Electrical study of Ge-nanocrystal-based metal-oxide-semiconductor structures for <i>p</i>-type nonvolatile memory applications

Kanoun, Mehdi; Souifi, A.; Baron, T.; Mazen, F.

doi:10.1063/1.1751227

Cited by 120 publications

(69 citation statements)

References 15 publications

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“…Ge has a smaller band-gap than Si which makes it compatible with currently used metal oxide semiconductor (MOS) technology and also improves its write/erase speed [5,6]. Promising non-volatile properties of Ge-NCs were reported by several groups [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Ge nanocrystals in alumina matrix: A structural study

Kashtiban

Pinto

Bangert

et al. 2010

J. Phys.: Conf. Ser.

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Section: Introductionmentioning

confidence: 99%

Ge nanocrystals in alumina matrix: A structural study

Kashtiban

Pinto

Bangert

et al. 2010

J. Phys.: Conf. Ser.

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“…This produces two phenomena: a faster charging process in Ge islands and a larger potential barrier for carrier leakage to the substrate, resulting in a larger retention time [3][4][5][6][7]. Recent theoretical studies have demonstrated the better retention properties of Ge NC memories, compared with those based on Si NCs and an ideal size for Ge islands of ~15 nm [8].…”

mentioning

confidence: 99%

Two-dimensional arrays of ordered, highly dense and ultra-small Ge nanocrystals on thin SiO₂layers

Berbézier

Karmous

Ronda

et al. 2005

J. Phys.: Conf. Ser.

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“…However, research results in several groups have demonstrated the superior properties of Ge-based nanocrystal memories over those based on Si. [4][5][6] The Ge nanocrystals offer improved nonvolatile charge retention time due to their smaller band gap. The smaller band gap provides both a higher confinement barrier for the retention mode and a smaller barrier for the program and erase modes.…”

mentioning

confidence: 99%

Synthesis and memory effect study of Ge nanocrystals embedded in LaAlO3 high-k dielectrics

Lee

Dai

2005

Applied Physics Letters

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A floating gate memory structure utilizing Ge nanocrystals embedded in LaAlO 3 ͑LAO͒ high-k dielectric films has been fabricated by pulsed-laser deposition. A cross-sectional high-resolution transmission electron microscopy study revealed that the floating gate structure contains 5-nm-diam spherelike Ge nanocrystals embedded in amorphous LAO. A significant memory effect with a very high density of charge storage up to 2 ϫ 10 13 /cm 2 in the Ge nanocrystals and a maximum flat band voltage shift of 3.2 V have been achieved for the trilayer structure of LAO͑8 nm͒ / Ge/ LAO͑3 nm͒ / Si. The memory structure utilizing the Ge nanocrystals grown in 1 min showed excellent charge retention characteristics, whereas the decay in memory capacitance after 10 4 s of stress under a flat band voltage was only 8%. These results suggest that this memory structure utilizing Ge nanocrystals embedded in a LAO dielectric offers a high potential for the further scaling of floating gate memory devices. In addition, the effects of Ge growth time, and thus the size and density of the Ge nanocrystals, to the charge storage and charge retention characteristics were also studied. Metal-oxide-semiconductor ͑MOS͒ memory structures based on Si quantum dots or nanocrystals have recently attracted a great deal of interest due to the physical phenomena and potential applications in scaled flash memory. [1][2][3][4] In this kind of memory structure, Si nanocrystals are embedded as charge-storage nodes in an oxide layer between the control gate and the tunneling layer, which can reduce the problem of charge loss encountered in conventional flash memories. It allows thinner injection oxides and, hence, smaller operating voltages, better endurance, and faster write/erase speeds. 1,2 The memory function of these devices has been attributed to the charge exchange between the nanocrystals and inversion layer. Most quantum dot flash memories use Si nanocrystals to replace the continuous floating gate layer. However, research results in several groups have demonstrated the superior properties of Ge-based nanocrystal memories over those based on Si. [4][5][6] The Ge nanocrystals offer improved nonvolatile charge retention time due to their smaller band gap. The smaller band gap provides both a higher confinement barrier for the retention mode and a smaller barrier for the program and erase modes. Various methods of fabrication have been reported to form the Ge dot, such as implantation of Ge ions in SiO 2 , 7 the sputter deposition of Ge on the Si substrate, 8 and the rapid thermal annealing of chemical-vapordeposited Ge layers. 9 Pulsed-laser deposition ͑PLD͒ has also proven to be very successful in the fabrication of complex oxide materials, and is also effective in the growth of Ge nanocrystals.High-k gate dielectrics have been extensively investigated for replacing SiO 2 in future MOS field effect transistors ͑MOSFETs͒. [10][11][12] In recent studies, high-k gate dielectrics were also used as the control and tunneling oxide layers in floating gate memor...

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Electrical study of Ge-nanocrystal-based metal-oxide-semiconductor structures for p-type nonvolatile memory applications

Cited by 120 publications

References 15 publications

Ge nanocrystals in alumina matrix: A structural study

Ge nanocrystals in alumina matrix: A structural study

Two-dimensional arrays of ordered, highly dense and ultra-small Ge nanocrystals on thin SiO₂layers

Synthesis and memory effect study of Ge nanocrystals embedded in LaAlO3 high-k dielectrics

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Electrical study of Ge-nanocrystal-based metal-oxide-semiconductor structures for p-type nonvolatile memory applications

Cited by 120 publications

References 15 publications

Ge nanocrystals in alumina matrix: A structural study

Ge nanocrystals in alumina matrix: A structural study

Two-dimensional arrays of ordered, highly dense and ultra-small Ge nanocrystals on thin SiO2layers

Synthesis and memory effect study of Ge nanocrystals embedded in LaAlO3 high-k dielectrics

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Two-dimensional arrays of ordered, highly dense and ultra-small Ge nanocrystals on thin SiO₂layers