Your search keyword '"Jeffrey Teng"' showing total 5 results

1. Demonstration of Ultra-Low Voltage and Ultra Low Power STT-MRAM designed for compatibility with 0x node embedded LLC applications

Author

Vignesh Sundar, Zhongjian Jeffrey Teng, Yu-Jen Wang, Jian Zhu, Luc Thomas, Ru-Ying Tong, Sahil Patel, Shen Dongna, Vinh Lam, Hideaki Fukuzawa, Yang Yi, Po-Kang Wang, Guenole Jan, Tom Zhong, Jesmin Haq, Son T. Le, Santiago Serrano-Guisan, Renren He, Huanlong Liu, Yuan-Jen Lee, and Jodi Iwata-Harms

Subjects

010302 applied physics, Very-large-scale integration, Magnetoresistive random-access memory, Ultra low power, business.industry, Computer science, 020208 electrical & electronic engineering, Electrical engineering, Word error rate, Time-dependent gate oxide breakdown, 02 engineering and technology, 01 natural sciences, 0103 physical sciences, Compatibility (mechanics), 0202 electrical engineering, electronic engineering, information engineering, business, Low voltage, Voltage

Abstract

We present for the first time STT-MRAM devices with ultra low operating voltage and power compatible with next generation 0x node logic voltages. By engineering the tunnel barrier and improving the efficiency of the devices we report a record low writing voltage of 0.17V for a 1ppm error rate, which has been achieved for a 20ns write operation using a writing current of only 35uA. We further demonstrate error rates below 10-9 at voltage and current at 0.25V and 50uA using 10ns writing pulses on the same 30nm devices with extended 400C thermal budget while preserving functionality confirm the almost unlimited endurance of these data and retention at 85°C. Finally, TDDB studies confirm the almost unlimited endurance of these devices at the operating voltage.

Published

2018

2. Achieving Sub-ns switching of STT-MRAM for future embedded LLC applications through improvement of nucleation and propagation switching mechanisms

Author

Vinh Lam, Jeffrey Teng, Son T. Le, Jodi Iwata-Harms, Santiago Serrano-Guisan, Guenole Jan, Yu-Jen Wang, Jian Zhu, Yuan-Jen Lee, Shen Dongna, Huanlong Liu, Luc Thomas, Sahil Patel, Ru-Ying Tong, Jesmin Haq, Po-Kang Wang, Renren He, Terry Torng, Rao Annapragada, and Tom Zhong

Subjects

Tunnel magnetoresistance, Engineering, Magnetoresistive random-access memory, Stack (abstract data type), business.industry, Electrical engineering, Electronic engineering, Nucleation, Pulse duration, Cache, Data retention, business

Abstract

We present recent advances in writing speed of pSTT_MRAM which demonstrate its potential as a candidate for replacement of LCC cache for advanced technology nodes as well as applications where non-volatility may be needed. In this paper we explore the feasibility of sub-ns switching of devices and their characterization using comprehensive time resolved electrical measurement of the reversal mechanism. We show that the switching mechanism can be described as a simple nucleation followed by propagation model that can be characterized statistically. We further demonstrate that after optimization of the Magnetic Tunnel Junction (MTJ) stack, single devices can be switched reliably using write pulse length down to 750ps while preserving functionality and data retention @ 125°C. Results of the integration at array level on an 8MB test vehicle are also presented allowing full array writing using 3ns pulses without ECC and demonstrated data retention of 10 years (1ppm) at 125°C.

Published

2016

3. Demonstration of an MgO based anti-fuse OTP design integrated with a fully functional STT-MRAM at the Mbit level

Author

Vinh Lam, Tom Zhong, Son T. Le, Luc Thomas, Yu-Jen Wang, Jian Zhu, Ru-Ying Tong, Terry Torng, Jesmin Haq, Shen Dongna, K. Pi, Po-Kang Wang, Yuan-Jen Lee, Renren He, Jeffrey Teng, Guenole Jan, Huanlong Liu, and Rao Annapragada

Subjects

Engineering, Magnetoresistive random-access memory, CMOS, Megabit, business.industry, Reading (computer), Voltage divider, Electronic engineering, Fuse (electrical), Electrical engineering, Breakdown voltage, business, Voltage drop

Abstract

STT-MRAM technology has been attracting renewed attention since the embedability of a working STT-MRAM design has been demonstrated [1]. In this paper we expand on the versatility of STT-MRAM by demonstrating the conversion of a standard STT-MRAM cell to a One Time Programmable (OTP) anti-fuse cell. Both designs are integrated at the Mbit level on a single chip using the same magnetic stack, processing and CMOS cell design. A single BEOL mask change can convert an STT-MRAM device to an OTP design by simply reducing its size. The increased resistance yields larger voltage drop across the device, due to the voltage divider effect in the 1T-1MTJ cell and is sufficient to trigger reliable dielectric breakdown of the oxide tunnel barrier, effectively shorting the device. In this paper we demonstrate the seamless integration of an OTP based on STT-MRAM and 100% programming and reading yield at the Mbit level.

Published

2015

4. Demonstration of fully functional 8Mb perpendicular STT-MRAM chips with sub-5ns writing for non-volatile embedded memories

Author

Jesmin Haq, Vinh Lam, Shen Dongna, Po-Kang Wang, Guenole Jan, Luc Thomas, K. Pi, Huanlong Liu, Kenlin Huang, Ru-Ying Tong, Terry Torng, Jeffrey Teng, Le Son, Renren He, Yu-Jen Wang, Jian Zhu, Yuan-Jen Lee, and Tom Zhong

Subjects

Magnetoresistive random-access memory, business.industry, Computer science, Scalability, Electronic engineering, Perpendicular, Data retention, business, Error detection and correction, Chip, Computer hardware

Abstract

We present major breakthroughs in MTJ design for STT-MRAM applications allowing reliable write for pulse lengths down to 1.5ns, data retention up to 125°C for 10 years and full compatibility with BEOL process up to 400°C for 1 hour. We have successfully integrated the novel structure onto an 8Mbit test chip. We demonstrate writing of every single cell in the array using sub-5ns pulses over a wide temperature range without using any error correction. We also show that sensing times of 4ns are sufficient to read every data cell. The inherent scalability of the design makes it a prime candidate for universal embedded non-volatile memories down to the 28nm node and beyond.

Published

2014

5. Perpendicular spin transfer torque magnetic random access memories with high spin torque efficiency and thermal stability for embedded applications (invited)

Author

Son Thai Le, Jesmin Haq, Luc Thomas, Yu-Jen Wang, Ru-Ying Tong, Guenole Jan, Jian Zhu, Terry Torng, Kenlin Huang, Po-Kang Wang, Jeffrey Teng, Renren He, K. Pi, Tom Zhong, Yuan-Jen Lee, Huanlong Liu, Shen Dongna, and Vinh Lam

Subjects

Physics, Condensed matter physics, Magnetoresistance, business.industry, Electrical engineering, Spin-transfer torque, General Physics and Astronomy, Tunnel magnetoresistance, Tunnel effect, CMOS, Stack (abstract data type), Torque, business, Random access

Abstract

Magnetic random access memories based on the spin transfer torque phenomenon (STT-MRAMs) have become one of the leading candidates for next generation memory applications. Among the many attractive features of this technology are its potential for high speed and endurance, read signal margin, low power consumption, scalability, and non-volatility. In this paper, we discuss our recent results on perpendicular STT-MRAM stack designs that show STT efficiency higher than 5 kBT/μA, energy barriers higher than 100 kBT at room temperature for sub-40 nm diameter devices, and tunnel magnetoresistance higher than 150%. We use both single device data and results from 8 Mb array to demonstrate data retention sufficient for automotive applications. Moreover, we also demonstrate for the first time thermal stability up to 400 °C exceeding the requirement of Si CMOS back-end processing, thus opening the realm of non-volatile embedded memory to STT-MRAM technology.

Published

2014