J. Ahn, Y.W. Park, J. Shin, S.T. Kim, S. Shim, S. Nam, W.M. Park, H. Shin, C. Choi, K.T. Kim, D. Chin, O. Kwon, C. Hwang
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引用次数: 6
摘要
讨论了微绒毛图像化(MVP)技术,该技术提供了最大的电池电容。MVP技术的关键特点是形成半球形颗粒(HSG)群岛,并将其转移到下层氧化物中。HSG群岛图案在氧化层上产生,并且,通过使用该图案作为蚀刻掩膜,氧化物群岛图案再次转移到存储聚体上,通过各向异性干蚀刻形成绒毛棒。在蚀刻过程结束后,使用氧化物湿式蚀刻将氧化物蚀刻掩模图案剥离,从而在主体下方实现额外的翅片凹边结构。存储电极的主体可以通过一次沉积和蚀刻工艺形成,使得存储电极结构足够坚固,尽管其形状复杂,但仍能保持其物理稳定性。已经实现了256 mb的dram单元尺寸为0.6(约0.8 mu m/sup 2),具有超过30ff的堆叠结构单元电容。
Micro villus patterning (MVP) technology for 256 Mb DRAM stack cell
Micro villus patterning (MVP) technology which delivers the maximized cell capacitance is discussed. The key feature of the MVP technology is the formation of a hemispherical grain (HSG) archipelago and its transference to the underlayered oxide. The HSG archipelago pattern is produced on the oxide layer, and, by using that pattern as an etch mask, the oxide archipelago pattern is again transferred to the storage poly for the formation of villus bars by anisotropic dry etch. After the etching process, the oxide etch mask pattern is stripped away by using oxide wet etchant, so that additional Fin undercut structure is achieved underneath the main body. The main body of the storage electrode can be formed by single deposition and etch process, so that the storage electrode structure is strong enough to maintain its physical stability in spite of the complication of its shape. A 256-Mb DRAM-cell size of 0.6 approximately 0.8 mu m/sup 2/ having more than 30 fF of cell capacitance with a stack structure, has been realized.<>
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