Provided is a semiconductor device provided with an IGBT, comprising: a semiconductor substrate having upper and lower surfaces, throughout which bulk donors are distributed; a hydrogen peak including a local maximum arranged 25 μm or more away from the lower surface of the semiconductor substrate in a depth direction, at which a hydrogen chemical concentration shows a local maximum value; an upper tail where the hydrogen chemical concentration decreases in a direction from the local maximum toward the upper surface; and a lower tail where the hydrogen chemical concentration decreases in a direction from the local maximum toward the lower surface more gradually than the upper tail; and a first high concentration region having a donor concentration higher than a bulk donor concentration and including a region extending for 4 μm or more in a direction from the local maximum of the hydrogen peak toward the upper surface.

A semiconductor device includes a semiconductor layer having a first surface and a second surface, an element structure formed on the first surface side of the semiconductor layer and including a first conductivity type first region and a second conductivity type second region in contact with the first region, a gate electrode opposing the second region with a gate insulating film therebetween, a first conductivity type third region formed in the semiconductor layer to be in contact with the second region, and a first electrode formed on the semiconductor layer and electrically connected to the first region and the second region, in which the element structure includes a first and a second element structure, the first element structure is separated from the second region in a direction along the first surface of the semiconductor layer, and includes a second conductivity type first column layer extending in a thickness direction.

A p-type semiconductor region is formed in a front surface side of an n-type semiconductor substrate. An n-type field stop (FS) region including protons as a donor is formed in a rear surface side of the semiconductor substrate. A concentration distribution of the donors in the FS region include first, second, third and fourth peaks in order from a front surface to the rear surface. Each of the peaks has a peak maximum point, and peak end points formed at both sides of the peak maximum point. The peak maximum points of the first and second peaks are higher than the peak maximum point of the third peak. The peak maximum point of the third peak is lower than the peak maximum point of the fourth peak.

A method of manufacturing a semiconductor device having an insulated gate bipolar transistor portion and a freewheeling diode portion. The method includes introducing an impurity to a rear surface of a semiconductor substrate, performing first heat treating to activate the impurity to form a field stop layer, performing a first irradiation to irradiate light ions from the rear surface of semiconductor substrate to form, in the semiconductor substrate, a first low-lifetime region, performing a second irradiation to irradiate the light ions from the rear surface of the semiconductor substrate to form, in the field stop layer, a second low-lifetime region, and performing second heat treating to reduce a density of defects generated in the field stop layer when the second irradiation is performed. Each of the first and second low-lifetime regions has a carrier lifetime thereof shorter than that of any region of the semiconductor device other than the first and second low-lifetime regions.

A semiconductor device has transistor portions and diode portions. The transistor portions have a semiconductor substrate of a first conductivity type, a first semiconductor region of a second conductivity type, second semiconductor regions of the first conductivity type, gate insulating films, gate electrodes, a first semiconductor layer of the first conductivity type, a third semiconductor region of the second conductivity type, a first electrode, and a second electrode. The diode portions have the semiconductor substrate, the first semiconductor region, the first semiconductor layer, a fourth semiconductor region of the first conductivity type, the first electrode, and the second electrode. The first semiconductor layer has a predetermined region, a depth of the predetermined region from a second main surface of the semiconductor substrate is greater than a depth of a region of the first semiconductor layer excluding the predetermined region, from the second main surface of the semiconductor substrate.

According to various embodiments, a method for processing a semiconductor region, wherein the semiconductor region comprises at least one precipitate, may include: forming a precipitate removal layer over the semiconductor region, wherein the precipitate removal layer may define an absorption temperature at which a chemical solubility of a constituent of the at least one precipitate is greater in the precipitate removal layer than in the semiconductor region; and heating the at least one precipitate above the absorption temperature.

Provided is a semiconductor device having an RC-IGBT structure, the semiconductor device comprising an FWD (Free Wheel Diode) region and an IGBT (Insulated Gate Bipolar Transistor) region. Provided is a semiconductor device comprising:

a semiconductor substrate; a transistor section formed on the semiconductor substrate; a diode section formed on the semiconductor substrate and including a lifetime killer at a front surface side of the semiconductor substrate;
a gate runner provided between the transistor section and the diode section and electrically connected to a gate of the transistor section.

Methods and systems for reducing electrical disturb effects between thyristor memory cells in a memory array are provided. Electrical disturb effects between cells are reduced by using a material having a reduced minority carrier lifetime as a cathode line that is embedded within the array. Disturb effects are also reduced by forming a potential well within a cathode line, or a one-sided potential barrier in a cathode line.

A semiconductor device includes a polycrystalline silicon part buried in a termination region of a silicon layer. The polycrystalline silicon part contacts the silicon layer, has a higher crystal grain density than the silicon layer, and includes a heavy metal. The silicon layer includes a drift layer located in a cell region and the termination region. The drift layer has a lower first-conductivity-type impurity concentration than a silicon substrate. The drift layer includes a same element of heavy metal as the heavy metal included in the polycrystalline silicon part.

A semiconductor device includes an N-type silicon carbide layer, a P-type region, an N-type source region, a P-type contact region, a gate insulating film, a gate electrode, and a source electrode on the front surface side of an N-type silicon carbide substrate. A drain electrode is located on the back surface of the N-type silicon carbide substrate. A life time killer introduction region is located along an entire interface of the N-type silicon carbide layer and the bottom face of the P-type region. The life time killer is introduced by implanting helium or protons from the back surface side of the N-type silicon carbide substrate after forming a surface structure of an element on the front surface side of the N-type silicon carbide substrate and before forming the drain electrode.