Abstract: In a nonvolatile memory, the tunnel dielectric (150) has a surface in physical contact with the charge trapping dielectric (160) and also has a surface in physical contact with a semiconductor region providing the active area (120, 130, 140). Under the vacuum level, the bottom edge of the conduction band of the tunnel dielectric (150) is higher at the surface contacting the charge-trapping dielectric (160) than at the surface contacting the active area.

Abstract: A nonvolatile memory cell stores at least 50% of the charge in a dielectric, charge-trapping layer (160) and at least 20% of the charge in a floating gate (170). The floating gate is at most 20 nm thick.

Abstract: Thin oxide films are grown on silicon which has been previously treated with a gaseous or liquid source of chloride ions. The resulting oxide is of more uniform thickness than obtained on untreated silicon, thereby allowing a given charge to be stored on a floating gate formed over said oxide for a longer time than previously required for a structure not so treated.

Abstract: A nonvolatile memory has a charge trapping layer which includes a layer (130) made of silicon nitride doped with germanium or phosphorus (210). The germanium or phosphorus contains a large percentage of scattered, non-crystallized atoms uniformly distributed in the silicon nitride layer to increase the charge trapping density.

Abstract: In-situ steam generation (ISSG) is used to reduce the nitrogen concentration in silicon and silicon oxide areas.

Abstract: Thin oxide films are grown on silicon which has been previously treated with a gaseous or liquid source of chloride ions. The resulting oxide is of more uniform thickness than obtained on untreated silicon, thereby allowing a given charge to be stored on a floating gate formed over said oxide for a longer time than previously required for a structure not so treated.

Abstract: In-situ steam generation (ISSG) is used to reduce the nitrogen concentration in silicon and silicon oxide areas.

Abstract: A method and apparatus are disclosed for reducing the concentration of chlorine and/or other bound contaminants within a semiconductor oxide composition that is formed by chemical vapor deposition (CVD) using a semiconductor-element-providing reactant such as dichlorosilane (DCS) and an oxygen-providing reactant such as N2O. In one embodiment, a DCS-HTO film is annealed by heating N2O gas to a temperature in the range of about 825° C. to about 950° C. so as to trigger exothermic decomposition of the N2O gas and flowing the heated gas across the DCS-HTO film so that disassociated atomic oxygen radicals within the heated N2O gas can transfer disassociating energy to chlorine atoms bound within the DCS-HTO film and so that the atomic oxygen radicals can fill oxygen vacancies within the semiconductor-oxide matrix of DCS-HTO film. An improved ONO structure may be formed with the annealed DCS-HTO film for use in floating gate or other memory applications.

Abstract: Conventional fabrication of top oxide in an ONO-type memory cell stack usually produces Bird's Beak. Certain materials in the stack such as silicon nitrides are relatively difficult to oxidize. As a result oxidation does not proceed uniformly along the multi-layered height of the ONO-type stack. The present disclosure shows how radical-based fabrication of top-oxide of an ONO stack (i.e. by ISSG method) can help to reduce formation of Bird's Beak. More specifically, it is indicated that short-lived oxidizing agents (e.g., atomic oxygen) are able to better oxidize difficult to oxidize materials such as silicon nitride and the it is indicated that the short-lived oxidizing agents alternatively or additionally do not diffuse deeply through already oxidized layers of the ONO stack such as the lower silicon oxide layer. As a result, a more uniform top oxide dielectric can be fabricated with more uniform breakdown voltages along its height.

Abstract: An ONO-type inter-poly insulator is formed by depositing intrinsic silicon on an oxidation stop layer. In one embodiment, the oxidation stop layer is a nitridated top surface of a lower, and conductively-doped, polysilicon layer. In one embodiment, atomic layer deposition (ALD) is used to precisely control the thickness of the deposited, intrinsic silicon. Heat and an oxidizing atmosphere are used to convert the deposited, intrinsic silicon into thermally-grown, silicon dioxide. The oxidation stop layer impedes deeper oxidation. A silicon nitride layer and an additional silicon oxide layer are further deposited to complete the ONO structure before an upper, and conductively-doped, polysilicon layer is formed. In one embodiment, the lower and upper polysilicon layers are patterned to respectively define a floating gate (FG) and a control gate (CG) of an electrically re-programmable memory cell.

Abstract: In-situ steam generation (ISSG) is used to reduce the nitrogen concentration in silicon and silicon oxide areas.

Abstract: In-situ steam generation (ISSG) is used to reduce the nitrogen concentration in silicon and silicon oxide areas.

Abstract: Chlorine is incorporated into pad oxide (110) formed on a silicon substrate (120) before the etch of substrate isolation trenches (134). The chlorine enhances the rounding of the top corners (140C) of the trenches when a silicon oxide liner (150.1) is thermally grown on the trench surfaces. A second silicon oxide liner (150.2) incorporating chlorine is deposited by CVD over the first liner (150.1), and then a third liner (150.3) is thermally grown. The chlorine concentration in the second liner (150.2) and the thickness of the three liners (150.1, 150.2, 150.3) are controlled to improve the corner rounding without consuming too much of the active areas (140).

Abstract: Silicon oxide (210) is grown on a silicon region (130). At least a portion (210N) of the silicon oxide (210) adjacent to the silicon region (130) is nitrided. Then some of the silicon oxide (210) is removed, leaving the nitrided portion (210N). Additional silicon oxide is thermally grown on the silicon region (130) under the nitrided silicon oxide portion (210N). This additional silicon oxide and the nitrided portion (210N) form a silicon oxide layer (140) having a high nitrogen concentration adjacent to a surface opposite from the silicon region (130) and a low nitrogen concentration elsewhere. Another nitridation step increases the nitrogen concentration in the silicon oxide layer (140) adjacent to the silicon region, providing a double peak nitrogen profile.

Abstract: An ONO-type inter-poly insulator is formed by depositing intrinsic silicon on an oxidation stop layer. In one embodiment, the oxidation stop layer is a nitridated top surface of a lower, and conductively-doped, polysilicon layer. In one embodiment, atomic layer deposition (ALD) is used to precisely control the thickness of the deposited, intrinsic silicon. Heat and an oxidizing atmosphere are used to convert the deposited, intrinsic silicon into thermally-grown, silicon dioxide. The oxidation stop layer impedes deeper oxidation. A silicon nitride layer and an additional silicon oxide layer are further deposited to complete the ONO structure before an upper, and conductively-doped, polysilicon layer is formed. In one embodiment, the lower and upper polysilicon layers are patterned to respectively define a floating gate (FG) and a control gate (CG) of an electrically re-programmable memory cell.

Abstract: Chlorine is incorporated into pad oxide (110) formed on a silicon substrate (120) before the etch of substrate isolation trenches (134). The chlorine enhances the rounding of the top corners (140C) of the trenches when a silicon oxide liner (150.1) is thermally grown on the trench surfaces. A second silicon oxide liner (150.2) incorporating chlorine is deposited by CVD over the first liner (150.1), and then a third liner (150.3) is thermally grown. The chlorine concentration in the second liner (150.2) and the thickness of the three liners (150.1, 150.2, 150.3) are controlled to improve the corner rounding without consuming too much of the active areas (140).

Abstract: Silicon oxide (210) is grown on a silicon region (130). At least a portion (210N) of the silicon oxide (210) adjacent to the silicon region (130) is nitrided. Then some of the silicon oxide (210) is removed, leaving the nitrided portion (210N). Additional silicon oxide is thermally grown on the silicon region (130) under the nitrided silicon oxide portion (210N). This additional silicon oxide and the nitrided portion (210N) form a silicon oxide layer (140) having a high nitrogen concentration adjacent to a surface opposite from the silicon region (130) and a low nitrogen concentration elsewhere. Another nitridation step increases the nitrogen concentration in the silicon oxide layer (140) adjacent to the silicon region, providing a double peak nitrogen profile.

Abstract: Chlorine is incorporated into pad oxide (110) formed on a silicon substrate (120) before the etch of substrate isolation trenches (134). The chlorine enhances the rounding of the top corners (140C) of the trenches when a silicon oxide liner (150.1) is thermally grown on the trench surfaces. A second silicon oxide liner (150.2) incorporating chlorine is deposited by CVD over the first liner (150.1), and then a third liner (150.3) is thermally grown. The chlorine concentration in the second liner (150.2) and the thickness of the three liners (150.1, 150.2, 150.3) are controlled to improve the corner rounding without consuming too much of the active areas (140).

Abstract: Aluminum oxide is deposited by atomic layer deposition to form a high-k dielectric for the interpoly dielectric layer of a non-volatile memory device. The increased capacitive coupling can allow a thicker oxide layer to be used between the floating gate and the control gate, resulting in improved reliability and longer lifetime of the memory cells fabricated according to this invention.

Abstract: A method and apparatus are disclosed for reducing the concentration of chlorine and/or other bound contaminants within a semiconductor oxide composition that is formed by chemical vapor deposition (CVD) using a semiconductor-element-providing reactant such as dichlorosilane (DCS) and an oxygen-providing reactant such as N2O. In one embodiment, a DCS-HTO film is annealed by heating N2O gas to a temperature in the range of about 825° C. to about 950 ° C. so as to trigger exothermic decomposition of the N2O gas and flowing the heated gas across the DCS-HTO film so that disassociated atomic oxygen radicals within the heated N2O gas can transfer disassociating energy to chlorine atoms bound within the DCS-HTO film and so that the atomic oxygen radicals can fill oxygen vacancies within the semiconductor-oxide matrix of DCS-HTO film. An improved ONO structure may be formed with the annealed DCS-HTO film for use in floating gate or other memory applications.