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    • 7. 发明授权
    • Process for fabricating an MNOS flash memory device
    • 制造MNOS闪存设备的过程
    • US06287917B1
    • 2001-09-11
    • US09392675
    • 1999-09-08
    • Stephen Keetai ParkTim ThurgateBharath Rangarajan
    • Stephen Keetai ParkTim ThurgateBharath Rangarajan
    • H01L218247
    • H01L27/11568H01L27/115
    • A process for fabricating an MNOS device includes the steps of forming a hardmask containing at least first and second openings over a core array area of a semiconductor substrate. An angle doping process is carried out to form halo regions in precise locations within the substrate at the edges of the first and second openings in the hardmask. Another doping process is carried out to form buried bit-lines in the substrate using the hardmask as a doping mask. Once the halo regions and the buried bit-lines are formed, the hardmask is removed and a composite dielectric layer is formed overlying the substrate. A gate layer is deposited to overlie the composite dielectric layer, and an etching process is carried out to form a control gate electrode and a charge storage electrode in the MNOS device
    • 制造MNOS器件的方法包括以下步骤:在半导体衬底的芯阵列区域上形成至少包含第一和第二开口的硬掩模。 进行角度掺杂处理以在硬掩模中的第一和第二开口的边缘处在衬底内的精确位置中形成晕圈。 进行另一种掺杂工艺以使用硬掩模作为掺杂掩模在衬底中形成掩埋位线。 一旦形成了光晕区域和掩埋位线,就去除了硬掩模,并且在衬底上形成复合介电层。 沉积栅极层以覆盖复合介电层,并且进行蚀刻处理以在MNOS器件中形成控制栅电极和电荷存储电极
    • 8. 发明授权
    • Charge injection
    • 电荷注入
    • US06567303B1
    • 2003-05-20
    • US10050483
    • 2002-01-16
    • Darlene G. HamiltonJanet S. Y. WangNarbeh DerhacobianTim ThurgateMichael K. Han
    • Darlene G. HamiltonJanet S. Y. WangNarbeh DerhacobianTim ThurgateMichael K. Han
    • G11C1604
    • G11C16/3409G11C11/5671G11C16/0475G11C16/10G11C16/3404G11C16/3436G11C16/3445
    • A system and methodology is provided for programming first and second bits of a memory array of dual bit memory cells at a substantially high delta VT. The substantially higher VT assures that the memory array will maintain programmed data and erase data consistently after higher temperature stresses and/or customer operation over substantial periods of time. At a substantially higher delta VT, programming of the first bit of the memory cell causes the second bit to program harder and faster due to the shorter channel length. Therefore, the present invention employs selected gate and drain voltages and programming pulse widths during programming of the first and second bit that assures a controlled first bit VT and slows down programming of the second bit. Furthermore, the selected programming parameters keep the programming times short without degrading charge loss.
    • 提供了一种用于以基本上高的delta VT对双位存储器单元的存储器阵列的第一和第二位进行编程的系统和方法。 基本上更高的VT确保存储器阵列将维持编程数据并且在相当长的一段时间内在较高的温度应力和/或客户操作之后一致地擦除数据。 在基本上较高的增量VT下,存储器单元的第一位的编程使得第二位由于较短的通道长度而更硬更快地编程。 因此,本发明在第一和第二位的编程期间采用选择的栅极和漏极电压以及编程脉冲宽度,以确保受控的第一位VT并减慢第二位的编程。 此外,所选择的编程参数保持编程时间短而不降低电荷损耗。
    • 9. 发明授权
    • Method for measuring source and drain junction depth in silicon on insulator technology
    • 硅绝缘体技术测量源极和漏极结深度的方法
    • US06475816B1
    • 2002-11-05
    • US09781435
    • 2001-02-13
    • Concetta RiccobeneNga-Ching WongTim Thurgate
    • Concetta RiccobeneNga-Ching WongTim Thurgate
    • H01L2166
    • H01L22/14G01R31/27
    • A method is provided for accurately determining the junction depth of silicon-on-insulator (SOI) devices. Embodiments include determining the junction depth in an SOI device under inspection by measuring the threshold voltage of its “bottom transistor” formed by its source and drain regions together with its substrate acting as a gate. The threshold voltage of the bottom transistor of an SOI device varies with its junction depth in a predictable way. Thus, the junction depth of the inspected device is determined by comparing its bottom transistor threshold voltage with the bottom transistor threshold voltage of corresponding reference SOI devices of known junction depth to find a match. For example, simulated SOI devices with the same characteristics as the inspected device, whose junction depth and bottom transistor threshold voltages have been previously calculated, are used as a “reference library”. If the bottom transistor threshold voltage of the inspected device has about the same value as that of a particular one of the reference devices, then the inspected device has the junction depth of that particular reference device. Thus, junction depth of the inspected SOI device is accurately determined by a simple electrical measurement of threshold voltage.
    • 提供了一种用于精确地确定绝缘体上硅(SOI)器件的结深度的方法。 实施例包括通过测量其源极和漏极区域形成的其“底部晶体管”及其衬底作为栅极的阈值电压来确定被检查的SOI器件中的结深度。 SOI器件的底部晶体管的阈值电压以其可预测的方式随其结深度而变化。 因此,通过将其底部晶体管阈值电压与已知结深度的相应参考SOI器件的底部晶体管阈值电压进行比较来确定被检查器件的结深度以找到匹配。 例如,具有与被预先计算的结深度和底部晶体管阈值电压的被检查器件相同特性的模拟SOI器件被用作“参考库”。 如果被检查装置的底部晶体管阈值电压具有与特定参考装置的底部晶体管阈值电压相同的值,则所检查的装置具有该特定参考装置的结深度。 因此,通过阈值电压的简单电测量精确地确定被检查的SOI器件的结深度。