The present disclosure relates generally to All-Spin Logic Devices from which all-spin architectures may be constructed. The possible role of spin as an alternative to charge for logic applications has been recognized. Most spin-based proposals, however, use spin only as an internal variable (i.e., the terminal quantities of each individual logic gate are still charge-based). It has also been pointed out that collective entities like magnets may require significantly less switching energy than an equivalent number of non-interacting spins. Recently, there has been significant experimental progress in implementing different forms of magnet-based switching circuits. For instance, in the Magnetic Quantum Cellular Automata (MQCA) architecture, each magnet controls the switching of a neighboring magnet through its magnetic field. In MQCA circuits, interconnects are made of an array of magnets, which also require clocking by external magnetic fields. This scheme is not well-suited for general purpose computing due to the limited control over the nearest-neighbor interconnections.
According to one aspect, an all-spin logic device may comprise a first nanomagnet, a second nanomagnet, and a spin-coherent channel extending between the first and second nanomagnets. The spin-coherent channel may be configured to conduct a spin current from the first nanomagnet to the second nanomagnet to determine a state of the second nanomagnet in response to a state of the first nanomagnet.
In some embodiments, the first and second nanomagnets may have identical switching characteristics. The all-spin logic device may further comprise a tunnel barrier disposed at an interface between the spin-coherent channel and one of the first and second nanomagnets. The second nanomagnet may comprise a free layer having an easy axis and a fixed layer having an easy axis, where the easy axis of the fixed layer is perpendicular to the easy axis of the free layer.
In other embodiments, the first and second nanomagnets may each be electrically coupled to one un-clocked supply voltage. The second nanomagnet may have a greater spin-torque conductance relative to the spin-coherent channel than the first nanomagnet. The spin-coherent channel may comprise a ground terminal positioned closer to the first nanomagnet than to the second nanomagnet.
In still other embodiments, second nanomagnet may be electrically coupled to a floating voltage. Alternatively, the second nanomagnet may be grounded. The first and second nanomagnets may each have an energy barrier of at least one-quarter electron-volt and may each comprise less than 106 Bohr magnetons.
According to another aspect, an all-spin logic circuit may comprise a first nanomagnet having an input side and an output side, a second nanomagnet having an input side and an output side, a third nanomagnet having an input side and an output side, a first spin-coherent channel configured to conduct a spin current generated from the input side of the first nanomagnet to the output side of the second nanomagnet, and a second spin-coherent channel configured to conduct a spin current generated from the input side of the second nanomagnet to the output side of the third nanomagnet.
In some embodiments, the first, second, and third nanomagnets may have identical switching characteristics. The all-spin logic circuit may further comprise a third spin-coherent channel configured to conduct a spin current generated from the input side of the third nanomagnet to the output side of the first nanomagnet. The output sides of the first, second, and third nanomagnets each have a greater spin-torque conductance than the input sides of the first, second, and third nanomagnets.
In other embodiments, the first spin-coherent channel may comprise a ground terminal positioned closer to the input side of the first nanomagnet than to the output side of the second nanomagnet, and the second spin-coherent channel may comprise a ground terminal positioned closer to the input side of the second nanomagnet than to the output side of the third nanomagnet. The first and second spin-coherent channels may be separated by an isolation layer. The first, second, and third nanomagnets may each be electrically coupled to one unclocked supply voltage.
According to yet another aspect, a method may comprise applying a voltage to a first nanomagnet to generate a first spin current in response to a magnetization direction of the first nanomagnet and routing the first spin current along a first spin-coherent channel to a second nanomagnet to determine a magnetization direction of the second nanomagnet.
In some embodiments, the magnetization direction of the second nanomagnet does not determine the magnetization direction of the first nanomagnet. The method may further comprise applying a voltage to a third nanomagnet to generate a second spin current in response to a magnetization direction of the third nanomagnet and routing the second spin current along the first spin-coherent channel to the second nanomagnet to determine the magnetization direction of the second nanomagnet in response to a superposition of the first and second spin currents.
In other embodiments, the method may further comprise applying a voltage to the second nanomagnet to generate a second spin current in response to the magnetization direction of the second nanomagnet and routing the second spin current along a second spin-coherent channel to a third nanomagnet to determine a magnetization direction of the third nanomagnet. The method may also comprise applying a voltage to the third nanomagnet to generate a third spin current in response to the magnetization direction of the third nanomagnet and routing the third spin current along a third spin-coherent channel to the first nanomagnet to determine the magnetization direction of the first nanomagnet. Applying a voltage to the first nanomagnet and applying a voltage to the second nanomagnet may comprise applying one un-clocked supply voltage to both the first and second nanomagnets.
In still other embodiments, the method may further comprise applying a clocked supply voltage to a fixed layer of the second nanomagnet to place a free layer of the second nanomagnet in a neutral state while receiving the first spin current from the first spin-coherent channel. The method may further comprise applying a floating voltage to the second nanomagnet while receiving the first spin current from the first spin-coherent channel. The method may further comprise grounding the second nanomagnet while receiving the first spin current from the first spin-coherent channel. The magnetization direction of the second nanomagnet may oscillate with the magnetization direction of the first nanomagnet.
The invention described herein is illustrated by way of example and not by way of limitation in the accompanying figures. For simplicity and clarity of illustration, elements illustrated in the figures are not necessarily drawn to scale. For example, the dimensions of some elements may be exaggerated relative to other elements for clarity. Further, where considered appropriate, reference labels have been repeated among the figures to indicate corresponding or analogous elements.
While the concepts of the present disclosure are susceptible to various modifications and alternative forms, specific exemplary embodiments thereof have been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the concepts of the present disclosure to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives consistent with the present disclosure and appended claims.
References in the specification to “one embodiment,” “an embodiment,” “an example embodiment,” etcetera, indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.
The present disclosure relates to All-Spin Logic Devices (ASLD) comprising a number of nanomagnets linked by a number of spin-coherent channels. The nanomagnets of the ASLD may be switched between their stable states representing binary data (e.g., right-magnetized or left-magnetized in
The presently disclosed ASLD may operate without the use of conventional charge current, even at its terminals. The nanomagnets act as digital spin capacitors that also provide non-volatile memory. The ASLD exhibits the five essential characteristics required for logic applications. First, both input and output information in the ASLD are in the same form, namely magnetization, providing concatenability. Second, the nanomagnets of the ASLD are intrinsically nonlinear (as further described below with reference to
Unlike known MQCA circuits, which use magnetic fields, the ASLD uses spin currents, which may lead to significant increases in both scalability and versatility. As spin currents are not limited to nearest neighbor communication, the ASLD will not be inherently limited to cellular architectures. Instead, the range of communication is limited to a spin diffusion length. At room temperature, using a silicon diffusion constant of D=36 cm2/second and a lifetime of 10 nanoseconds, the spin diffusion length would be approximately 6 microns. Drift in an electric field may be used to increase the diffusion length. The range of a few microns is large enough to allow considerable flexibility and versatility of architecture. Moreover, information is transferred in an ASLD with Fermi velocity, which may be compared to magnon velocity, as in the case of MQCA devices. In some embodiments, larger interconnects (e.g., a few millimeters) in an ASLD-based system could be electrical, current-based interconnects. Thus, an entire circuit may comprise blocks of all-spin logic, which may be connected by electrical interconnects, if necessary.
As compared to conventional CMOS devices, the ASLD has the potential for extremely low switching energies (i.e., the energy dissipated throughout switching). The self-correcting feature provided by magnets may make it possible to reduce the switching energy to several kBT (where T is the room temperature) per magnet rather than several kBT per spin. Although the ASLD is based on the physics of spin-torque, it does not require the use of structures or phenomena commonly associated with spin-torque, such as the tunneling magneto-resistance (TMR) of high resistance tunnel junctions. The dissipation in existing spin-torque devices is far in excess of the theoretical minimum. Power dissipation, along with other factors that affect scaling of the ASLD, are discussed in more detail below.
Referring now to
The ASLD 100 may also include one or more isolation layers 108 that separate the spin-coherent channel 104 from other spin-coherent channels in the architecture, preventing unwanted cross-talk between the channels. The isolation layers 108 may be comprise electrostatic barriers (e.g., oppositely doped semiconductor) and/or insulation layers (e.g., an oxide). Where an isolation layer 108 is placed under a nanomagnet 102, the nanomagnet 102 may interface with two (or more) spin-coherent channels 104. As such, each nanomagnet 102 may have an input side 110 (i.e., a “talking” side) that transmits information via spin currents 106 and an output side 112 (i.e., a “listening” side) that receives information via spin currents 106, providing non-reciprocity.
In some embodiments, the ASLD 100 may further include a tunnel barrier 114 at the interface between the input side 110 of each nanomagnet 102 and the spin-coherent channel 104 to the increase spin injection efficiency (while an ohmic contact at the interface between the output side 112 of each nanomagnet 102 and the spin-coherent channel 104 prevents back-injection of spins). The tunnel barriers 114 may comprise oxides and/or Schottky barriers. In other embodiments, the tunnel barriers 114 may be disposed in other portions of the spin-coherent channel 104. It will be appreciated that, while the tunnel barriers 114 may be included in any embodiment of the presently disclosed ASLD to increase spin injection efficiency, the tunnel barriers 114 need not be included in every embodiment.
Referring now to
The fixed layer 102B may be used to place the magnetization direction of the free layer 102A in a neutral state (e.g., state B of
The ASLD 200 illustrated in
Heff is a conservative field that includes all internal and external fields and can be written as the gradient of the potential energy with respect to the normalized magnetization components (i.e., Heff=−(1/MsV){right arrow over (∇)}E, where MsV is the magnetic moment if the unit volume V is magnetized to saturation). A nanomagnet may be switched by applying an easy axis field which exceeds the minimum field of switching Hc=2Ku/Ms, where Ku is the effective second order uniaxial anisotropy constant.
A spin current may be used to toggle a nanomagnet between its two stable states. This spin current interacts with the magnetization of the nanomagnet and exerts a torque on it. Equation (1) should therefore be modified to include this effect:
{circumflex over (M)} and {circumflex over (m)} are unit vectors in the direction of the fixed and free layers' magnetizations, respectively. H∥≡τ∥/MsV and H⊥=≡τ⊥/MsV are magnitudes of the magnetic fields that enter the magneto-dynamics equation due to interaction with a spin current. The quantities τ∥ and τ⊥ are in units of energy and are directly related to the torque exerted by the spin current. This analysis assumes that the spin current's momentum is fully absorbed by the macro-spin and that its polarization is redirected in the direction of the macro-spin once it passes a few atomic layers inside the nanomagnet. This analysis also assumes that H∥ and H⊥ are independent of the relative angle between the two magnetic layers.
For logic applications, a different switching scheme employing two spin currents may be used: a larger spin current providing the energy and a smaller spin current providing the bias that determines the final state of switching. To include the effect of both spin currents, Equation (2) is modified accordingly:
where “clk” denotes the torques due to clock spin current and “b” denotes the torques due to the bias spin current. {circumflex over (M)}clk represents the direction of the fixed magnetic layer, which is along the hard axis of the output free layer, while {circumflex over (m)}b represents the direction of the bias, which is along the easy axis of the input free layer. The normalized magnetic moment of the output free layer is represented by {circumflex over (m)}. The role of the clock torques is to soften the magnetization by putting it along its hard axis. If there is bias present, it gives the magnetization a tilt from this neutral state: upon removing the clock spin current, magnetization will relax to the state dictated by the tilt. The spin current may be generated by applying a lower voltage, Vbias, to an input nanomagnet 102 of the ASLD 200 and the clock torque may be supplied by applying a higher voltage, Vsupply, to an output nanomagnet 102 of the ASLD 200, as illustrated in
This type of logic switching using spin currents, using a free layer 102A and a fixed layer 102B with perpendicular easy axes, is illustrated in
Since nanomagnets 102 have internal fields that prefer either of two stable states along the easy axis of the free layer 102A, they inherently digitize information which allows for large gains and error correction, as shown in
Noting that (mz)rms=cosine(θrms) and using a barrier height of Eani=40 kBT, the fluctuations in the normalized component of magnetization along the easy axis are less than 0.01. Changes in the deflection Δ as a function of the bias magnitudes h∥b and h⊥b for various alignments of the input nanomagnet 102 are illustrated in
The spin current density needed to overcome thermal fluctuations of about 0.01 may also be calculated. Using typical parameters of 170×60×2 nm3 for the volume of the nanomagnet 102, 800 emu/cm3 for saturation magnetization Ms, with an anisotropy barrier height of approximately 40 kT (for a stability of approximately 10 years), and a damping parameter of α=0:01, a spin current density of about 2.5×104 A/cm2 is needed to overcome thermal fluctuations. This spin current density is about two orders of magnitude smaller than the spin current density needed to switch the output nanomagnet 102. Again, in the ASLD 200, the energy needed for switching the output nanomagnet 102 essentially comes from Vsupply and not Vbias.
For the graph of
A phase diagram for a single-pulse switching scheme was plotted using Equation (2) and is illustrated in
A phase diagram for a two-pulse switching scheme was also plotted using Equation (3) and is illustrated in
To make general purpose digital logic circuits, a minimal set of Boolean logic operations from which all other logical functions can be constructed is needed. A complete minimal set is composed of a basic binary operator like logical AND or logical OR and the unary operator NOT. AND and OR gates can be combined with inversion to make NAND and NOR gates respectively, which are universal logic gates. As will be explained shortly, a minimal set of Boolean logic gates can be constructed using a number of ASLD. When using the ASLD 200, the transfer of information in a chain of concatenated gates can be achieved by proper clocking As will be described further below, when using other embodiments of the ASLD, clocking may not be necessary.
One illustrative embodiment of a digital logic circuit including a number of ASLD 200 is illustrated in
Three phases of clocking and signal transmission from one gate to the next are illustrated sequentially in
Referring now to
As described above with reference to
In the ASLD 700, the asymmetric positioning of the ground terminal 702 results in the first nanomagnet 102 effectively shielding the second nanomagnet 102 from communicating with the ground terminal 702, thereby reducing the charge current and consequently the spin current ({right arrow over (I)}S) injected by the second nanomagnet 102 as compared to the first nanomagnet 102. As a result the torque exerted on the second nanomagnet 102, given by {right arrow over (I)}S={circumflex over (m)}2×({right arrow over (I)}S2×{circumflex over (m)}2), is greater than the torque exerted on the first nanomagnet 102. This effect is captured by the distributed conductance network model illustrated in
As one illustrative example,
Each nanomagnet 102 is described by a separate LLG equation. Ns is the net number of Bohr magnetons in one of the nanomagnets 102, given by Ns=MsΩ/μB (where Ms is the saturation magnetization, Ω is the volume, and μB is the Bohr magneton). The solid curves in
where ℏ is the reduced Plank's constant, Eb is the anisotropy energy barrier, Ha is the demagnetizing field, and HK is the uniaxial anisotropy field.
As shown in
Even if both nanomagnets 102 of the ASLD 700 initially start to switch after one of the transitions of the supply voltage in
As shown in
Referring now to
Another illustrative embodiment of a digital circuit including a number of cascaded ASLD 700 is illustrated in
In addition to the ground terminal 702 of the ASLD 700 described above, other asymmetries may be used to provide non-reciprocity to an ASLD. The degree of non-reciprocity of an ASLD can be arrived at by defining a “spin-torque conductance” (gs) relating the spin-torque component of the current at each nanomagnet in the ASLD to the supply voltage:
|{right arrow over (I)}s1⊥|={circumflex over (m)}1×({right arrow over (I)}s1×{circumflex over (m)}1)|=gs1VSS (7),
|{right arrow over (I)}s2⊥|=|{circumflex over (m)}2×({right arrow over (I)}s2×{circumflex over (m)}2)|=gs2VSS (8).
Of the two nanomagnets in an ASLD, the nanomagnet with the greater spin-torque conductance (gs) will function as the output.
where gF is the conductance of the FM/interface region, gα=PgF, and P is the effective polarization of the FM interface. gβ and gγ refer to the effective spin “mixing” conductance of the interface and describe the Slonczewski and field-like components of spin torque, respectively. gγ may be set to zero because the field-like term is generally very small in all-metallic structures. The lead to the ground terminal may be assumed to be unpolarized with the absence of any spin-orbit interaction effects (thereby, equally affecting all spin components) and can be described by a matrix:
ρ, λ, L and A refer to the resistivity, spin-diffusion length, length and cross section of the lead, respectively. Solving the conductance model of
For two perpendicular magnets (θ=π/2), the expression simplifies to:
Equation (12) may used to evaluate several possibilities for implementing non-reciprocity in an ASLD. For instance, the non-reciprocity of an ASLD depends on how well the input nanomagnet can inject polarized spin current (gα1) and how easily the output nanomagnet can relax the non-collinear spins (gβ2), and vice-versa. As described above, the insertion of a tunnel barrier 114 at an interface between the spin-coherent channel 104 and one of the nanomagnets 102 may introduce or improve non-reciprocity. In other embodiments, the input and output nanomagnets 102 may be designed with different interface areas to the spin-coherent channel 104. It is contemplated that any suitable technique for designing different spin-torque conductances at the input and output nanomagnets 102 may be used to introduce or to improve non-reciprocity.
Referring now to
In general, the nanomagnet 102 with a voltage closer to that of the ground terminal 702 ends up with a higher spin-torque conductance (gs). The ASLD 1300, however, has no stable state and once the state of the output nanomagnet 102 has switched, the system continues to oscillate deterministically between all the possible states (i.e., 00, 01, 11, 10), as illustrated in
There are several factors which determine the scalability of circuits employing the ASLD. The most basic requirement for scalability is small nanomagnets. One limit on the size of each nanomagnet is its thermal stability. The retention time of a magnet is given by:
f0 is called the attempt frequency and, for magnetic thin films used for storage purposes, is on the order of 1 GHz. KuV (V is the volume) is the height of the energy barrier separating the stable states of a magnet and should be at least 40 kBT (where T is the room temperature) to give about 10 years of retention time. Many experiments have reported Ku values as high as 107 erg/cm3≈¼ kT/nm3. Based on the aforementioned f0 value, magnets with volumes on the order of 100 nm3 are stable at room temperature, which translates to only a few nm in each dimension and indicates the potential for an extremely small footprint.
Power dissipation is an additional factor that should be taken into account for extremely high density large scale computational circuits and is believed to be the main road block for further downsizing of CMOS technology. The intrinsic switching energy (i.e. the energy dissipated throughout switching) of a magnet is roughly on the order of the barrier height, KuV, which is at least 40 kBT<1 aJ per magnet, based on the discussion above. While the magnet may be composed of millions of spins, the dissipation for switching the magnet as one giant collective entity is only a few kBT. In a charge-based transistor, every single electronic charge dissipates a few kBT throughout switching. In general, switching energy and energy-delay can be written as:
where V and I are the charge voltage and current, respectively, and tsw is the switching delay. Qtot=Itsw is the total charge involved in a switching event. Equation (15) permits a simple comparison with charge-based devices, where Qtot is the amount of charge being switched.
The Qtot involved in switching an ASLD may be analyzed using the coupled spin-transport/magneto-dynamics model of
The factor f1 is exactly 1 if only a uniaxial field is present. However, f1 can be less or more than 1 when fields other than uniaxial are involved. The total charge Qtot will be larger than f1(2qNs) and can be written as:
where I is the charge current, Is is the time-average spin current, and f2=∫Isdt/∫Istzdt is a factor reflecting the fact that the spin current is larger than the spin-torque current that enters the LLG equation.
Thus, the Qtot and the switching energy-delay of an ASLD may be improved by lowering the number of Bohr magnetons (Ns) of the nanomagnets of the ASLD, while maintaining a fixed energy barrier (Eb) of at least 10 kT (i.e., at least ¼ eV at room temperature) to sustain nonvolatility of the nanomagnets. As shown in
While the disclosure has been illustrated and described in detail in the drawings and foregoing description, such an illustration and description is to be considered as exemplary and not restrictive in character, it being understood that only illustrative embodiments have been shown and described and that all changes and modifications consistent with the disclosure and recited claims are desired to be protected.
This application claims priority under 35 U.S.C. §119(e) to U.S. Provisional Patent Application Ser. No. 61/430,248, filed on Jan. 6, 2011, and entitled “All-Spin Transistor with Built-In Memory,” the entire disclosure of which is expressly incorporated herein by reference.
This invention was made with government support under Grant Nos. EEC0228390 and EEC0738513, both awarded by the National Science Foundation. The U.S. Government has certain rights in the invention.
Number | Name | Date | Kind |
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8138874 | Carlton et al. | Mar 2012 | B1 |
20110095761 | Ahn | Apr 2011 | A1 |
20110140217 | Nguyen et al. | Jun 2011 | A1 |
20110147866 | Sun et al. | Jun 2011 | A1 |
20120154063 | Nikonov et al. | Jun 2012 | A1 |
20120267735 | Atulasimha et al. | Oct 2012 | A1 |
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Number | Date | Country | |
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20120176154 A1 | Jul 2012 | US |
Number | Date | Country | |
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61430248 | Jan 2011 | US |