摘要:
A three-dimensional (3D) CMOS image sensor (CIS) that sufficiently absorbs incident infrared-rays (IRs) and includes an infrared-ray (IR) receiving unit formed in a thin epitaxial film, thereby being easily manufactured using a conventional CIS process, a sensor system including the 3D CIS, and a method of manufacturing the 3D CIS, the 3D CIS including an IR receiving part absorbing IRs incident thereto by repetitive reflection to produce electron-hole pairs (EHPs); and an electrode part formed on the IR receiving part and collecting electrons produced by applying a predetermined voltage thereto.
摘要:
A three-dimensional (3D) CMOS image sensor (CIS) that sufficiently absorbs incident infrared-rays (IRs) and includes an infrared-ray (IR) receiving unit formed in a thin epitaxial film, thereby being easily manufactured using a conventional CIS process, a sensor system including the 3D CIS, and a method of manufacturing the 3D CIS, the 3D CIS including an IR receiving part absorbing IRs incident thereto by repetitive reflection to produce electron-hole pairs (EHPs); and an electrode part formed on the IR receiving part and collecting electrons produced by applying a predetermined voltage thereto.
摘要:
Methods of forming a gate structure for an integrated circuit memory device include forming a metal oxide dielectric layer on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the dielectric layer to form a charge storing region in the dielectric layer with a tunnel dielectric layer under the charge storing region and a capping dielectric layer above the charge storing region. The substrate including the metal oxide dielectric layer is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region. A gate electrode layer is formed on the dielectric layer.
摘要:
Methods of forming a gate structure for an integrated circuit memory device include forming a first dielectric layer having a dielectric constant of under 7 on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the first dielectric layer to form a charge storing region in the first dielectric layer with a tunnel dielectric layer under the charge storing region. A metal oxide second dielectric layer is formed on the first dielectric layer, the second dielectric layer. The substrate including the first and second dielectric layers is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region and a gate electrode layer is formed on the second dielectric layer. Gate structures for integrated circuit devices and memory cells are also provided.
摘要:
Methods of forming a gate structure for an integrated circuit memory device include forming a first dielectric layer having a dielectric constant of under 7 on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the first dielectric layer to form a charge storing region in the first dielectric layer with a tunnel dielectric layer under the charge storing region. A metal oxide second dielectric layer is formed on the first dielectric layer, the second dielectric layer. The substrate including the first and second dielectric layers is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region and a gate electrode layer is formed on the second dielectric layer. Gate structures for integrated circuit devices and memory cells are also provided.
摘要:
Methods of forming a gate structure for an integrated circuit memory device include forming a first dielectric layer having a dielectric constant of under 7 on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the first dielectric layer to form a charge storing region in the first dielectric layer with a tunnel dielectric layer under the charge storing region. A metal oxide second dielectric layer is formed on the first dielectric layer, the second dielectric layer. The substrate including the first and second dielectric layers is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region and a gate electrode layer is formed on the second dielectric layer. Gate structures for integrated circuit devices and memory cells are also provided.
摘要:
Methods of forming a gate structure for an integrated circuit memory device include forming a first dielectric layer having a dielectric constant of under 7 on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the first dielectric layer to form a charge storing region in the first dielectric layer with a tunnel dielectric layer under the charge storing region. A metal oxide second dielectric layer is formed on the first dielectric layer, the second dielectric layer. The substrate including the first and second dielectric layers is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region and a gate electrode layer is formed on the second dielectric layer. Gate structures for integrated circuit devices and memory cells are also provided.
摘要:
Embodiments of the present invention provide methods for measuring a wafer surface. A portion of the wafer surface is measured using a particle counter to provide first measurements corresponding to a plurality of points on the wafer surface. A selected area of the wafer surface including one of the plurality of points is measured using an atomic force microscope (AFM) to provide a microroughness measurement of the selected area. The selected area is a localized area of the portion of the wafer surface measured using the particle counter. The first measurements and the microroughness measurement are provided as a measurement of the wafer surface. The portion measured using a particle counter may, for example, be substantially the entire wafer surface.
摘要:
With a view to optimizing the donor killing process performed in the semiconductor wafer fabricating process, a heat-treating operation is performed in a thermal furnace above at least 900 .degree. C. for a predetermined time so that growth of the initial oxygen precipitates, induced into the crystal lattices during single-crystal growth, is suppressed. Thus, the oxygen precipitates are easily suppressed, irrespective of the concentration of the initial oxygen, so that the yield of the semiconductor device is improved
摘要:
A wafer packaging method in which a wafer is placed into a packaging bag that is sealed before the concentration of sulphuric oxide on the surface of the wafer reaches 3×1012 atoms/cm2. The placing of the wafer in the wafer packaging bag is carried out in a substantially clean environment
摘要翻译:一种晶片封装方法,其中将晶片放置在在晶片表面上的硫酸氧化物的浓度达到3×10 12原子/ cm 2之前密封的包装袋中。 在晶片包装袋中放置晶片在基本上清洁的环境中进行