Simulation of capacitorless DRAM based on polycrystalline silicon with a vertical underlap structure and a separated channel layer

Bae, Seung Ji; Lee, Sang Ho; Park, Jin; Kang, Ga Eon; Heo, Jun Hyeok; Jeon, So Ra; Kim, Min Seok; Hong, Jeong Woo; Jang, Jaewon; Bae, Jin-Hyuk; Lee, Sin-Hyung; Kang, In Man

doi:10.35848/1347-4065/ad2bbd

Jpn. J. Appl. Phys.

2024

DOI: 10.35848/1347-4065/ad2bbd

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Simulation of capacitorless DRAM based on polycrystalline silicon with a vertical underlap structure and a separated channel layer

Seung Ji Bae,

Sang Ho Lee,

Jin Park

et al.

Abstract: In this study, a capacitorless one-transistor dynamic random-access memory (1T-DRAM) based on polycrystalline silicon (poly-Si) with a vertical underlap structure and a separated channel layer was designed and analyzed. The memory performance was improved by the vertical underlap structure and the region separated into channel and storage layers. The vertical underlap structure suppressed the recombination rate by storing the holes in the isolated body and could be more easily fabricated than a conventional un… Show more

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Cited by 2 publications

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Doping- and capacitor-less 1T-DRAM cell using reconfigurable feedback mechanism

Suh,

Lim

2024

Nanotechnology

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In this paper, we propose a doping- and capacitor-less 1T-DRAM cell, which achieved virtual doping by leveraging charge plasma and bias-induced electrostatic doping (bias-ED) techniques in a 5-nm-thick intrinsic silicon body, thereby eliminating doping processes. Platinum was in contact with the drain, while aluminum was in contact with the source, enabling virtual doping of the silicon body into a p*-i-n* configuration via the charge-plasma technique. Two coupled polarity gates and one control gate are positioned above the intrinsic channel region. The intrinsic channel region is virtually doped through the bias-ED by applying voltages to the gates, forming potential wells inside the channel. The voltage applied to the two coupled polarity gates determines whether the device operates in the p- or n-channel mode, whereas the control gate governs the flow of charge carriers. Charge carriers are stored and released in the potential wells inside the channel by adjusting the gate, effectively replacing the capacitor. In this device, the placement of polarity gates on either side of the control gate enables the observation of the reconfigurable characteristics. Moreover, the proposed device utilizes a feedback mechanism, enabling excellent memory characteristics such as a high on/off current ratio of ~10^9, steep switching behavior of ~0.2 µV/dec, short write time of 10 ns, long hold retention of over 100 s, and long read retention of over 600 s.

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Doping- and capacitor-less 1T-DRAM cell using reconfigurable feedback mechanism

Suh,

Lim

2024

Nanotechnology

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A high-performance capacitorless 1T-DRAM based on Z-shaped electron-hole bilayer TFET and SiGe memory window

Liu,

Zhou,

et al. 2024

Phys. Scr.

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In this paper, a novel capacitorless dynamic random access memory (Z-EHBTFET 1T-DRAM) is designed based on a Z-shaped electron-hole bilayer tunnel field-effect transistor and a SiGe memory window, and its storage performance is systematically analyzed and studied in detail through numerical simulation. A large number of electrons can be induced in the inverted L-shaped channel of Z-EHBTFET 1T-DRAM using gate 1 to create an electron-hole bilayer together with the source region, which increases the line tunneling electric field and ultimately improves the sensing margin (SM) and read current ratio (IR1/IR0). SiGe memory window helps to improve the storage capacity of holes, aiming to improve the retention time (RT) and SM. By optimizing the Ge-composition and width of the SiGe memory window, the thickness of the I-shaped channel, and the gate gap length, the SM of 2.03 μA/μm, IR1/IR0 of 3.58 × 104, and RT of 1.2 s can be obtained for Z-EHBTFET 1T-DRAM. Compared with most reported 1T1C-DRAMs and traditional 1T-DRAMs, it has better storage performance. Moreover, it can operate at a lower programming voltage while ensuring superior storage performance, making it has great application prospect in the low power consumption field.

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Simulation of capacitorless DRAM based on polycrystalline silicon with a vertical underlap structure and a separated channel layer

Cited by 2 publications

References 36 publications

Doping- and capacitor-less 1T-DRAM cell using reconfigurable feedback mechanism

Doping- and capacitor-less 1T-DRAM cell using reconfigurable feedback mechanism

A high-performance capacitorless 1T-DRAM based on Z-shaped electron-hole bilayer TFET and SiGe memory window

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