Ji-Sang Lee

A 64Gb 533Mb/s DDR interface MLC NAND Flash in sub-20nm technology

The market growth of mobile applications such as smart phones and tablet computers has fueled the explosive demand of NAND Flash memories having high density and fast throughput. To meet such a demand, we present a 64Gb multilevel cell (MLC) NAND Flash memory having 533Mb/s DDR interface in sub-20nm technology. Large floating-gate (FG) coupling interference and program disturbance are major challenges to impede the scaling of NAND Flash memories in sub-20nm technology node [1]. In this paper, we present correction-before-coupling (CBC) reprogram and P3-pattern pre-pulse scheme, allowing us to overcome large FG coupling interferences. We improve program disturbance by inventing inhibit-channel-coupling-reduction (ICCR) technique. In addition, we achieve a 533Mb/s DDR interface by employing a wave-pipeline architecture [2].

7.2 A 128Gb 3b/cell V-NAND flash memory with 1Gb/s I/O rate

Most memory-chip manufacturers keep trying to supply cost-effective storage devices with high-performance characteristics such as smaller tPROG, lower power consumption and longer endurance. For many years, every effort has been made to shrink die size to lower cost and to improve performance. However, the previously used node-shrinking methodology is facing challenges due to increased cell-to-cell interference and patterning difficulties caused by decreasing dimension. To overcome these limitations, 3D-stacking technology has been developed. As a result of long and focused research in 3D stacking technology, 128Gb 2b/cell device with 24 stack WL layers was announced in 2014 [1].

11.4 A 512Gb 3b/cell 64-stacked WL 3D V-NAND flash memory

The advent of emerging technologies such as cloud computing, big data, the internet of things and mobile computing is producing a tremendous amount of data. In the era of big data, storage devices with versatile characteristics are required for ultra-fast processing, higher capacity storage, lower cost, and lower power operation. SSDs employing 3D NAND are a promising to meet these requirements. Since the introduction of 3D NAND technology to marketplace in 2014 [1], the memory array size has nearly doubled every year [2,3]. To continue scaling 3D NAND array density, it is essential to scale down vertically to minimize total mold height. However, vertical scaling results in critical problems such as increasing WL capacitance and non-uniformity of stacked WLs due to variation in the channel hole diameter. To tackle these issues, this work proposes schemes for programming speed improvement and power reduction, and on-chip processing algorithms for error correction.