Samsung now mass-producing industry's first 2nd-generation, 10-nanometer class DRAM

December 21, 2017, Samsung
Samsung now mass-producing industry’s first 2nd-generation, 10-nanometer class DRAM
Credit: Samsung

Samsung Electronics announced today that it has begun mass producing the industry's first 2nd-generation of 10-nanometer class (1y-nm), 8-gigabit (Gb) DDR4 DRAM. For use in a wide range of next-generation computing systems, the new 8Gb DDR4 features the highest performance and energy efficiency for an 8Gb DRAM chip, as well as the smallest dimensions.

"By developing innovative technologies in DRAM circuit design and process, we have broken through what has been a major barrier for DRAM scalability," said Gyoyoung Jin, president of Memory Business at Samsung Electronics. "Through a rapid ramp-up of the 2nd-generation 10nm-class DRAM, we will expand our overall 10nm-class DRAM production more aggressively, in order to accommodate strong market demand and continue to strengthen our business competitiveness."

Samsung's 2nd-generation 10nm-class 8Gb DDR4 features an approximate 30 percent productivity gain over the company's 1st–generation 10nm-class 8Gb DDR4. In addition, the new 8Gb DDR4's performance levels and energy efficiency have been improved about 10 and 15 percent respectively, thanks to the use of an advanced, proprietary circuit design technology. The new 8Gb DDR4 can operate at 3,600 megabits per second (Mbps) per pin, compared to 3,200 Mbps of the company's 1x-nm 8Gb DDR4.

To enable these achievements, Samsung has applied new technologies, without the use of an EUV process. The innovation here includes use of a high-sensitivity cell data sensing system and a progressive "air spacer" scheme.

Samsung now mass-producing industry’s first 2nd-generation, 10-nanometer class DRAM
Credit: Samsung

In the cells of Samsung's 2nd-generation 10nm-class DRAM, a newly devised data sensing system enables a more accurate determination of the data stored in each cell, which leads to a significant increase in the level of circuit integration and manufacturing productivity.

The new 10nm-class DRAM also makes use of a unique air spacer that has been placed around its bit lines to dramatically decrease parasitic capacitance. Use of the air spacer enables not only a higher level of scaling, but also rapid cell operation.

With these advancements, Samsung is now accelerating its plans for much faster introductions of next-generation DRAM chips and systems, including DDR5, HBM3, LPDDR5 and GDDR6, for use in enterprise servers, mobile devices, supercomputers, HPC systems and high-speed graphics cards.

Samsung has finished validating its 2nd-generation 10nm-class DDR4 modules with CPU manufacturers, and next plans to work closely with its global IT customers in the development of more efficient next-generation computing systems.

In addition, the world's leading DRAM producer expects to not only rapidly increase the production volume of the 2nd-generation 10nm-class DRAM lineups, but also to manufacture more of its mainstream 1st-generation 10nm-class DRAM, which together will meet the growing demands for DRAM in premium electronic systems worldwide.

Explore further: Samsung starts mass producing industry's first 10-nanometer class DRAM

Related Stories

Samsung rolls out industry's first 8GB LPDDR4 DRAM package

October 25, 2016

Samsung Electronics announced today that it is introducing the industry's first 8-gigabyte (GB) LPDDR4 (low power, double data rate 4) mobile DRAM package, which is expected to greatly improve mobile user experiences, especially ...

Recommended for you

What can snakes teach us about engineering friction?

May 21, 2018

If you want to know how to make a sneaker with better traction, just ask a snake. That's the theory driving the research of Hisham Abdel-Aal, Ph.D., an associate teaching professor from Drexel University's College of Engineering ...

Flexible, highly efficient multimodal energy harvesting

May 21, 2018

A 10-fold increase in the ability to harvest mechanical and thermal energy over standard piezoelectric composites may be possible using a piezoelectric ceramic foam supported by a flexible polymer support, according to Penn ...

0 comments

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.