The invention relates to switching magnetic tunnel junctions using spin currents created by a temperature gradient, and more particularly, to the use of such technology in a magnetic random access memory device.
One of the most exciting potential new memory technologies is magnetic random access memory (MRAM) based on advanced spintronics, which promises to be a high performance, non-volatile memory. The essential feature of MRAM is the switching of a magnetic tunnel junction (MTJ) memory cell between two distinct resistance states associated with the relative magnetic orientation of the ferromagnetic electrodes sandwiching the tunnel barrier. This switching can be achieved by passing spin polarized charge currents directly through the MTJ, so that switching is induced via spin transfer torque (STT); however, the current densities that are required are currently too large to make it a viable technology. A number of different approaches are being pursued to decrease the current density, using novel materials and physics. In particular, there has been a great deal of interest in the generation of spin currents without any significant charge currents through the use of temperature gradients (i.e., ‘spin-caloritronics’). However, the demonstration of the potential of thermally induced spin currents for MRAM has not been realized due to the difficulty in creating sufficiently large temperature gradients across the ultra-thin tunnel barriers needed for useful applications.
On the other hand, using heat to create gradients and charge-currents has been an active area of research in thermoelectrics (1). Spin caloritronics (2, 3) adds a new dimension to this concept by employing heat to create spin-dependent chemical potential gradients in ferromagnetic materials (4). Traditionally, electric current driven spin-currents have been used to transport spin angular momentum to change the magnetization of a magnetic material a phenomenon known as spin-transfer-torque (STT) (5-7). Heat currents can also create spin-currents in magnetic materials; the transfer of spin angular momentum through this process has been called thermal-spin-torque (TST) (8, 9). A number of experiments employing spin currents generated by heat have been reported, including: the spin-Seebeck effect observed in ferromagnetic metals (10, 11), semiconductors (12) and insulators (13); thermal spin injection from a ferromagnet into a non-magnetic metal (14); the magneto-Seebeck effect observed in magnetic tunnel junctions (15-17); Seebeck spin tunneling in ferromagnet-oxide-silicon tunnel junctions (18); and several others (19, 20). On the other hand, while there have been several theoretical predictions (8, 9, 21, 22) of the TST, few experiments have been reported to date.
We find that a temperature gradient of ˜1 K/nm across a 0.9 nm thick MgO tunnel barrier in an MTJ induces modest charge currents (corresponding to current densities on the order of 1×103 A/cm2), in addition to large spin currents that induce significant TST. The TST is as large as the STT that would be created solely by a charge current density of 1×106 A/cm2 in the devices herein (which are otherwise similar to previously reported MTJ devices (24)). Furthermore, the TST is strongly dependent on the orientation of the free layer (FL) with respect to the reference layer (RL). We show that the TST can be attributed to an asymmetry in the tunneling conductance across zero bias, which is consistent with the spin accumulation in the free layer of the MTJ due to the temperature gradient across the tunnel barrier of the MTJ.
One aspect of the invention is a method that includes creating a temperature gradient across a tunnel barrier that separates a magnetic reference layer and a magnetic free layer, thereby inducing a thermal spin current across the tunnel barrier. The magnetic layers and the tunnel barrier advantageously form a magnetic tunnel junction. The thermal spin current reduces the magnitude of any magnetic field and/or electrical spin current required to switch the free layer. (If a magnetic field alone is used to switch the free layer, the field strength required for this switching is less as a result of the temperature gradient-induced thermal spin current. Likewise, if an electrical spin current alone is used to switch the free layer, the electrical spin current required for this switching is less as a result of the temperature gradient-induced thermal spin current. Similarly, if a combination of a magnetic field and an electrical spin current is used to switch the free layer, a smaller magnetic field and a smaller electrical spin current are required.) The magnetic layers and the tunnel barrier are configured such that the tunneling conductance across the tunnel barrier is asymmetric with respect to bias voltage across the tunnel barrier.
Another aspect of the invention is a method that includes creating a temperature gradient across a tunnel barrier that separates a magnetic reference layer and a magnetic free layer, thereby inducing a thermal spin current across the tunnel barrier, in which the magnetic layers and the tunnel barrier form a magnetic tunnel junction. The method also includes switching the free layer with a magnetic field and/or an electrical spin current, in which the thermal spin current reduces the magnitude of the magnetic field and/or the electrical spin current required to switch the free layer. Furthermore, the magnetic layers and the tunnel barrier are configured such that the tunneling conductance across the tunnel barrier is asymmetric with respect to bias voltage across the tunnel barrier.
Yet another aspect of the invention is method that includes creating a temperature gradient across a tunnel barrier that separates a magnetic reference layer and a magnetic free layer, thereby inducing a thermal spin current across the tunnel barrier, in which the tunnel barrier and the magnetic layers form a magnetic tunnel junction. The free layer is brought into a precessional state through the use of a temperature gradient-induced thermal spin current across the tunnel barrier.
Another aspect of the invention is a method that includes creating a temperature gradient across a tunnel barrier that separates a magnetic reference layer and a magnetic free layer, thereby inducing a thermal spin current across the tunnel barrier, in which the tunnel barrier and the magnetic layers form a magnetic tunnel junction. The free layer is brought into a precessional state (i) through the use of a temperature gradient-induced thermal spin current across the tunnel barrier, in combination with (ii) an external magnetic field applied to the magnetic tunnel junction and/or an electrical spin current that flows across the magnetic tunnel junction.
First, a large mesa of 3 μm×20 μm is formed by etching portions of the film stack down to the MgO (001) substrate. To this end, Ar ion milling is performed followed by in situ side-wall encapsulation with alumina (AlOx). Next, a free layer (FL) of appropriate size and orientation is exposed by etching in the center of the large mesa down to the MgO tunnel barrier, while also making a series of additional mesas 120 at both ends, with the mesa serving as the bottom contact to the tunnel junction. Specifically, Ar ion milling of portions of the large mesa is performed down to the MgO tunnel barrier (an in situ residual gas analyzer is used to determine which layer of the film stack is being etched the during Ar ion milling process), and thereafter AlOx is deposited in situ for MTJ side-wall encapsulation. A 30 nm thick S-shaped gold layer 130 is then deposited, which serves as the top contact to the FL. Another 20 nm thick alumina pad 140 is deposited to encapsulate the underlying FL and its gold contact, thereby providing electrical isolation between the top contact of the MTJ and the heater (to be formed next). Thereafter, a 20 nm thick layer of ScN with resistivity ˜2 mΩ-cm is deposited, which serves as the heater. Six large Au contacts 150 are then deposited to connect to each of the top and bottom electrodes of the MTJ and to the heater.
The FL is 200 nm wide and 500 nm long, whereas the RL of the MTJ is of considerably larger proportions (3 μm wide and 11 μm long) and serves as an on-site thermometer to measure the local temperature of the MTJ upon heating. As mentioned above, a 1 μm wide resistive heater (resistivity ˜2 mΩ-cm) made of ScN is deposited above the MTJ and is electrically isolated from the top contact of the MTJ by a 20 nm thick alumina (AlOx) pad. The advantage of this geometry is that effects on the MTJ switching due solely to thermal gradients can be studied in the closed-circuit configuration (
In order to create sharp temperature gradients with little heat input, experiments were performed at a base temperature of 10 K, which has several advantages. Firstly, the heat capacity of the entire device at this temperature is 2-3 orders of magnitude smaller than it is at room temperature, i.e., less heat is required to raise the temperature by a given amount. Secondly, the thermal conductivity of oxides is a few orders of magnitude lower at low temperatures than at room temperature, thereby leading to larger temperature gradients across the tunnel barrier for a given heat current. Thirdly, the resistivity of the semiconducting ScN heater is higher at lower temperatures, thereby requiring a smaller heater current, IHeater, to generate the same amount of heat. Finally and most importantly, the highest temperatures of the FL of the MTJ (<60 K) accessed in our experiments change the saturation magnetization of the FL by less than 1% of its lowest temperature value.
The change in the resistance of the MTJ (device I) as the magnetic field is applied to switch the FL (i.e., the tunneling magneto-resistance or TMR) is plotted in
The TMR measurement can now be performed at 10 K while locally heating the MTJ with a current through the heater, IHeater, thereby creating sharp temperature gradients on the order of 1 K/nm across the tunnel barrier (transverse) and 0.1 K/nm along the length of the RL (longitudinal), as shown in the finite element model (
Creation of sharp temperature gradients (ΔT/Δz) is necessarily associated with an increased absolute temperature of the MTJ. To minimize the net increase of the absolute temperature, the MTJ stack is grown on a thermally conducting substrate, i.e., MgO (100), which acts as a heat sink for the bottom electrode of the MTJ. Hswitch also depends on the absolute temperature T of the MTJ as shown by the data of
We use local thermometry data (see
Comparing (see the data of
In order to investigate the angular dependence of the TST, similar measurements were performed on another device (device II), where the FL was patterned at 120° to the RL as shown in
We performed magneto-Seebeck (15-17) measurements (
We performed STT measurements on the MTJ devices to find out the effect of charge currents (passed through the tunnel barrier) on the switching fields of the devices and to make sure that the devices studied here behave properly. Typically, current densities>5×106 A/cm2 are needed to switch the most efficient MTJs with STT alone. Such high current densities are bound to create large amounts of heat in the MTJs (see
For the geometry of our device, the RL is much better thermally grounded than the FL, owing to the RL's much larger dimensions. As a consequence, for large current densities across the MTJ, the FL will be hotter than the RL. Thus, for large current densities of either polarity, the temperature gradient will always be in the same direction with the FL being hotter than the RL, which would induce TST along with STT. Also, owing to small specific heat at low temperatures, the temperature of the device will change by a large amount for current densities such as those indicated in
As per the COMSOL simulation (see
As is evident from
It is clear from the discussion above that self-heating from the tunnel barrier due to larger current density represents a complication. Furthermore, the results cannot be accounted for by the difference in temperature of the free layer in the P and AP states arising from differences in the thermal conductivity of the MTJ in these two states, since this leads to changes in temperature that are much too small to account for these observations (27). We note that this would mean, for example, that the FL of the MTJ in the AP configuration would have to be 15 K hotter (dashed line in
In order to ascertain the origin of the TST, experiments were also performed on another device III (with its TEM being shown in
As is now explained below, the TST depends on the current-voltage (IV) characteristics of the MTJ.
for devices II and III in their respective AP and P states. For device II (and I), since there is an asymmetry in the Gnorm across V=0 in the AP state, evidence of the TST affecting AP→P switching is observed, whereas negligible TST is found for P→AP switching in device II (and I) and both AP→P and P→AP switching of device III, as the Gnorm is much more symmetric across V=0 in all these cases (
This is happening in the devices described herein, where there is a net minority spin (↓) of the RL accumulating in the FL of the MTJ, when it is in the anti-parallel (AP) state, thereby increasing HswitchAP→P as is observed (see
Such an asymmetry can be obtained in different ways: either by allowing for a change in the polarization P of the magnetic electrodes near the Fermi energy εF, i.e.,
as shown in
would always lead to minority spins from the RL accumulating in the FL, when the FL is hotter than RL (TFL>TRL) in the AP configuration, thereby giving evidence for the thermal spin torque (TST).
We postulate that the asymmetry in the conductance is due to the energy dependence of the tunnel matrix elements in the AP state rather than the DOS itself. If this asymmetry were to be in the DOS, such an asymmetry in the IV characteristic of the MTJ would be seen in the P state as well. Regardless, so long as there is an asymmetry in the tunnel conductance of the MTJ, TST effects would be expected.
Accordingly, temperature gradients of ˜1 K/nm across an ultra-thin tunnel barrier can induce large spin currents, and thus a giant TST, which can influence MTJ switching. The measurements reported here are performed with static temperature gradients. Much sharper temperature gradients can be created on short time scales to create greater TST, which can be large enough to switch an MTJ with pure temperature gradients alone, thereby making it relevant to Magnetic Random Access Memory (MRAM) technology (28). For example, the MTJs described herein can form part of an MRAM device, in which many MTJs form an array of such devices, thereby permitting data to be written into and read out of the MRAM device.
Alternatively, the MTJs described herein may form components within a racetrack memory device, e.g., for data storage. In such an embodiment, the free layers of the MTJs may form a continuous layer used for data storage and retrieval. In still other embodiments, a double magnetic tunnel junction may be employed. In this case, a free magnetic layer may be sandwiched between two tunnel barriers, each of which is in proximity with a respective reference layer.
In yet other embodiments, a magnetic free layer of an MTJ may be brought into a precessional state through the use of TST, with or without the assistance of an external magnetic field applied to the magnetic tunnel junction and/or an electrical spin current that flows across the magnetic tunnel junction.
The temperature gradient across the MTJ can be created more efficiently (e.g., increased) by optimizing the geometry and/or materials that form the MTJ. In particular, the resistivities of the free and reference magnetic layers can selected so that a temperature gradient is created at least in part by flowing current across the magnetic tunnel junction itself. For example, the resistivity of one of the magnetic layers can be increased by alloying or doping with elements that increase electron scattering. CoFeB can be used to this end, since its resistivity is significantly higher than CoFe. Alternatively, ferromagnetic nitrides can be used and their resistivity can be tuned over a wide range by varying the nitrogen concentration.
An MTJ can also be constructed in which the free and reference magnetic layers have different cross-sectional areas. In such a geometry, a current flowing through the MTJ will have a current density that varies throughout the magnetic layers. This means that different amounts of heat are produced in different portions of the MTJ (e.g., the heat produced in the magnetic free layer is different in this situation than the heat produced in the magnetic reference layer). Accordingly, a temperature gradient across the MTJ is produced, leading to TST.
The invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is therefore indicated by the appended claims rather than the foregoing description. All changes within the meaning and range of equivalency of the claims are to be embraced within that scope.
Number | Name | Date | Kind |
---|---|---|---|
7679155 | Korenivski | Mar 2010 | B2 |
7948044 | Horng et al. | May 2011 | B2 |
8203191 | Uchida et al. | Jun 2012 | B2 |
8208295 | Dieny | Jun 2012 | B2 |
8289759 | Wang et al. | Oct 2012 | B2 |
8379352 | Braganca et al. | Feb 2013 | B1 |
8456894 | Abraham et al. | Jun 2013 | B2 |
8750013 | Abraham et al. | Jun 2014 | B1 |
8750028 | Ogimoto | Jun 2014 | B2 |
8754491 | Abraham et al. | Jun 2014 | B2 |
8908424 | Wang et al. | Dec 2014 | B2 |
20120280338 | Abraham | Nov 2012 | A1 |
20120281460 | Abraham | Nov 2012 | A1 |
20120281467 | Abraham | Nov 2012 | A1 |
20120319221 | Apalkov et al. | Dec 2012 | A1 |
20140015074 | Bedau et al. | Jan 2014 | A1 |
Entry |
---|
W. F. Brinkman, R. C. Dyner, and J. M. Rowell “Tunneling Conductance of Asymmetriccal Barrier” Apr. 1970. |
Hatami et al., “Thermal Spin-Transfer Torque in Magnetoelectric Devices.” The American Physical Society, vol. 99, pp. 066603-1-066603-4, (Aug. 2007). |
Hatami et al., “Thermoelectric effects in magnetic nanostructures.” The American Physical Society, vol. B 79, pp. 174426-1-174426-13, (2009). |
Jaworski et al., “Giant spin Seebeck effect in a non-magnetic material.” Nature, vol. 487, issue 7406, pp. 210-213, (Jul. 12, 2012). |
Jia et al., “Thermal Spin Transfer in Fe-MgO-Fe Tunnel Junctions.” Physical Review Letters, vol. 107, pp. 176603-1-176603-5, (Oct. 2011). |
Le Breton et al., “Thermal Spin Current from a ferromagnet to silicon by Seeback spin tunneling.” Nature, vol. 475, issue 7354, pp. 82-85, (Jun. 29, 2011). |
Liebing et al., “Tunneling Magnotothermopower in Magnetic Tunnel Junction Nanopillars.” The American Physical Society, vol. 107, pp. 177201-1-177201-4, (Oct. 2011). |
Lin et al., “Giant spin-dependent thermoelectric effect in magnetic tunnel junctions.” Nature Communications, vol. 3, pp. 1-6, (Mar. 2012). |
Nogi et al., “Preparation and magnetotransport properties of MgO-barrier-based magnetic double tunnel junctions including nonmagnetic nanoparticles.” Journal of Physics D: Applied Physics, vol. 40, No. 5, pp. 1242-1246, Feb. 16, 2007). |
Saito et al., “Bias voltage and annealing-temperature dependences of magnetoresistence ratio in Ir-Mn exchange-baised double tunnel junctions.” Journal of Magnetism and Magnetic Materials, vol. 223, issue 3, pp. 293-298, (Feb. 2001). |
Slonczewski, “Initiation of spin-transfer torque by thermal transport from magnons.” The American Physical Society, vol. B 82, pp. 054403-1-054403-11, (2010). |
Walter et al., “Seebeck effect in magnetic tunnel junctions.” Nature Materials, vol. 10, pp. 742-746, (Jul. 24, 2011). |
Yu et al., “Evidence for Thermal Spin-Transfer Torque.” The American Physical Society, vol. 104, pp. 146601-1-146601-4, (2010). |
Number | Date | Country | |
---|---|---|---|
20160322091 A1 | Nov 2016 | US |