A highly manufacturable deep trench based DRAM cell layout with a planar array device in a 70nm technology

Amon, Johannes; Kieslich, A.; Heineck, L.; Schuster, Thomas J; Faul, J.; Luetzen, J.; Fan, Chih‐Peng; Huang, Chaoyi; Fischer, B.; Enders, Gisela; Kudelka, S.; Schroeder, Uwe; Kuesters, K.-H.; Lange, Gert de; Alsmeier, J.

doi:10.1109/iedm.2004.1419068

Cited by 23 publications

(15 citation statements)

References 3 publications

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“…As scaling advances, the area available for capacitor decreases. Therefore, capacitance enhancement technologies such as hemispherical silicon grains and Al 2 O 3 ALD high k dielectric are promising candidate [7]. DRAM scaling will continue to integrate many advanced technologies in view of the huge size of the DRAM market.…”

Section: Tis/fin/sgt Drammentioning

confidence: 99%

Advanced memory concepts for DRAM and nonvolatile memories

Horiguchi

2006

Solid-State Electronics

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Section: Tis/fin/sgt Drammentioning

confidence: 99%

Advanced memory concepts for DRAM and nonvolatile memories

Horiguchi

2006

Solid-State Electronics

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“…Here, capacitance enhancement was reached by surface area enhancement due to improved aspect ratio etches (up to 70:1), introduction of hemispherical grains and bottle-shaped trenches. [21] The required EOT of a stacked capacitor is shown in Figure 11. Based on improvements in high-k materials, the EOT of stacked capacitor dielectric was shrunk from EOT ¼ 1.5 nm at 80 nm groundrule to EOT ¼ 1.0 nm at 55 nm ground rule; the trend will continue towards EOT ¼ 0.5 nm at 40 nm groundrule (base for this estimate: storage node height 1.4 mm).…”

Section: Capacitor Developmentmentioning

confidence: 99%

New Materials in Memory Development Sub 50 nm: Trends in Flash and DRAM

Kuesters¹,

Beug²,

Schroeder³

et al. 2009

Adv Eng Mater

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“…To address the latter problem, the introduction of the high-k dielectric materials such as the Al 2 O 3 [1], HfSiO [2], HfAlO x [3], and HfO 2 /Ta 2 O 5 stack [4], along with the hemispherical-silicongrain (HSG) structure is an ineluctable trend. Nevertheless, the aforementioned avenues offer opportunities to boost the cell capacitance for the upcoming generations; unfortunately, it is not true for the 8-in fab since most of the DRAM chipmakers concentrate the advanced-equipment investment on the 12-in fab.…”

Section: Introductionmentioning

confidence: 99%

Oxide-Nitride Storage Dielectric Formation in a Single-Furnace Process for Trench DRAM

Chang²,

Wang³

et al. 2006

IEEE Electron Device Lett.

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Abstract-A simplified and integrated technique has been proposed to form an oxide/nitride storage dielectric in a single-furnace process by low-pressure oxidation and nitride film deposition with an extra N 2 O treatment for the trench dynamic random access memory (DRAM). Compared to the conventional nitride/oxide dielectric, this newly developed dielectric enjoys cellcapacitance-enhancement factor as high as 12.5% without degrading the leakage current and electron-trapping property. From the reliability test, the qualification for the DRAM application is also proven by the dielectric lifetime longer than 10-years. Most importantly, this technique can reduce the production cycle time without an additional equipment investment, which is essential in the cost-competitive DRAM arena.Index Terms-N 2 O treatment, oxide/nitride (ON) stack, singlefurnace process, storage dielectric, trench dynamic random access memory (DRAM).

show abstract

A highly manufacturable deep trench based DRAM cell layout with a planar array device in a 70nm technology

Cited by 23 publications

References 3 publications

Advanced memory concepts for DRAM and nonvolatile memories

Advanced memory concepts for DRAM and nonvolatile memories

New Materials in Memory Development Sub 50 nm: Trends in Flash and DRAM

Oxide-Nitride Storage Dielectric Formation in a Single-Furnace Process for Trench DRAM

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