Abstract: A semiconductor device may include an isolation layer, gate electrodes, an insulating interlayer, an impurity region, a capping layer and a plug. The isolation layer may be formed in the substrate. The gate electrodes may be formed on the substrate. The insulating interlayer may be formed on the gate electrodes. The insulating interlayer may have a contact hole between the gate electrodes. The impurity region may be in the substrate exposed through the contact hole. The capping layer may be on the impurity region. The plug may be on the capping layer. Thus, the impurities may not be lost from the impurity region.

Abstract: Provided are methods of forming a low temperature deposition layer and methods of manufacturing a semiconductor device using the same. The method of manufacturing a semiconductor device comprises forming a mask layer exposing a gate pattern on a substrate on which the gate pattern is formed, forming a sacrifice layer on the mask layer and on a substrate not covered by the mask layer using a plasma ion immersion implantation and deposition (PIIID), and doping a substrate adjacent to both sidewalls of the gate pattern with an impurity.

Abstract: Methods of manufacturing a semiconductor device, which can reduce hot electron induced punchthrough (HEIP) and/or improve the operating characteristics of the device include selectively forming an oxynitride layer in a device isolation layer according to the characteristics of transistors isolated by the device isolation layer. The methods include forming first trenches and second trenches on a substrate, forming an oxide layer on the surfaces of the first trenches and the second trenches, selectively forming an oxynitride layer on the second trenches by using plasma ion immersion implantation (PIII), and forming a buried insulating layer in the first trenches and the second trenches. The buried insulating layer may be planarized to form a first device isolation layer in the first trenches and a second device isolation layer in the second trenches.

Abstract: A semiconductor device is manufactured by forming trenches in a substrate and selectively performing Plasma Ion Immersion Implantation and Deposition (PIIID) on a subset of the trenches in the substrate. The PIIID may be performed on only a portion of a surface of at least one of the trenches in the substrate. Semiconductor devices can include a semiconductor substrate having first, second and third trenches therein, and an oxide liner layer that fully lines the first trenches, that does not line the second trenches and that partially lines the third trenches.

Abstract: In plasma ion doping operations, a wafer is positioned on a susceptor within a reaction chamber and an ion doping source gas is plasmalyzed in an upper part of the reaction chamber above a major surface of the wafer while supplying a control gas into the reaction chamber in a lower part of the reaction chamber opposite the major surface of the wafer to thereby dope ions into the major surface of the wafer. The ion doping source gas may comprise at least one halide gas, and the control gas may comprise at least one depositing gas, such as a silane gas. In further embodiments, a diluent gas, such as an inert gas, may be supplied to the reaction chamber while supplying the ion doping source gas and the control gas. Related plasma ion doping apparatus are described.

Abstract: Some embodiments of the present invention provide semiconductor devices including a gate trench in an active region of a semiconductor substrate and a gate electrode in the gate trench. A low-concentration impurity region is provided in the active region adjacent to a sidewall of the gate trench. A high-concentration impurity region is provided between the low-concentration impurity region and the sidewall of the gate trench and along the sidewall of the gate trench. Related methods of fabricating semiconductor devices are also provided herein.

Abstract: A method of forming a field effect transistor includes forming a vertical channel protruding from a substrate including a source/drain region junction between the vertical channel and the substrate, and forming an insulating layer extending on a side wall of the vertical channel toward the substrate to beyond the source/drain region junction. The method may also include forming a nitride layer extending on the side wall away from the substrate to beyond the insulating layer, forming a second insulating layer extending on the side wall that is separated from the channel by the nitride layer, and forming a gate electrode extending on the side wall toward the substrate to beyond the source/drain region junction.

Abstract: A plasma doping method includes providing a substrate including a layer to be doped inside a chamber, and supplying first and second source gases to the layer to achieve a desired doping concentration. The first source gas includes a component configured to increase a thickness of the layer, and the second gas includes a component configured to reduce a thickness of the layer.

Abstract: A method of forming a semiconductor device includes forming a three-dimensional structure formed of a semiconductor on a semiconductor substrate, and isotropically doping the three-dimensional structure by performing a plasma doping process using a first source gas and a second source gas. The first source gas includes n-type or p-type impurity elements, and the second source gas includes a dilution element regardless of the electrical characteristic of a doped region.

Abstract: Provided are a fin field effect transistor (FinFET) with recess source/drain regions, and a method of forming the same. One example embodiment may provide a semiconductor device including a fin provided on a substrate and extending in a first direction, the fin including a stepped portion, and a gate electrode extending in a second direction crossing the first direction, and provided on a top surface and side surfaces of the stepped portion of the fin.

Abstract: Provided is a double gate field effect transistor and a method of manufacturing the same. The method of manufacturing the double gate field effect transistor includes forming as many fins as required by etching a silicon substrate, masking the resultant product by an insulating material such as silicon nitride, forming trench regions for device isolation and STI film by using the silicon nitride mask, forming gate oxide films on both faces of the fins after removing the hard mask, and forming a gate line. As such, unnecessary channel formation under the silicon oxide film, when a voltage higher than a threshold voltage is applied to the substrate, is prevented by forming a thick silicon oxide film on the substrate on which no protruding fins are formed.

Abstract: A semiconductor device may include a semiconductor substrate, first and second source/drain regions on a surface of the semiconductor substrate, and a channel region on the surface of the semiconductor substrate with the channel region between the first and second source/drain regions. An insulating layer pattern may be on the channel region, a first conductive layer pattern may be on the insulating layer, and a second conductive layer pattern may be on the first conductive layer pattern. The insulating layer pattern may be between the first conductive layer pattern and the channel region, and the first conductive layer pattern may include boron doped polysilicon with a surface portion having an accumulation of silicon boronide. The first conductive layer pattern may be between the second conductive layer pattern and the insulating layer pattern, and the second conductive layer pattern may include tungsten. Related methods are also discussed.

Abstract: A method of forming a field effect transistor includes forming a vertical channel protruding from a substrate including a source/drain region junction between the vertical channel and the substrate, and forming an insulating layer extending on a side wall of the vertical channel toward the substrate to beyond the source/drain region junction. The method may also include forming a nitride layer extending on the side wall away from the substrate to beyond the insulating layer, forming a second insulating layer extending on the side wall that is separated from the channel by the nitride layer, and forming a gate electrode extending on the side wall toward the substrate to beyond the source/drain region junction.

Abstract: Methods of forming an integrated circuit memory device include forming a dielectric layer on a substrate and forming a charge storing layer on an upper surface of the dielectric layer using a plasma doping process with a remaining portion of the dielectric layer under the charge storing layer defining a tunnel dielectric layer. A blocking dielectric layer is formed on the charge storing layer and a gate electrode layer is formed on the blocking dielectric layer.

Abstract: A method of forming a semiconductor device includes forming a three-dimensional structure formed of a semiconductor on a semiconductor substrate, and isotropically doping the three-dimensional structure by performing a plasma doping process using a first source gas and a second source gas. The first source gas includes n-type or p-type impurity elements, and the second source gas includes a dilution element regardless of the electrical characteristic of a doped region.

Abstract: A field effect transistor can include a vertical channel protruding from a substrate including a source/drain region junction between the vertical channel and the substrate, and an insulating layer extending on a side wall of the vertical channel toward the substrate to beyond the source/drain region junction. The transistor can also include a nitride layer extending on the side wall away from the substrate to beyond the insulating layer, a second insulating layer extending on the side wall that is separated from the channel by the nitride layer, and a gate electrode extending on the side wall toward the substrate to beyond the source/drain region junction. Related methods are also disclosed.

Abstract: There are provided a high-voltage transistor and a method of forming the same. A channel region of the high-voltage transistor includes a first region and a second region. The first region has high impurity concentration that is higher than that of the second region. In addition, the first region may be in contact with the isolation layer. Thus, it is possible to enhance leakage current characteristics of the high-voltage transistor.

Abstract: Provided is a double gate field effect transistor and a method of manufacturing the same. The method of manufacturing the double gate field effect transistor comprises forming as many fins as required by etching a silicon substrate, masking the resultant product by an insulating material such as silicon nitride, forming trench regions for device isolation and STI film by using the silicon nitride mask, forming gate oxide films on both faces of the fins after removing the hard mask, and forming a gate line. As such, unnecessary channel formation under the silicon oxide film, when a voltage higher than a threshold voltage is applied to the substrate, is prevented by forming a thick silicon oxide film on the substrate on which no protruding fins are formed.

Abstract: Provided is a double gate field effect transistor and a method of manufacturing the same. The method of manufacturing the double gate field effect transistor comprises forming as many fins as required by etching a silicon substrate, masking the resultant product by an insulating material such as silicon nitride, forming trench regions for device isolation and STI film by using the silicon nitride mask, forming gate oxide films on both faces of the fins after removing the hard mask, and forming a gate line. As such, unnecessary channel formation under the silicon oxide film, when a voltage higher than a threshold voltage is applied to the substrate, is prevented by forming a thick silicon oxide film on the substrate on which no protruding fins are formed.

Abstract: A field effect transistor can include a vertical channel protruding from a substrate including a source/drain region junction between the vertical channel and the substrate, and an insulating layer extending on a side wall of the vertical channel toward the substrate to beyond the source/drain region junction. The transistor can also include a nitride layer extending on the side wall away from the substrate to beyond the insulating layer, a second insulating layer extending on the side wall that is separated from the channel by the nitride layer, and a gate electrode extending on the side wall toward the substrate to beyond the source/drain region junction. Related methods are also disclosed.