The invention is directed towards enhanced systems and methods for employing a pulsed photon (or EM energy) source, such as but not limited to a laser, to electrically couple, bond, and/or affix the electrical contacts of a semiconductor device to the electrical contacts of another semiconductor devices. Full or partial rows of LEDs are electrically coupled, bonded, and/or affixed to a backplane of a display device. The LEDs may be μLEDs. The pulsed photon source is employed to irradiate the LEDs with scanning photon pulses. The EM radiation is absorbed by either the surfaces, bulk, substrate, the electrical contacts of the LED, and/or electrical contacts of the backplane to generate thermal energy that induces the bonding between the electrical contacts of the LEDs' electrical contacts and backplane's electrical contacts. The temporal and spatial profiles of the photon pulses, as well as a pulsing frequency and a scanning frequency of the photon source, are selected to control for adverse thermal effects.

A power module substrate with a Ag underlayer of the invention includes: a circuit layer that is formed on one surface of an insulating layer; and a Ag underlayer that is formed on the circuit layer, in which the Ag underlayer is composed of a glass layer that is formed on the circuit layer side and a Ag layer that is formed by lamination on the glass layer, and regarding the Ag underlayer, in a Raman spectrum obtained by a Raman spectroscopy with incident light made incident from a surface of the Ag layer on a side opposite to the glass layer, when a maximum value of intensity in a wavenumber range of 3,000 cm.sup.−1 to 4,000 cm.sup.−1 indicated by I.sub.A, and a maximum value of intensity in a wavenumber range of 450 cm.sup.−1 to 550 cm.sup.−1 is indicated by I.sub.B, I.sub.A/I.sub.B is 1.1 or greater.

A power module substrate with a Ag underlayer of the invention includes: a circuit layer that is formed on one surface of an insulating layer; and a Ag underlayer that is formed on the circuit layer, in which the Ag underlayer is composed of a glass layer that is formed on the circuit layer side and a Ag layer that is formed by lamination on the glass layer, and regarding the Ag underlayer, in a Raman spectrum obtained by a Raman spectroscopy with incident light made incident from a surface of the Ag layer on a side opposite to the glass layer, when a maximum value of intensity in a wavenumber range of 3,000 cm.sup.−1 to 4,000 cm.sup.−1 indicated by I.sub.A, and a maximum value of intensity in a wavenumber range of 450 cm.sup.−1 to 550 cm.sup.−1 is indicated by I.sub.B, I.sub.A/I.sub.B is 1.1 or greater.

A semiconductor device includes an insulation board, an electrode provided on the insulation board, a bonding layer provided on the electrode and made of a sintered body of metal particles having an average particle size of nano-order, and a semiconductor element bonded to the electrode via the bonding layer. A layer thickness of the bonding layer is greater than or equal to 220 μm and less than or equal to 700 μm.

A fingerprint sensor device and a method of making a fingerprint sensor device. As non-limiting examples, various aspects of this disclosure provide various fingerprint sensor devices, and methods of manufacturing thereof, that comprise a sensing area on a bottom side of a die without top side electrodes that senses fingerprints from the top side, and/or that comprise a sensor die directly electrically connected to conductive elements of a plate through which fingerprints are sensed.

In an embodiment, a method includes performing a first plasma deposition to form a buffer layer over a first side of a first integrated circuit device, the first integrated circuit device comprising a first substrate and a first interconnect structure; performing a second plasma deposition to form a first bonding layer over the buffer layer, wherein a plasma power applied during the second plasma deposition is greater than a plasma power applied during the first plasma deposition; planarizing the first bonding layer; forming a second bonding layer over a second substrate; pressing the second bonding layer onto the first bonding layer; and removing the first substrate.

An optoelectronic component includes a substrate, a connecting element applied on the substrate and a layer sequence that emits electromagnetic radiation. The layer sequence is applied on the connecting element. The connecting element includes at least one connecting material that has an oriented molecular configuration. The connecting element has at least one parameter that is anisotropic.

Disclosed herein is an electrical connecting structure having nano-twins copper, including a first substrate having a first nano-twins copper layer and a second substrate having a second nano-twins copper layer. The first nano-twins copper layer includes a plurality of first nano-twins copper grains. The second nano-twins copper layer includes a plurality of second nano-twins copper grains. The first nano-twins copper layer is joined with the second nano-twins copper layer. At least a portion of the first nano-twins copper grains extend into the second nano-twins copper layer, or at least a portion of the second nano-twins copper grains extend into the first nano-twins copper layer.

A method of manufacturing a substrate layered body includes: a step of applying a bonding material to the surface of at least one of a first substrate or a second substrate; a step of curing the bonding material applied on the surface to form a bonding layer having a reduced modulus at 23° C. of 10 GPa or less; and a step of bonding the first substrate and the second substrate via the bonding layer formed.

The invention is directed towards enhanced systems and methods for employing a pulsed photon (or EM energy) source, such as but not limited to a laser, to electrically couple, bond, and/or affix the electrical contacts of a semiconductor device to the electrical contacts of another semiconductor devices. Full or partial rows of LEDs are electrically coupled, bonded, and/or affixed to a backplane of a display device. The LEDs may be μLEDs. The pulsed photon source is employed to irradiate the LEDs with scanning photon pulses. The EM radiation is absorbed by either the surfaces, bulk, substrate, the electrical contacts of the LED, and/or electrical contacts of the backplane to generate thermal energy that induces the bonding between the electrical contacts of the LEDs' electrical contacts and backplane's electrical contacts. The temporal and spatial profiles of the photon pulses, as well as a pulsing frequency and a scanning frequency of the photon source, are selected to control for adverse thermal effects.