This paper explores and demonstrates a novel technique to conformally coat solution-derived electrodes and dielectric films over Through-Silicon-Via (TSV) or Through-Silicon Trench (TST) structures. In this technique, precursor solution for electrode or dielectric coatings is dispensed on the top of a TSV wafer and infiltrated through the via by creating a pressure gradient. Two material systems used in capacitors, Lanthanum Nickel Oxide (LNO) as electrode and Lead Zirconate Titanate (PZT) as dielectric, were deposited on the TSV surfaces using this technique. SEM cross-section analysis showed that the vacuum-infiltration can be extended to conformally coat on trenches with aspect ratios of greater than 5. A planar capacitor with density of 3 μF/cm2 and low leakage was fabricated to demonstrate the material compatibility. Using this technique, a trench capacitor device can be fabricated with an all-solution coating process, without involving any expensive deposition tools. This can thus eliminate costly platinum electrodes that are frequently required to yield high permittivity PZT films. This technique can also address the through-put limitations of today's conformal deposition technologies such as sputtering, Chemical Vapor Deposition (CVD) and Atomic Layer Deposition (ALD). The tool and process can also be applied to other 3D silicon structures where conformal ceramic coatings are needed.
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机译:本文探讨并展示了一种新颖的技术,以将溶液衍生的电极和介电薄膜整合到通过硅通孔(TSV)或硅沟槽(TST)结构。在该技术中,电极或电介质涂层的前体溶液在TSV晶片的顶部上分配并通过产生压力梯度通过通孔渗透。使用该技术沉积在电容器中,镧镍氧化镍(LNO)作为电极和锆钛酸铅(PZT)作为电介质的锆(PZT)。 SEM横截面分析表明,真空渗透可以延伸以在大于5的横向比的横沟上涂布。平面电容器,密度为3μ f / cm 2 和制造低渗漏以证明材料相容性。使用该技术,可以使用全溶液涂覆工艺制造沟槽电容器装置,而不涉及任何昂贵的沉积工具。因此,这可以消除通常需要产生高介电常数PZT薄膜所需的昂贵铂电极。该技术还可以解决当今诸如溅射,化学气相沉积(CVD)和原子层沉积(ALD)之类的诸如溅射,化学气相沉积(ALD)的整体沉积技术的透过限制。该工具和工艺也可以应用于所需保形陶瓷涂层的其他3D硅结构。
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