Memristor

Memristor
Memristor
Type Passive
Working principle Memristance
Invented Leon Chua (1971)
First production HP Labs (2008)
Electronic symbol
Memristor-Symbol.svg

Memristor (pronounced /ˈmɛmrɨstər/; a portmanteau of "memory resistor") is a passive two-terminal electrical component in which there is a functional relationship between electric charge and magnetic flux linkage. When current flows in one direction through the device, the electrical resistance increases; and when current flows in the opposite direction, the resistance decreases.[1] When the current is stopped, the component retains the last resistance that it had, and when the flow of charge starts again, the resistance of the circuit will be what it was when it was last active.[2] It has a regime of operation with an approximately linear charge-resistance relationship as long as the time-integral of the current stays within certain bounds.[3]

Memristor theory was formulated and named by Leon Chua in a 1971 paper.[4] In 2008, a team at HP Labs announced the development of a switching memristor based on a thin film of titanium dioxide.[5] These devices are being developed for application in nanoelectronic memories, computer logic, and neuromorphic computer architectures.[6] In October 2011, the same team announced the commercial availability of memristor technology within 18 months, as a replacement for Flash, SSD, DRAM and SRAM. [7]

An array of 17 purpose-built oxygen-depleted titanium dioxide memristors built at HP Labs, imaged by an atomic force microscope. The wires are about 50 nm, or 150 atoms, wide.[8] Electric current through the memristors shifts the oxygen vacancies, causing a gradual and persistent change in electrical resistance.[9]

Contents

Background

In his 1971 paper, Chua extrapolated the conceptual symmetry between the resistor, inductor, and capacitor, and inferred the memristor was a similarly fundamental device. However, it has a nonlinear relationship between current and voltage, like the varistor. Other scientists had already proposed fixed nonlinear flux-charge relationships, but Chua's theory introduced generality.

The resistance of a memristor depends on the integral of the input applied to the terminals (rather than on the instantaneous value of the input as in a varistor).[10] Since the element "remembers" the amount of current that has passed through it in the past, it was tagged by Chua with the name "memristor". Another way of describing a memristor is that it is any passive two-terminal circuit elements that maintains a functional relationship between the time integral of current (called charge) and the time integral of voltage (often called flux, as it is related to magnetic flux). The slope of this function is called the memristance M and is similar to variable resistance. Batteries can be considered to have memristance, but they are not passive devices.

The definition of the memristor is based solely on the fundamental circuit variables of current and voltage and their time-integrals, just like the resistor, capacitor, and inductor. Unlike those three elements however, which are allowed in linear time-invariant or LTI system theory, memristors of interest have a nonlinear function and may be described by any of a variety of functions of net charge. There is no such thing as a standard memristor. Instead, each device implements a particular function, wherein the integral of voltage determines the integral of current, and vice versa. A linear time-invariant memristor, with a constant value for M, is simply a conventional resistor.[4] Like other two-terminal components (e.g., resistor, capacitor, inductor), real-world devices are never purely memristors ("ideal memristor"), but will also exhibit some amount of capacitance, resistance, and inductance.

Theory

The memristor is essentially a two-terminal variable resistor, with resistance dependent upon the amount of charge q that has passed between the terminals.

V = I \cdot M(q)

To relate the memristor to the resistor, capacitor, and inductor, it is helpful to isolate the term M(q), which characterizes the device, and write it as a differential equation:

M = \frac{d\phi_m}{dQ}

where Q is defined by I = \frac{dQ}{dt}, and ϕm is defined by V = \frac{d\phi_m}{dt}. Note that the above table covers all meaningful ratios of I, Q, Φm, and V. No device can relate I to Q, or Φm to V, because I is the derivative of Q and Φm is the integral of V.

The variable Φm ("magnetic flux linkage") is generalized from the circuit characteristic of an inductor. It does not represent a magnetic field here, and its physical meaning is discussed below. The symbol Φm may simply be regarded as the integral of voltage over time.[11]

Thus, the memristor is formally defined[4] as a two-terminal element in which the flux linkage (or integral of voltage) Φm between the terminals is a function of the amount of electric charge Q that has passed through the device. Each memristor is characterized by its memristance function describing the charge-dependent rate of change of flux with charge.

M(q)=\frac{\mathrm d\Phi_m}{\mathrm dq}

Substituting that the flux is simply the time integral of the voltage, and charge is the time integral of current, we may write the more convenient form

M(q(t))=\cfrac{\mathrm d\Phi_m/\mathrm dt}{\mathrm dq/\mathrm dt}=\frac{V(t)}{I(t)}

It can be inferred from this that memristance is simply charge-dependent resistance. If M(q(t)) is a constant, then we obtain Ohm's Law R(t) = V(t)/ I(t). If M(q(t)) is nontrivial, however, the equation is not equivalent because q(t) and M(q(t)) will vary with time. Solving for voltage as a function of time we obtain

V(t) =\ M(q(t)) I(t)

This equation reveals that memristance defines a linear relationship between current and voltage, as long as M does not vary with charge. Of course, nonzero current implies time varying charge. Alternating current, however, may reveal the linear dependence in circuit operation by inducing a measurable voltage without net charge movement—as long as the maximum change in q does not cause much change in M.

Furthermore, the memristor is static if no current is applied. If I(t) = 0, we find V(t) = 0 and M(t) is constant. This is the essence of the memory effect.

The power consumption characteristic recalls that of a resistor, I2R.

P(t) =\ I(t)V(t) =\ I^2(t) M(q(t))

As long as M(q(t)) varies little, such as under alternating current, the memristor will appear as a constant resistor. If M(q(t)) increases rapidly, however, current and power consumption will quickly stop.

Derivation of "flux linkage" in a passive device

In an inductor, magnetic flux Φm relates to Faraday's law of induction, which states that the energy to push charges around a loop (electromotive force, in units of Volts) equals the negative derivative of the flux through the loop:

\mathcal E = -\frac{\mathrm d\Phi_\mathrm m}{\mathrm dt}

This notion may be extended by analogy to a single device. Working against an accelerating force (which may be EMF, or any applied voltage), a resistor produces a decelerating force, and an associated "flux linkage" varying with opposite sign. For example, a high-valued resistor will quickly produce flux linkage. The term "flux linkage" is generalized from the equation for inductors, where it represents a physical magnetic flux: If 1 Volt is applied across an inductor for 1 second, then there is 1 V·s of flux linkage in the inductor, which represents energy stored in a magnetic field that may later be obtained from it. The same voltage over the same time across a resistor results in the same flux linkage (as defined here, in units of V·s), but the energy is dissipated, rather than stored in a magnetic field — there is no physical magnetic field involved as a link to anything. Voltage for passive devices is evaluated in terms of energy lost by a unit of charge, so generalizing the above equation simply requires reversing the sense of EMF.

V = \frac{\mathrm d\Phi_\mathrm m}{\mathrm dt\,}
\Phi_\mathrm m = \int V\mathrm dt

Observing that Φm is simply equal to the integral over time of the potential drop between two points, we find that it may readily be calculated, for example by an operational amplifier configured as an integrator.

Two unintuitive concepts are at play:

  • Magnetic flux is defined here as generated by a resistance in opposition to an applied field or electromotive force. In the absence of resistance, flux due to constant EMF, and the magnetic field within the circuit, would increase indefinitely. The opposing flux induced in a resistor must also increase indefinitely so the sum with applied EMF remains finite.
  • Any appropriate response to applied voltage may be called "magnetic flux", as the term is used here.

The upshot is that a passive element may relate some variable to flux without storing a magnetic field. Indeed, a memristor always appears instantaneously as a resistor. As shown above, assuming non-negative resistance, at any instant it is dissipating power from an applied EMF and thus has no outlet to dissipate a stored field into the circuit. This contrasts with an inductor, for which a magnetic field stores all energy originating in the potential across its terminals, later releasing it as an electromotive force within the circuit.

Physical restrictions on M(q)

M(q) is physically restricted to be positive for all values of q (assuming the device is passive and does not become superconductive at some q). A negative value would mean that it would perpetually supply energy when operated with alternating current.

An applied constant voltage potential results in uniformly increasing Φm. It is not realistic for the function M(q) to contain an infinite amount of information over this infinite range. Three alternatives avoid this physical impossibility:

  • M(q) approaches zero, such that Φm = ∫M(q)dq = ∫M(q(t))I(t) dt remains bounded, but continues changing at an ever-decreasing rate. Eventually, this would encounter some kind of quantization and non-ideal behavior.
  • M(q) is periodic, so that M(q) = M(q − Δq) for all q and some Δq, e.g. sin2(q/Q).
  • The device enters hysteresis once a certain amount of charge has passed through, or otherwise ceases to act as a memristor.

Memristive systems

The memristor was generalized to memristive systems in a 1976 paper by Leon Chua.[12] Whereas a memristor has mathematically scalar state, a system has vector state. The number of state variables is independent of, and usually greater than, the number of terminals.

In this paper, Chua applied this model to empirically observed phenomena, including the Hodgkin-Huxley model of the axon and a thermistor at constant ambient temperature. He also described memristive systems in terms of energy storage and easily observed electrical characteristics. These characteristics match resistive random-access memory and phase-change memory, relating the theory to active areas of research.

In the more general concept of an n-th order memristive system the defining equations are

V(t)=M(\textbf{w},I,t)I(t),
\dot{\textbf{w}}=f(\textbf{w},I,t)

where the vector w represents a set of n state variables describing the device.[13] The pure memristor is a particular case of these equations, namely when M depends only on charge (w=q) and since the charge is related to the current via the time derivative dq/dt=I. For pure memristors f is not an explicit function of I.[13]

Operation as a switch

For some memristors, applied current or voltage will cause a great change in resistance. Such devices may be characterized as switches by investigating the time and energy that must be spent in order to achieve a desired change in resistance. Here we will assume that the applied voltage remains constant and solve for the energy dissipation during a single switching event. For a memristor to switch from Ron to Roff in time Ton to Toff, the charge must change by ΔQ = QonQoff.

E_{\mathrm{switch}}
=\ V^2\int_{T_\mathrm{off}}^{T_\mathrm{on}} \frac{\mathrm dt}{M(q(t))}
=\ V^2\int_{Q_\mathrm{off}}^{Q_\mathrm{on}}\frac{\mathrm dq}{I(q)M(q)}
=\ V^2\int_{Q_\mathrm{off}}^{Q_\mathrm{on}}\frac{\mathrm dq}{V(q)} =\ V\Delta Q

To arrive at the final expression, substitute V=I(q)M(q), and then ∫dq/V = ∆Q/V for constant V. This power characteristic differs fundamentally from that of a metal oxide semiconductor transistor, which is a capacitor-based device. Unlike the transistor, the final state of the memristor in terms of charge does not depend on bias voltage.

The type of memristor described by Williams ceases to be ideal after switching over its entire resistance range and enters hysteresis, also called the "hard-switching regime".[10] Another kind of switch would have a cyclic M(q) so that each off-on event would be followed by an on-off event under constant bias. Such a device would act as a memristor under all conditions, but would be less practical.

Implementations

Titanium dioxide memristor

Interest in the memristor revived when an experimental solid state version was reported by R. Stanley Williams of Hewlett Packard.[14][15][16] The article was the first to demonstrate that a solid-state device could have the characteristics of a memristor based on the behavior of nanoscale thin films. The device neither uses magnetic flux as the theoretical memristor suggested, nor stores charge as a capacitor does, but instead achieves a resistance dependent on the history of current.

Although not cited in HP's initial reports on their TiO2 memristor, the resistance switching characteristics of titanium dioxide was originally described in the 1960s.[17]

The HP device is composed of a thin (50 nm) titanium dioxide film between two 5 nm thick electrodes, one Ti, the other Pt. Initially, there are two layers to the titanium dioxide film, one of which has a slight depletion of oxygen atoms. The oxygen vacancies act as charge carriers, meaning that the depleted layer has a much lower resistance than the non-depleted layer. When an electric field is applied, the oxygen vacancies drift (see Fast ion conductor), changing the boundary between the high-resistance and low-resistance layers. Thus the resistance of the film as a whole is dependent on how much charge has been passed through it in a particular direction, which is reversible by changing the direction of current.[10] Since the HP device displays fast ion conduction at nanoscale, it is considered as a nanoionic device.[18]

Memristance is displayed only when both the doped layer and depleted layer contribute to resistance. When enough charge has passed through the memristor that the ions can no longer move, the device enters hysteresis. It ceases to integrate q=∫Idt, but rather keeps q at an upper bound and M fixed, thus acting as a constant resistor until current is reversed.

Memory applications of thin-film oxides had been an area of active investigation for some time. IBM published an article in 2000 regarding structures similar to that described by Williams.[19] Samsung has a U.S. patent for oxide-vacancy based switches similar to that described by Williams.[20] Williams also has a pending U.S. patent application related to the memristor construction.[21]

Although the HP memristor is a major discovery for electrical engineering theory, it has yet to be demonstrated in operation at practical speeds and densities. Graphs in Williams' original report show switching operation at only ~1 Hz. Although the small dimensions of the device seem to imply fast operation, the charge carriers move very slowly, with an ion mobility of 10−10 cm2/(Vs). In comparison, the highest known drift ionic mobilities occur in advanced superionic conductors, such as rubidium silver iodide with about 2×10−4 cm2/(Vs) conducting silver ions at room temperature. Electrons and holes in silicon have a mobility ~1000 cm2/(Vs), a figure which is essential to the performance of transistors. However, a relatively low bias of 1 volt was used, and the plots appear to be generated by a mathematical model rather than a laboratory experiment.[10]

In April 2010, HP labs announced that they had practical memristors working at 1 ns (~1 GHz) switching times and 3 nm by 3 nm sizes, with electron/hole mobility of 1 m/s,[22] which bodes well for the future of the technology.[23] At these densities it could easily rival the current sub-25 nm flash memory technology.

Polymeric memristor

In July 2008, Victor Erokhin and Marco P. Fontana, in Electrochemically controlled polymeric device: a memristor (and more) found two years ago,[24] claim to have developed a polymeric memristor before the titanium dioxide memristor more recently announced.

In 2004, Juri H. Krieger and Stuart M. Spitzer published a paper "Non-traditional, Non-volatile Memory Based on Switching and Retention Phenomena in Polymeric Thin Films"[25] at the IEEE Non-Volatile Memory Technology Symposium, describing the process of dynamic doping of polymer and inorganic dielectric-like materials in order to improve the switching characteristics and retention required to create functioning nonvolatile memory cells. Described is the use of a special passive layer between electrode and active thin films, which enhances the extraction of ions from the electrode. It is possible to use fast ion conductor as this passive layer, which allows to significantly decrease the ionic extraction field.

Spin memristive systems

Spintronic Memristor

Yiran Chen and Xiaobin Wang, researchers at disk-drive manufacturer Seagate Technology, in Bloomington, Minnesota, described three examples of possible magnetic memristors in March, 2009 in IEEE Electron Device Letters.[26] In one of the three, resistance is caused by the spin of electrons in one section of the device pointing in a different direction than those in another section, creating a "domain wall", a boundary between the two states. Electrons flowing into the device have a certain spin, which alters the magnetization state of the device. Changing the magnetization, in turn, moves the domain wall and changes the device's resistance.

This work attracted significant attention from the electronics press, including an interview by IEEE Spectrum.[27]

Spin Torque Transfer Magnetoresistance

Spin Torque Transfer MRAM is a well-known device that exhibits memristive behavior. The resistance is dependent on the relative spin orientation between two sides of a magnetic tunnel junction. This in turn can be controlled by the spin torque induced by the current flowing through the junction. However, the length of time the current flows through the junction determines the amount of current needed, i.e., the charge flowing through is the key variable.[28]
Additionally, as reported by Krzysteczko et al.,[29] MgO based magnetic tunnel junctions show memristive behavior based on the drift of oxygen vacancies within the insulating MgO layer (resistive switching). Therefore, the combination of spin transfer torque and resistive switching leads naturally to a second-order memristive system with w=(w1,w2) where w1 describes the magnetic state of the magnetic tunnel junction and w2 denotes the resistive state of the MgO barrier. Note that in this case the change of w1 is current-controlled (spin torque is due to a high current density) whereas the change of w2 is voltage-controlled (the drift of oxygen vacancies is due to high electric fields).

Spin Memristive System

A fundamentally different mechanism for memristive behavior has been proposed by Yuriy V. Pershin and Massimiliano Di Ventra in their paper "Spin memristive systems".[30] The authors show that certain types of semiconductor spintronic structures belong to a broad class of memristive systems as defined by Chua and Kang.[12] The mechanism of memristive behavior in such structures is based entirely on the electron spin degree of freedom which allows for a more convenient control than the ionic transport in nanostructures. When an external control parameter (such as voltage) is changed, the adjustment of electron spin polarization is delayed because of the diffusion and relaxation processes causing a hysteresis-type behavior. This result was anticipated in the study of spin extraction at semiconductor/ferromagnet interfaces,[31] but was not described in terms of memristive behavior. On a short time scale, these structures behave almost as an ideal memristor.[4] This result broadens the possible range of applications of semiconductor spintronics and makes a step forward in future practical applications of the concept of memristive systems.

Manganite memristive systems

Although not described using the word "memristor", a study was done of bilayer oxide films based on manganite for non-volatile memory by researchers at the University of Houston in 2001.[32] Some of the graphs indicate a tunable resistance based on the number of applied voltage pulses similar to the effects found in the titanium dioxide memristor materials described in the Nature paper "The missing memristor found".

Resonant tunneling diode memristor

In 1994, F. A. Buot and A. K. Rajagopal of the U.S. Naval Research Laboratory demonstrated[33] that a 'bow-tie' current-voltage (I-V) characteristics occurs in AlAs/GaAs/AlAs quantum-well diodes containing special doping design of the spacer layers in the source and drain regions, in agreement with the published experimental results.[34] This 'bow-tie' current-voltage (I-V) characteristic is characteristic of a memristor although the term memristor was not explicitly used in their papers. No magnetic interaction is involved in the analysis of the 'bow-tie' I-V characteristics.

Potential applications

Williams' solid-state memristors can be combined into devices called crossbar latches, which could replace transistors in future computers, taking up a much smaller area.

They can also be fashioned into non-volatile solid-state memory, which would allow greater data density than hard drives with access times potentially similar to DRAM, replacing both components.[35] HP prototyped a crossbar latch memory using the devices that can fit 100 gigabits in a square centimeter,[5] and has designed a highly scalable 3D design (consisting of up to 1000 layers or 1 petabit per cm3).[citation needed] HP has reported that its version of the memristor is currently about one-tenth the speed of DRAM.[36] The devices' resistance would be read with alternating current so that the stored value would not be affected.[37]

Some patents related to memristors appear to include applications in programmable logic,[38] signal processing,[39] neural networks,[40] and control systems.[41] Memristive devices can be potentially used for stateful logic implication, allowing a replacement for CMOS-based logic computation. Several early works in this direction is reported. [42] [43]


In the mid 2000's, a simple electronic circuit[44] consisting of an LC network and a memristor was used to model experiments on adaptive behavior of unicellular organisms.[45] It was shown that the electronic circuit subjected to a train of periodic pulses learns and anticipates the next pulse to come, similarly to the behavior of slime molds Physarum polycephalum where the viscosity of channels in the cytoplasm respond to periodic changes of environment.[45] Such a learning circuit may find applications, e.g., in pattern recognition. The DARPA’s SyNAPSE project has funded HP Labs, in collaboration with the Boston University Neuromorphics Lab, to develop neuromorphic architectures which may be based on memristive systems. In 2010, Massimiliano Versace and Ben Chandler co-wrote an article [46] describing the MoNETA (Modular Neural Exploring Traveling Agent) model. MoNETA is the first large-scale neural network model to implement whole-brain circuits to power a virtual and robotic agent compatibly with memristive hardware computations. The software used to implement MoNETA, Cog Ex Machina, has been featured on the cover page of IEEE Computer in February 2011 in a joint article [47] by HP Labs and the Boston University Neuromorphics Lab. Application of the memristor crossbar structure in the construction of analog soft computing system is demonstrated by Farnood Merrikh-Bayat and Saeed Bagheri Shouraki [48]. They have also shown in 2011 [49] how memristor crossbars can be combined with fuzzy logic to create analog memristive neuro-fuzzy computing system with fuzzy input and output terminals. Learning of this system is based on the creation of fuzzy relations inspired from Hebbian learning rule.

Memcapacitors and meminductors

In 2009, Massimiliano Di Ventra, Yuriy Pershin and Leon Chua co-wrote an article[50] extending the notion of memristive systems to capacitive and inductive elements in the form of memcapacitors and meminductors whose properties depend on the state and history of the system.

Historical timeline

See also

References

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