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: The floating gate, or the oxide between the floating and control gates, or both are nitrided before the control gate layer is deposited.

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: 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: Conventional fabrication of sidewall oxide around an ONO-type memory cell stack usually produces Bird's Beak because prior to the fabrication, there is an exposed sidewall of the ONO-type memory cell stack that exposes side parts of a plurality of material layers respectively composed of different materials. Certain materials in the stack such as silicon nitrides are more difficult to oxidize than other materials in the stack such polysilicon. As a result oxidation does not proceed uniformly along the multi-layered height of the sidewall. The present disclosure shows how radical-based fabrication of sidewall dielectric can help to reduce the Bird's Beak formation. More specifically, it is indicated that short-lived oxidizing agents (e.g.

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: A thin buffer layer of SiON is formed on the top surface of the floating gate, in order to protect the polysilicon surface from attack by atomic chlorine produced during the formation of the high temperature oxide of the ONO stack. The buffer layer can also be formed on other dielectric surfaces which are otherwise subject to adverse conditions in subsequent processing, such as the nitride layer in the ONO dielectric stack.

Abstract: A thin buffer layer of SiON is formed on the top surface of the floating gate, in order to protect the polysilicon surface from attack by atomic chlorine produced during the formation of the high temperature oxide of the ONO stack. The buffer layer can also be formed on other dielectric surfaces which are otherwise subject to adverse conditions in subsequent processing, such as the nitride layer in the ONO dielectric stack.

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: The floating gate, or the oxide between the floating and control gates, or both are nitrided before the control gate layer is deposited.

Abstract: A thin buffer layer of SiON is formed on the top surface of the floating gate, in order to protect the polysilicon surface from attack by atomic chlorine produced during the formation of the high temperature oxide of the ONO stack. The buffer layer can also be formed on other dielectric surfaces which are otherwise subject to adverse conditions in subsequent processing, such as the nitride layer in the ONO dielectric stack.

Abstract: A thin buffer layer of SiON is formed on the top surface of the floating gate, in order to protect the polysilicon surface from attack by atomic chlorine produced during the formation of the high temperature oxide of the ONO stack. The buffer layer can also be formed on other dielectric surfaces which are otherwise subject to adverse conditions in subsequent processing, such as the nitride layer in the ONO dielectric stack.

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: The floating gate, or the oxide between the floating and control gates, or both are nitrided before the control gate layer is deposited.

Abstract: The floating gate, or the oxide between the floating and control gates, or both are nitrided before the control gate layer is deposited.

Abstract: A process used to retard out diffusion of P type dopants from P type LDD regions, resulting in unwanted LDD series resistance increases, has been developed. The process features the formation of a nitrogen containing layer, placed between the P type LDD region and overlying silicon oxide regions, retarding the diffusion of boron from the LDD regions to the overlying silicon oxide regions, during subsequent high temperature anneals. The nitrogen containing layer, such as a thin silicon nitride layer, or a silicon oxynitride layer, formed during or after reoxidation of a P type polysilicon gate structure, is also formed in a region that also retards the out diffusion of P type dopants from the P type polysilicon gate structure.

Abstract: A process for forming a first group of gate structures, designed to operate at a lower voltage than a simultaneously formed second group of gate structures, has been developed. The process features the thermal growth of a first silicon dioxide gate insulator layer, on a portion of the semiconductor substrate used for the lower voltage gate structures, while simultaneously forming a thicker, second silicon dioxide gate insulator layer on a portion of the semiconductor substrate used for the higher voltage gate structures. The thermal growth of the first, and second silicon dioxide gate insulator layers is accomplished via diffusion of the oxidizing species: through a thick, composite silicon nitride layer, to obtain the thinner, first silicon dioxide gate insulator layer, on a first portion of the semiconductor substrate; and through a thinner, silicon nitride layer, to obtain the thicker, second silicon dioxide gate insulator layer, on a second portion of the semiconductor substrate.

Abstract: A method for improving oxide quality and reliability by using low pressure during oxidation and nitridation is described. The wafer is loaded into a chamber wherein a pressure of between about 80 and 300 torr is maintained during the forming of the dielectric layer. The silicon substrate of the wafer is oxidized, then nitrided. The substrate is annealed to complete formation of the dielectric layer.

Abstract: The invention is a method of manufacturing a semiconductor memory device using a novel intergate dielectric stack. A key feature of of the invention is the novel O/N/SiON/O structure, forming a silicon oxynitride layer on the silicon nitride layer. The method begins by forming a first insulating layer and a first conductive layer on a semiconductor substrate having one conductivity type. A second insulating layer is formed on the first conducting layer by sequentially stacking: a first silicon oxide layer; a silicon nitride layer; a silicon oxynitride layer; and a second silicon oxide layer. A second conductive layer is formed on the second insulating layer. The first insulating layer, the first conductive layer, the second insulating layer, and the second conductive layer are patterned to form a floating gate, an intergate dielectric, and a control gate. Finally, a source and drain are formed to complete the memory device.