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    • 2. 发明授权
    • Nonselective unpatterned etchback to expose buried patterned features
    • 曝光掩埋图案特征的无选择性无图案蚀刻
    • US07307013B2
    • 2007-12-11
    • US10883417
    • 2004-06-30
    • Usha RaghuramMichael W. KoneveckiSamuel V. Dunton
    • Usha RaghuramMichael W. KoneveckiSamuel V. Dunton
    • H01L21/461C03C25/68C23F1/00
    • H01L21/7684H01L21/31055H01L21/31116H01L21/32136H01L21/32137H01L21/76819H01L27/101H01L27/1021
    • A method for etching to form a planarized surface is disclosed. Spaced-apart features are formed of a first material, the first material either conductive or insulating. A second material is deposited over and between the first material. The second material is either insulating or conductive, opposite the conductivity of the first material. The second material is preferably self-planarizing during deposition. An unpatterned etch is performed to etch the second material and expose the top of the buried features of the first material. The etch is preferably a two-stage etch: The first stage is selective to the second material. When the second material is exposed, the etch chemistry is changed such that the etch is nonselective, etching the first material and the second material at substantially the same rate until the buried features are exposed across the wafer, producing a substantially planar surface.
    • 公开了一种用于蚀刻以形成平坦化表面的方法。 隔开的特征由第一材料形成,第一材料是导电的或绝缘的。 第二材料沉积在第一材料之上和之间。 第二种材料是绝缘的或导电的,与第一种材料的电导率相反。 第二种材料优选在沉积期间是自平面化的。 执行未图案化的蚀刻以蚀刻第二材料并暴露第一材料的掩埋特征的顶部。 蚀刻优选是两阶段蚀刻:第一阶段对第二材料是选择性的。 当暴露第二材料时,蚀刻化学物质被改变,使得蚀刻是非选择性的,以基本上相同的速率蚀刻第一材料和第二材料,直到掩埋特征暴露在晶片之外,产生基本平坦的表面。
    • 3. 发明申请
    • CONDUCTIVE HARD MASK TO PROTECT PATTERNED FEATURES DURING TRENCH ETCH
    • 导电硬掩模,以保护在TRENCH ETCH期间的图案特征
    • US20090273022A1
    • 2009-11-05
    • US12502796
    • 2009-07-14
    • Steven J. RadiganUsha RaghuramSamuel V. DuntonMichael W. Konevecki
    • Steven J. RadiganUsha RaghuramSamuel V. DuntonMichael W. Konevecki
    • H01L27/105H01L21/8234H01L21/822H01L27/06
    • H01L23/5252H01L27/1021H01L29/6609H01L2924/0002H01L2924/00
    • A monolithic three dimensional memory array is formed by a method that includes forming a first memory level above a substrate by i) forming a plurality of first substantially parallel conductors extending in a first direction, ii) forming first pillars above the first conductors, each first pillar comprising a first conductive layer or layerstack above a vertically oriented diode, the first pillars formed in a single photolithography step, iii) depositing a first dielectric layer above the first pillars, and iv) etching a plurality of substantially parallel first trenches in the first dielectric layer, the first trenches extending in a second direction, wherein, after the etching step, the lowest point in the trenches is above the lowest point of the first conductive layer or layerstack, wherein the first conductive layer or layerstack does not comprise a resistivity-switching metal oxide or nitride. The method also includes monolithically forming a second memory level above the first memory level. Other aspects are also described.
    • 单片三维存储器阵列通过一种方法形成,该方法包括通过在第一方向上形成多个沿第一方向延伸的多个第一基本上平行的导体形成第一存储器电平,ii)在第一导体上方形成第一柱, 柱,其包括在垂直取向的二极管上方的第一导电层或层堆叠,在单个光刻步骤中形成的第一柱,iii)在第一柱上方沉积第一电介质层,以及iv)在第一栅极中蚀刻多个基本上平行的第一沟槽 所述第一沟槽在第二方向上延伸,其中在所述蚀刻步骤之后,所述沟槽中的最低点高于所述第一导电层或层堆叠的最低点,其中所述第一导电层或所述层堆叠不包含电阻率 开关金属氧化物或氮化物。 该方法还包括在第一存储器级上方单片地形成第二存储器级。 还描述了其他方面。
    • 10. 发明授权
    • Metal planarization system
    • US06586326B2
    • 2003-07-01
    • US09804783
    • 2001-03-13
    • Jayanthi PallintiSamuel V. DuntonRonald J. Nagahara
    • Jayanthi PallintiSamuel V. DuntonRonald J. Nagahara
    • H01L2100
    • H01L21/288H01L21/7684
    • A method for restoring an eroded portion in an exposed upper surface cavity of a metallic element in a microelectronic device, where the metallic element has a hardness, and the metallic element is laterally surrounded by lateral elements, where at least one structure within the lateral elements has a hardness that is greater than the hardness of the metallic element. A precursor material is deposited in at least the cavity of the upper surface of the metallic element. The precursor material is deposited to a thickness that at least fills the cavity of the upper surface of the metallic element. The precursor material has a hardness that is less than the hardness of the at least one structure within the lateral elements. The precursor material is removed as necessary from the lateral elements, and the precursor material is planarized. Only the precursor material within the cavity of the upper surface of the metallic element is selectively replaced with a desired material. The eroded portion of the metallic element is thereby restored. By removing precursor material from those areas in which no replacement with the desired material is wanted, the desired material is selectively deposited only in those place where the precursor material remains, and where it is desired to fill in the cavities or dishing that was created in the areas of the softer metallic elements between the harder laterally surrounding elements during a prior chemical mechanical polishing process. Thus, the microelectronic device is more fully planarized, as the dishing is filled in, and the metallic element is supplemented with an additional amount of desired material.