effect transistors (TFETs) are regarded as successors of metal-oxide semiconductor field-effect transistors (MOSFETs), but silicon-based TFETs typically suffer from low on-currents, a drawback related to the large resistance of the tunnel barrier. To achieve higher on-currents a nanowire-based TFET with a germanium (Ge) tunnel barrier in an otherwise silicon (Si) channel is used. A nanowire is introduced such that the lattice mismatch between silicon and germanium does not result in a highly defective interface. A dynamic power reduction as well as a static power reduction can result, compared to conventional MOSFET configurations. Multiple layers of logic can therefore be envisioned with these nanowire Si/Ge TFETs resulting in ultra-high on-chip transistor densities.

Abstract: Tunnel field-effect transistors (TFETs) are regarded as successors of metal-oxide semiconductor field-effect transistors (MOSFETs), but silicon-based TFETs typically suffer from low on-currents, a drawback related to the large resistance of the tunnel barrier. To achieve higher on-currents an elongate monocrystalline nanostructure-based TFET with a heterostructure made of a different semiconducting material (e.g. germanium (Ge)) is used. An elongate monocrystalline nanostructure made of a different semiconducting material is introduced which acts as source (or alternatively drain) region of the TFET. The introduction of the heterosection is such that the lattice mismatch between silicon and germanium does not result in a highly defective interface. A dynamic power reduction as well as a static power reduction can result, compared to conventional MOSFET configurations.

Abstract: One inventive aspect relates a variable capacitor comprising first and second electrically conductive electrodes, arranged above a support structure and spaced apart from each other and defining the capacitance of the capacitor. At least one of the electrodes comprises at least one bendable portion. The bendable portion(s) are actuated by a DC voltage difference which is applied over the electrodes to vary the capacitance. In preferred embodiments, the support structure comprises a layer of higher permittivity than the atmosphere surrounding the electrodes and the electrodes configure as an interdigitated structure upon actuation. Also disclosed is a 2-mask process for producing such capacitors.

Abstract: A method for forming doped metal-semiconductor compound regions in a substrate is disclosed. In one aspect, a method for forming silicide regions in a substrate comprises partially regrowing an upper amorphous region on top of a crystalline part of the substrate, after having doped the upper amorphous region, to form a regrown region, thereby leaving a remaining upper amorphous region in between the regrown region and the major surface of the substrate. The remaining upper amorphous region is used for forming the metal-semiconductor compound.