Abstract: An integrated circuit and methods for packaging the integrated circuit. In one example, a method for packaging an integrated circuit includes connecting input/output pads of a first integrated circuit die to terminals of a lead frame via palladium coated copper wires. An oxygen plasma is applied to the first integrated circuit die and the palladium coated copper wires. The first integrated circuit die and the palladium coated copper wires are encapsulated in a mold compound after application of the oxygen plasma.

Abstract: Methods of fabricating a thick oxide feature on a semiconductor wafer include forming a oxide layer having a thickness of at least six micrometers and depositing a photoresist layer on the oxide layer. The oxide layer has a first etch rate of X with a given etchant, the photoresist layer has a second etch rate of Y with the given etchant and the ratio of X:Y is less than 4:1. Prior to etching the photoresist layer and the oxide layer, the photoresist layer is patterned with a grayscale mask that creates a photoresist layer having a sidewall that forms an angle with the horizontal that is less than or equal to 10 degrees.

Abstract: A laminate embedded core and coil structure comprises a magnetic core embedded in a laminate structure that includes two types of laminates. A first laminate embeds the coils of the structure and a second laminate fills space between the magnetic core and the first laminate, as well as space below the magnetic core and lower surface of the first laminate. The first and second laminates form a laminate structure that protects and improves isolation of the magnetic components. Solder resist encloses the laminate structure, magnetic core and coils. The laminate embedded core and coil structure may be assembled on a transformer leadframe of various types using non-conductive paste.

Abstract: Isolator structures for an integrated circuit with reduced effective parasitic capacitance. Disclosed embodiments include an isolator structure with parallel conductive elements forming a capacitor or inductive transformer, overlying a semiconductor structure including a well region of a first conductivity type formed within an tank region of a second conductivity type. The tank region is surrounded by doped regions and a buried doped layer of the first conductivity type, forming a plurality of diodes in series to the substrate. The junction capacitances of the series diodes have the effect of reducing the parasitic capacitance apparent at the isolator.

Abstract: Isolator structures for an integrated circuit with reduced effective parasitic capacitance. Disclosed embodiments include an isolator structure with parallel conductive elements forming a capacitor or inductive transformer, overlying a semiconductor structure including a well region of a first conductivity type formed within an tank region of a second conductivity type. The tank region is surrounded by doped regions and a buried doped layer of the first conductivity type, forming a plurality of diodes in series to the substrate. The junction capacitances of the series diodes have the effect of reducing the parasitic capacitance apparent at the isolator.

Abstract: A semiconductor package includes a leadframe including a sensor coil between sensor coil leads and further including a plurality of die leads physically and electrically separated from the sensor coil, and a semiconductor die over the leadframe with die contacts electrically connected to the die leads. The semiconductor die includes a sensor operable to detect magnetic fields created by electrical current through the sensor coil, the semiconductor die operable to output a signal representative of the detected magnetic fields via the die leads. The semiconductor package further includes a dielectric underfill filling a gap between the sensor coil and the semiconductor die, and a dielectric mold compound covering the sensor coil and the dielectric underfill and at least partially covering the semiconductor die and the die leads.

Abstract: In examples, a semiconductor package comprises a first conductive terminal; a second conductive terminal; a conductive pathway coupling the first and second conductive terminals, the conductive pathway configured to generate a magnetic field; a semiconductor die including a circuit configured to detect the magnetic field; and first and second polyimide layers positioned between the conductive pathway and the semiconductor die.

Abstract: High voltage integrated circuit capacitors are disclosed. In an example arrangement, A capacitor structure includes a semiconductor substrate; a bottom plate having a conductive layer overlying the semiconductor substrate; a capacitor dielectric layer deposited overlying at least a portion of the bottom plate and having a first thickness greater than about 6 um in a first region; a sloped transition region in the capacitor dielectric at an edge of the first region, the sloped transition region having an upper surface with a slope of greater than 5 degrees from a horizontal plane and extending from the first region to a second region of the capacitor dielectric layer having a second thickness lower than the first thickness; and a top plate conductor formed overlying at least a portion of the capacitor dielectric layer in the first region. Methods and additional apparatus arrangements are disclosed.

Abstract: A method of fabricating an integrated circuit includes applying photoresist to a MESA dielectric layer of a semiconductor structure, to generate a photoresist layer. The method also includes exposing the photoresist layer with a grayscale mask, to generate an exposed photoresist layer. The photoresist exposed layer includes a thick photoresist pattern in a first region, a thin photoresist pattern in a second region where a height of the thin photoresist pattern is less than half a height of the thick photoresist pattern, and a gap region between the thick photoresist pattern and the thin photoresist pattern.

Abstract: An integrated circuit and methods for packaging the integrated circuit. In one example, a method for packaging an integrated circuit includes connecting input/output pads of a first integrated circuit die to terminals of a lead frame via palladium coated copper wires. An oxygen plasma is applied to the first integrated circuit die and the palladium coated copper wires. The first integrated circuit die and the palladium coated copper wires are encapsulated in a mold compound after application of the oxygen plasma.

Abstract: A microelectronic device contains a high voltage component having a high voltage node and a low voltage node. The high voltage node is isolated from the low voltage node by a main dielectric between the high voltage node and low voltage elements at a surface of the substrate of the microelectronic device. A lower-bandgap dielectric layer is disposed between the high voltage node and the main dielectric. The lower-bandgap dielectric layer contains at least one sub-layer with a bandgap energy less than a bandgap energy of the main dielectric. The lower-bandgap dielectric layer extends beyond the high voltage node continuously around the high voltage node. The lower-bandgap dielectric layer has an isolation break surrounding the high voltage node at a distance of at least twice the thickness of the lower-bandgap dielectric layer from the high voltage node.

Abstract: A method and structure suitable for, e.g., improving high voltage breakdown reliability of a microelectronic device such as a capacitor usable for galvanic isolation of two circuits. A first dielectric layer has a first dielectric constant located over a semiconductor substrate. A metal structure located over the first dielectric layer has a side surface. A second dielectric layer having a second different dielectric constant is located adjacent the metal structure. A dielectric structure located between the side surface of the metal structure and the second dielectric layer has the first dielectric constant.

Abstract: In some examples, a multi-chip module (MCM), comprises a first and a second die-attach pad (DAP); a first die comprising a first set of microelectronic devices; a second die comprising a first capacitor and a second capacitor; and a third die comprising a second set of microelectronic devices, where the first and second dies are positioned on the first DAP, and the third die is positioned on the second DAP. The first set of microelectronic devices couples to the first capacitor via a first inter-die connection and the second set of microelectronic devices couples to the second capacitor via a second inter-die connection.

Abstract: A method of fabricating an integrated circuit includes applying photoresist to a MESA dielectric layer of a semiconductor structure, to generate a photoresist layer. The method also includes exposing the photoresist layer with a grayscale mask, to generate an exposed photoresist layer. The photoresist exposed layer includes a thick photoresist pattern in a first region, a thin photoresist pattern in a second region where a height of the thin photoresist pattern is less than half a height of the thick photoresist pattern, and a gap region between the thick photoresist pattern and the thin photoresist pattern.

Abstract: An integrated circuit package and methods for packaging an integrated circuit. In one example, a method for packaging an integrated circuit includes connecting input/output pads of a first die to terminals of a lead frame via palladium coated copper wires. An oxygen plasma is applied to the first die and the palladium coated copper wires. The first die and the palladium coated copper wires are encapsulated in a mold compound after application of the oxygen plasma.

Abstract: A packaged multichip device includes a first IC die with an isolation capacitor utilizing a top metal layer as its top plate and a lower metal layer as its bottom plate. A second IC die has a second isolation capacitor utilizing its top metal layer as its top plate and a lower metal layer as its bottom plate. A first bondwire end is coupled to one top plate and a second bondwire end is coupled to the other top plate. The second bondwire end includes a stitch bond including a wire approach angle not normal to the top plate it is bonded to and is placed so that the stitch bond's center is positioned at least 5% further from an edge of this top plate on a bondwire crossover side compared to a distance of the stitch bond's center from the side opposite the bondwire crossover side.

Abstract: A method and structure suitable for, e.g., improving high voltage breakdown reliability of a microelectronic device such as a capacitor usable for galvanic isolation of two circuits. A first dielectric layer has a first dielectric constant located over a semiconductor substrate. A metal structure located over the first dielectric layer has a side surface. A second dielectric layer having a second different dielectric constant is located adjacent the metal structure. A dielectric structure located between the side surface of the metal structure and the second dielectric layer has the first dielectric constant.

Abstract: A method and structure suitable for, e.g., improving high voltage breakdown reliability of a microelectronic device such as a capacitor usable for galvanic isolation of two circuits. A metal plate having a top surface and a side surface is located over a first dielectric layer. A second dielectric layer of a second different material is located over the first metal plate. A dielectric structure of the first material is located over the side surface of the metal plate and over the surface of the first dielectric layer.

Abstract: A packaged multichip device includes a first IC die with an isolation capacitor utilizing a top metal layer as its top plate and a lower metal layer as its bottom plate. A second IC die has a second isolation capacitor utilizing its top metal layer as its top plate and a lower metal layer as its bottom plate. A first bondwire end is coupled to one top plate and a second bondwire end is coupled to the other top plate. The second bondwire end includes a stitch bond including a wire approach angle not normal to the top plate it is bonded to and is placed so that the stitch bond's center is positioned at least 5% further from an edge of this top plate on a bondwire crossover side compared to a distance of the stitch bond's center from the side opposite the bondwire crossover side.

Abstract: An integrated circuit with a micro inductor or with a micro transformer with a magnetic core. A process of forming an integrated circuit with a micro inductor with a magnetic core. A process of forming an integrated circuit with a micro transformer with a magnetic core.