Scalable Virtual-Ground Multilevel-Cell Floating-Gate Flash Memory

Yamauchi, Y.; Kamakura, Yoshinari; Matsuoka, Toshimasa

doi:10.1109/ted.2013.2270565

Cited by 14 publications

(8 citation statements)

References 20 publications

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“…A relatively thick tunneling oxide and inter poly dielectric layer have to be used in the floating-gate memory to maintain acceptable reliability, limiting further down-scaling of the cell size in the vertical direction [4]. In addition, maintaining a high gate coupling ratio is still one main bottle-neck for down-scaling the floating-gate devices [5]. Moreover, as the spacing between adjacent devices is down-scaled, this parasitic capacitance plays an increasingly dominant role in the device performance due to data stored in the adjacent cells can interfere with each other by capacitive coupling [6].…”

Section: Introductionmentioning

confidence: 99%

Review on Non-Volatile Memory with High-k Dielectrics: Flash for Generation Beyond 32 nm

et al. 2014

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Flash memory is the most widely used non-volatile memory device nowadays. In order to keep up with the demand for increased memory capacities, flash memory has been continuously scaled to smaller and smaller dimensions. The main benefits of down-scaling cell size and increasing integration are that they enable lower manufacturing cost as well as higher performance. Charge trapping memory is regarded as one of the most promising flash memory technologies as further down-scaling continues. In addition, more and more exploration is investigated with high-k dielectrics implemented in the charge trapping memory. The paper reviews the advanced research status concerning charge trapping memory with high-k dielectrics for the performance improvement. Application of high-k dielectric as charge trapping layer, blocking layer, and tunneling layer is comprehensively discussed accordingly.

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Section: Introductionmentioning

confidence: 99%

Review on Non-Volatile Memory with High-k Dielectrics: Flash for Generation Beyond 32 nm

et al. 2014

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“…10,11) The nonvolatile memory devices with low power, highspeed operation, and large storage are widely investigated such as metal/oxide/nitride/oxide/silicon (MONOS) structure and floating-gate type devices. [12][13][14][15][16][17] In the conventional floating-gate memory device, the high-k insulator for tunnel layer (TL) and block layer (BL) and a metal layer for floating gate (FG) and control gate (CG) are widely studied to improve the memory characteristics. [17][18][19][20][21][22] However, the high operation voltage (>10 V) is necessary.…”

Section: Introductionmentioning

confidence: 99%

N₂ gas flow rate dependence on the high-k LaB _x N _y thin film characteristics formed by RF sputtering for floating-gate memory applications

Park

Kamata

Ohmi

2021

Jpn. J. Appl. Phys.

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In this paper, the N2 gas flow rate dependence on the high-k LaB x N y thin film characteristics formed by RF sputtering for floating-gate memory applications was investigated. The N2 gas flow rate during the sputtering for the LaB x N y insulating layer was increased from 3 to 9 sccm with the Ar of 10 sccm for N-doped LaB6 (Metal: M)/LaB x N y (Insulator: I)/p-Si(100). Then, the N-doped LaB6/LaB x N y /N-doped LaB6/LaB x N y /p-Si(100) MIMIS diode was fabricated with LaB x N y tunnel layer and block layer formed by Ar/N2 gas flow ratio of 10/7 sccm. The equivalent oxide thickness (EOT) was decreased from 7 to 5.5 nm by increasing the N2 gas flow rate from 3 to 7 sccm. On the other hand, the LaB x N y insulating layer formed by N2 gas flow rate of 9 sccm showed EOT of 8.2 nm with crystallization. Furthermore, the memory window of 0.4 V was obtained for the MIMIS floating-gate structure utilizing the N-doped LaB6/LaB x N y stacked layer.

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“…[1][2][3] Recently, conventional floating gate (FG)-type NVM devices in large-scale integrated circuits (LSIs) are facing scaling limits in terms of coupling ratio and disturbance between cells among others. [4][5][6][7] Charge-trapping (CT)-type NVM devices such as metal=oxide=nitride=oxide= silicon (MONOS) or silicon=oxide=nitride=oxide=silicon (SONOS) are attractive candidates for realizing further scaling down. [8][9][10][11][12][13][14] For low-voltage operation, CT-type NVM devices with various high-k dielectrics were investigated, such as HfLaON=HfON=SiO 2 =Si and Al=Al 2 O 3 =ZrON=SiO 2 =Si.…”

Section: Introductionmentioning

confidence: 99%

In situ formation of Hf-based metal/oxide/nitride/oxide/silicon structure for nonvolatile memory application

Kudoh¹,

Ohmi²

2018

Jpn. J. Appl. Phys.

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In this study, we investigated the electrical characteristics of a Hf-based metal/oxide/nitride/oxide/silicon (MONOS) nonvolatile memory (NVM) device formed in situ for the first time. Furthermore, the effects of the in situ HfN gate stack formation process on the electrical characteristics of the Hf-based MONOS device were also investigated by comparing with the device with the Al gate formed ex situ. The drain-current–gate-voltage (ID–VG) characteristics with negligible hysteresis and high yield were realized by using the in situ HfN gate. A memory window (MW) as large as 4.2 V was obtained at the program voltage/time (VPGM/tPGM) of 10 V/1 s and the erase voltage/time (VERS/tERS) of −10 V/1 s. Furthermore, the low-voltage and short-pulse operations, such as ±6 V/2 ms were achieved. Finally, 2-bit/cell operation of the Hf-based MONOS device was demonstrated for the first time utilizing electron injection at the source and drain regions.

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Scalable Virtual-Ground Multilevel-Cell Floating-Gate Flash Memory

Cited by 14 publications

References 20 publications

Review on Non-Volatile Memory with High-k Dielectrics: Flash for Generation Beyond 32 nm

Review on Non-Volatile Memory with High-k Dielectrics: Flash for Generation Beyond 32 nm

N₂ gas flow rate dependence on the high-k LaB _x N _y thin film characteristics formed by RF sputtering for floating-gate memory applications

In situ formation of Hf-based metal/oxide/nitride/oxide/silicon structure for nonvolatile memory application

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