Giant Random Telegraph Signals in Nanoscale Floating-Gate Devices

Fantini, Paolo; Ghetti, A.; Marinoni, Andrea; Ghidini, G.; Visconti, A.; Marmiroli, A.

doi:10.1109/led.2007.909835

Cited by 47 publications

(27 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Specifically, in nano-scaled devices a particularly troubling noise phenomenon called random telegraph noise (RTN) [6] has the potential to severely limit sub-V TH circuit design. RTN is a digital fluctuation in device drain current (I D ) which has already been identified as a large obstacle in super-V TH operation of both SRAM and FLASH memory technologies [7][8][9]. However, the impact of RTN on sub-V TH operation is only sporadically debated in the literature with very little consensus.…”

Section: Introductionmentioning

confidence: 99%

Large random telegraph noise in sub-threshold operation of nano-scale nMOSFETs

Campbell

Cheung

et al. 2009

2009 IEEE International Conference on IC Design and Technology

View full text Add to dashboard Cite

We utilize low-frequency noise measurements to examine the sub-threshold voltage (sub-V TH ) operation of highly scaled devices. We find that the sub-V TH low-frequency noise is dominated by random telegraph noise (RTN). The RTN is exacerbated both by channel dimension scaling and reducing the gate overdrive into the sub-V TH regime. These large RTN fluctuations greatly impact circuit variability and represent a troubling obstacle that must be solved if sub-V TH operation is to become a viable solution for low-power applications.

show abstract

Section: Introductionmentioning

confidence: 99%

Large random telegraph noise in sub-threshold operation of nano-scale nMOSFETs

Campbell

Cheung

et al. 2009

2009 IEEE International Conference on IC Design and Technology

View full text Add to dashboard Cite

show abstract

“…This held true even if unusually large values for the RTN amplitude had been consistently reported on some devices, together with complex time behaviors [79,82,[87][88][89], that seemed to defy Equation (2). When Flash memories made a large quantity of data readily available, making it possible to pinpoint and study anomalous behaviors occurring with extremely low probability, larger and larger fluctuation amplitudes emerged [90,91], and RTN became a serious reliability constraint in static random-access [92][93][94] and Flash memories [90,91,[95][96][97][98][99], prompting an intensive research effort to understand its root cause and impact on memory array operation. An example of the relevance of RTN is shown in Figure 4, where results obtained on a selected decananometer Flash cell are reported [91]: current fluctuations up to 60% were detected, which cannot be explained with the above theory.…”

Section: Rtn Amplitudementioning

confidence: 93%

“…When Flash memories made a large quantity of data readily available, making it possible to pinpoint and study anomalous behaviors occurring with extremely low probability, larger and larger fluctuation amplitudes emerged [90,91], and RTN became a serious reliability constraint in static random-access [92][93][94] and Flash memories [90,91,[95][96][97][98][99], prompting an intensive research effort to understand its root cause and impact on memory array operation. An example of the relevance of RTN is shown in Figure 4, where results obtained on a selected decananometer Flash cell are reported [91]: current fluctuations up to 60% were detected, which cannot be explained with the above theory. Though early explanations pointed to multiple carrier emissions [88,89], change in defect properties [87] or interacting quantum wells [82], a different approach based on the percolative nature of the current conduction around the charged trap site had been mentioned in [100] and thoroughly revisited in [101], exploiting a concept applied to amorphous semiconductors [102].…”

Section: Rtn Amplitudementioning

confidence: 99%

Reliability of NAND Flash Memories: Planar Cells and Emerging Issues in 3D Devices

2017

View full text Add to dashboard Cite

Abstract:We review the state-of-the-art in the understanding of planar NAND Flash memory reliability and discuss how the recent move to three-dimensional (3D) devices has affected this field. Particular emphasis is placed on mechanisms developing along the lifetime of the memory array, as opposed to time-zero or technological issues, and the viewpoint is focused on the understanding of the root causes. The impressive amount of published work demonstrates that Flash reliability is a complex yet well-understood field, where nonetheless tighter and tighter constraints are set by device scaling. Three-dimensional NAND have offset the traditional scaling scenario, leading to an improvement in performance and reliability while raising new issues to be dealt with, determined by the newer and more complex cell and array architectures as well as operation modes. A thorough understanding of the complex phenomena involved in the operation and reliability of NAND cells remains vital for the development of future technology nodes.

show abstract

“…On the other hand, in Flash memory, the focusing point of the nitridation has been a reliability improvement against high field Fowler-Nordheim (FN) stress (> 10 MV/cm) or channel hot carrier [2]. Such nitrogen incorporation is reported to generate high density defects in the oxide and results in worse RTS in both conventional MOSFETs [3] and Flash memory cells [4]. In particular, since the realization that multilevel cell in Flash memory is being limited by random telegraph signal (RTS) [5], applying tunnel oxide nitridation (TON) is expected to result in a tradeoff between reliability and RTS.…”

Section: Introductionmentioning

confidence: 99%

Tunnel Oxide Nitridation Effect on the Evolution of $V_{t}$ Instabilities (RTS/QED) and Defect Characterization for Sub-40-nm Flash Memory

Kim

Morinville

et al. 2011

IEEE Electron Device Lett.

View full text Add to dashboard Cite

We report the impact of tunnel oxide nitridation (TON) on the evolution of random telegraph signal (RTS) and quick electron detrapping (QED) and investigate their microscopic origin. Applying nitridation at the SiO 2 /Si interface increases both Fermi level (RTS) and general midgap (QED) defects in fresh devices. However, it slows down additional defect generation and demonstrates improvement after severe program/erase cycling. Results from low-frequency 1/f noise indicate that TON aggravates RTS for high energy defects but hardens low energy defects, resulting in improved postcycled RTS. The suggestive defect chemistry is that strong Si-N bonding replaces relatively stable (but distorted) Si-O bonding, rather than passivating high energy dangling bonds. The Si-N bonding also causes more interface bonds to break, reducing strain and improving immunity against Fowler-Nordheim stress.Index Terms-Defect chemistry, Flash memory, low-frequency (LF) 1/f noise, multilevel cell (MLC), nitridation, oxynitride, quick electron detrapping (QED), random telegraph signal (RTS), tunnel oxide.

show abstract

Giant Random Telegraph Signals in Nanoscale Floating-Gate Devices

Cited by 47 publications

References 16 publications

Large random telegraph noise in sub-threshold operation of nano-scale nMOSFETs

Large random telegraph noise in sub-threshold operation of nano-scale nMOSFETs

Reliability of NAND Flash Memories: Planar Cells and Emerging Issues in 3D Devices

Tunnel Oxide Nitridation Effect on the Evolution of $V_{t}$ Instabilities (RTS/QED) and Defect Characterization for Sub-40-nm Flash Memory

Contact Info

Product

Resources

About