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Phasechange random access memory: A scalable technology

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... Current-Voltage Curve. Threshold switching. Higher conductivity after the Threshold voltage not ... Voltages may end up too close (for set, reset, read) ... – PowerPoint PPT presentation

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Title: Phasechange random access memory: A scalable technology


1
Phase-change random access memory A scalable
technology
  • S. Raoux, G.W. Burr, M.J. Breitwisch, C.T.
    Rettner, Y.-C. Chen, R.M. Shelby, M. Salinga, D.
    Krebs, S.-H. Chen, H.-L. Lung, C.H. Lam
  • Presentation by
  • Ioannis Papadopoulos
  • ipapadop_at_cse.tamu.edu

2
Phase-Change Memory Overview
  • Phase Change Memory (PCRAM) is based on
    phase-change materials
  • At least two phases with completely different
    properties
  • In the case of PCRAM, property is electrical
    conductivity differs at least 5 orders of
    magnitude between the two states
  • Crystallized phase (SET) logical 1 (low
    resistance)
  • Amorphous phase (RESET) logical 0 (high
    resistance)
  • Change from SET to RESET short, powerful current
    pulse
  • Change from RESET to SET longer, less powerful
    pulse
  • Read short, weak pulse

3
PCRAM Current-Voltage Curve
  • Threshold switching
  • Higher conductivity after the Threshold voltage
    not completely explained
  • Probably due to impact ionization, carrier
    recombination
  • The reason that PCRAM is feasible and interesting
    as technology

4
WARNING!
  • The rest of the paper is more of interest to
  • Physists
  • Chemical Engineers
  • Electrical Engineers with focus on manufacturing
    and analog circuit analysis
  • So I'm going to present the same content focused
    instead for
  • Computer Scientists and
  • Computer Engineers
  • You can find the original paper on
  • http//portal.acm.org/citation.cfm?id1462871.1462
    885

5
Support for PCRAM from manufacturers
  • Increased system functionality means
  • More megabytes
  • Smaller size
  • Higher speeds
  • Most are reluctant to invest until sure that
  • The technology works
  • It scales for more than one generation
  • Transition costs and is risky
  • Will only be done if results are promising and
    future looks bright

6
The Scaling Problem
  • It needs to be shown that the technology scales
  • Scalability studies to
  • Forsee roadblocks
  • Estimate the far future
  • What does the PCRAM cell serve? How small can it
    become?
  • Critical characteristics
  • SET/RESET resistance distributions
  • Ability to switch between states
  • Ability to read without petubation to the data
  • Life cycle
  • Data retention time
  • Fast SET speed

7
Possible problems with PCRAM
  • Voltages may end up too close (for set, reset,
    read)
  • Problems with doping of material when going in
    smaller scale
  • Can large currents be provided by the (current
    and future) device interfaces?
  • Are they realistic or practical?
  • Is PCRAM economically viable?
  • SET dictates speed, RESET consumption
  • Can the device be fast and energy-efficient?

8
Simulation importance
  • Reducing the current for RESET depends on a lot
    of factors
  • Predictive numerical simulations
  • Hybrid simulations that combine results from
    different types of simulations and experiments
  • Slow-thin film crystallization experiments
  • Optical-pulse experiments
  • Goal
  • Heat more efficiently the phase change material
  • Reduce the material

9
Phase change materials
  • The ultimate phase-change material
  • Low melting point (but not too low)
  • High resistance in crystallized form (but not too
    high)
  • Fast in crystallizing (but not too fast)
  • Be small (but not inexistant)
  • Mainly discovered by chemists
  • Too many parameters but we care about two
  • A material that can be used with CMOS technology
  • The device to work within common operating
    temperatures

10
PCRAM evolution
  • Size and dimension of materials
  • Thin films (1 dimension)
  • Nanowires (2 dimensions)
  • Nanoparticles (3 dimensions)
  • Sorry no 4th dimension but who knows...
  • Crystalization time
  • From 10µs down to 100ns
  • Phase change material is reduced
  • Lower voltages, lower currents, less power, lower
    temperatures
  • Lower temperatures increase data retention time
  • Different alloys have different characteristics
  • Still an open research area (for chemists)

11
Proof of Scaling
  • Phase change bridge
  • A simple research device
  • Two electrodes, a bridge of material
  • Waveform generator to create PCRAM-like pulses
  • Used to test new materials
  • Easy to construct for rapid prototyping
  • Experiments to estimate real PCRAM behaviour
  • Integration into a product is another issue
  • There are proposed methods though for lithography
    to support it

12
Paper Results
  • It is not a research presentation paper
  • It is a paper trying to prove through various
    research attempts that
  • PCRAM can scale
  • Is highly intergratable
  • Can provide products
  • The authors attempt to convince manufacturers and
    investors that
  • PCRAM research can lead to competitive products
  • PCRAM is as good, if not better, compared to
    Flash-Memory

13
Conclusion
  • Complete analysis of the scaling behaviour
  • Phase change materials can be scaled down
    considerably
  • High integration can be achieved
  • "Thus, in many aspects, PCRAM technology appears
    to be readily scalable to several future
    technology nodes"
  • In other words, PCRAM can replace flash-memory
  • Please pay attention and fund PCRAM research!!!

14
Thank you!!
  • Questions??
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