The present invention generally relates to radiation elements (sensors) for antennas and phased arrays and more particularly to a macro-sized, magnetic RF antenna for mobile devices.
Global telecommunication systems, such as cell phones and two way radios, are migrating to higher frequencies and data rates due to increased consumer demand on usage and the desire for more content. Current mobile devices are challenged by the increased functionality and complexity of multi-modes, multi-bands, and multi-standards, and progressing beyond 3 G with the increasing requirement of multimedia, mobile internet, connected home solutions, sensor-network, high-speed data connectivity such as Bluetooth, RFID, WLAN, WiMAX, UWB, and 4 G. Limited battery power and tight design space will become bottlenecks for the high integration and development of mobile devices. The tight design space is especially challenging for RF technologies and the requisite design/fabrication of adaptive/tunable antennas and antenna arrays. Nanosized RF antennas with low power consumption will be necessary.
Known antennas ranging from macro-size to micro-size, are based on a top-down approach, and are bulky. They have difficulties in meeting performance and power-consumption requirements, particularly with increased frequency, functionality and complexity of multi-modes, multi-bands, and multi standards for seamless mobility. Size and frequency limitation such as the Terahertz gap have been reached. With the increase of high frequency for high data rate communications, skin effect becomes more of an issue and causes the loss of efficiency for these conventional solid and bulky antennas, thereby impacting power consumption.
Accordingly, it is desirable to provide a macro-sized RF antenna for mobile devices having low power consumption and wide-range frequency spectrum based on bottom-up nanotechnology. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
A communication device includes a macro-sized RF antenna having low power consumption and wide-range frequency spectrum based on bottom-up nanotechnology. The communication device includes receiver circuitry coupled to a controller. An antenna coupled to the receiver circuitry comprises a magnetic element including a plurality of electrons having a spin. A voltage source provides a DC current through the magnetic element. A detector measures changes in the DC current caused by reception of an RF signal that changes the spin on the plurality of electrons.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and
The following detailed description of the invention is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the invention or the following detailed description of the invention.
An antenna system incorporating a magnetic nanostructure similar to those used in magnetic random access memories (MRAM) can perform in the broad wireless frequency spectrum from microwave such as 3 G/WCDMA, to millimeter wave, and to terahertz and beyond. The detection of RF signals is based on tuning of the spin resonance of a free ferromagnetic layer of a nanostructured MRAM device. The free ferromagnetic layer's magnetization is modulated by the incoming RF signal and is characterized by a proportionate modulation of a DC current through the device. The initial sensing of an RF signal that resonates with the spin resonance frequency causes the free layer magnetization to rotate, at least partially. This results in the modulation of the magnetic dipoles in the free magnetic layer of the MRAM device, resulting in a detectable modulation of the device current. The rate of change in the direction of the magnetization vector depends on the energy of the incoming RF signal.
Moreover, a nanostructure array of these devices provides a mechanism to detect individual frequencies in a wide frequency spectrum of RF signals by coupling a broadband antenna. This allows a high degree of tunability and specificity for which the individual MRAM devices are biased.
Generally, a single MRAM cell includes an upper ferromagnetic layer, a lower ferromagnetic layer, and a non-magnetic or insulating spacer between the two ferromagnetic layers. The upper ferromagnetic layer is the fixed magnetic layer because the direction of its magnetization is fixed. The lower ferromagnetic layer is the free magnetic layer because the direction of its magnetization can be switched to change the bit status of the cell. When the magnetization in the upper ferromagnetic layer is parallel to the magnetization in the lower ferromagnetic layer, the resistance across the cell is relatively low. When the magnetization in the upper ferromagnetic layer is anti-parallel to the magnetization in the lower ferromagnetic layer, the resistance across the cell is relatively high. The data (“0” or “1”) in a given cell is read by measuring the resistance of the cell. In this regard, electrical conductors attached to the cells are utilized to read the MRAM data.
The orientation of magnetization in the free magnetic layer can point in one of two opposite directions, while the orientation of the fixed magnetic layer is fixed along one direction. In conventional MRAM, the orientation of the magnetization in the free magnetic layer rotates in response to current flowing in a digit line and in response to current flowing in a write line. Selecting the directions of the currents will cause the magnetization in the free magnetic layer to switch from parallel to anti-parallel to the magnetization in the fixed magnetic layer. In a typical MRAM, the orientation of the bit is switched by reversing the polarity of the current in the write line while keeping a constant polarity of the current in the digit line.
Transmission mode spin-transfer switching is one technique for sensing an incoming signal. Writing bits using the spin-transfer interaction can be desirable because bits with a large coercivity (Hc) in terms of magnetic field induced switching (close to 1000 Oersteds (Oe)) can be switched using only a modest current, e.g., less than 5 mA. The higher He results in greater thermal stability and less possibility for disturbs. A conventional transmission mode spin-transfer switching technique for an MRAM cell includes a first magnetic layer, a nonmagnetic tunnel barrier layer, and a second magnetic layer. In this technique, the write current actually flows through the tunnel junction in the cell. According to the spin-transfer effect, the electrons in the write current become spin-polarized after they pass through the fixed magnetic layer. In this regard, the fixed layer functions as a polarizer. The spin-polarized electrons cross the nonmagnetic layer and, through conservation of angular momentum, impart a torque on the free magnetic layer. This torque causes the orientation of magnetization in the free magnetic layer to be parallel to the orientation of magnetization in the fixed magnetic layer. The parallel magnetizations will remain stable until a write current of opposite direction switches the orientation of magnetization in the free magnetic layer to be anti-parallel to the orientation of magnetization in the fixed magnetic layer.
The transmission mode spin-transfer switching technique requires relatively low power (compared to the conventional switching technique), virtually eliminates the problem of bit disturbs, results in improved data retention, and is desirable for small scale applications.
The spin-transfer effect is known to those skilled in the art for use in MRAM devices (See for example, U.S. Patent Publication No. 2006/0087880 which discloses an MRAM being written using spin-transfer reflection mode techniques; U.S. Pat. No. 6,967,863; and WIPO publication WO 2005/082061). Briefly, a current becomes spin-polarized after the electrons pass through the first magnetic layer in a magnet/non-magnet/magnet trilayer structure, where the first magnetic layer is substantially thicker than the second magnetic layer. The spin-polarized electrons cross the nonmagnetic spacer and then, through conservation of angular momentum, place a torque on the second magnetic layer, which switches the magnetic orientation of the second layer to be parallel to the magnetic orientation of the first layer. If a current of the opposite polarity is applied, the electrons instead pass first through the second magnetic layer. After crossing the nonmagnetic spacer, a torque is applied to the first magnetic layer. However, due to its larger thickness, the first magnetic layer does not switch. Simultaneously, a fraction of the electrons will then reflect off the first magnetic layer and travel back across the nonmagnetic spacer before interacting with the second magnetic layer. In this case, the spin-transfer torque acts so as to switch the magnetic orientation of the second layer to be anti-parallel to the magnetic orientation of the first layer. Spin-transfer as described so far involves transmission of the current across all layers in the structure. Another possibility is spin-transfer reflection mode switching. In reflection mode, the current again becomes spin-polarized as the electrons pass through the first magnetic layer. The electrons then cross the nonmagnetic spacer layer, but instead of also crossing the second magnetic layer, the electrons follow a lower resistance path through an additional conductor leading away from the interface between the nonmagnetic spacer and the second magnetic layer. In the process, some fraction of the electrons will reflect off this interface and thereby exert a spin-transfer torque on the second magnetic layer to align it parallel to the first magnetic layer.
Referring to
The antenna cell 100 generally includes the following elements: a first conductor 102; a fixed magnetic element 108; a nonmagnetic spacer or insulator 110; a free magnet element 112; a second conductor 114; and an optional select transistor 116. In some exemplary embodiments, the fixed magnet element 108 may include (not shown) a fixed magnetic layer, a spacer layer, a pinned magnetic layer, and an antiferromagnetic pinning layer. The select transistor 116 is addressed when it is desired to sense the cell 100 by providing a current 118 from voltage source 124 therethrough from the first conductor 102 to the select transistor 116. In one embodiment, a plurality of similar MRAM cells 100 (e.g., a column of cells) may be coupled between a common first conductor 102 and a common second conductor 114 wherein only one of the transistors 116 would be utilized. The ellipses in the conductors on either side of the voltage source 124 indicate that the voltage source 124 may be coupled to a plurality of cells 100.
First conductor 102 is formed from any suitable material capable of conducting electricity. For example, first conductor 102 may be formed from at least one of the elements Al, Cu, Au, Ag, or their combinations.
The free magnetic element 112 is formed from a magnetic material having a variable magnetization. For example, free magnetic element 112 may be formed from at least one of the elements Ni, Fe, Mn, Co, or their alloys as well as so-called half-metallic ferromagnets such as NiMnSb, PtMnSb, Fe3O4, or CrO2. As with conventional MRAM devices, the direction of the variable magnetization of free magnetic element 112 determines whether MRAM cell 100 represents a “1” bit or a “0” bit. In practice, the direction of the magnetization of free magnetic element 112 is either parallel or anti-parallel to the direction of the magnetization of fixed magnet element 108.
Free magnetic element 112 has a magnetic easy axis that defines a natural or “default” orientation of its magnetization. When the cell 100 is in a steady state condition with no current 118 applied, the magnetization of free magnetic element 112 will naturally point along its easy axis. As described in more detail below, the cell 100 is suitably configured to establish a particular easy axis direction for free magnetic element 112. From the perspective of
In this exemplary embodiment, a nonmagnetic spacer or an insulator 110 is located between free magnetic element 112 and fixed magnet element 108. Spacer 110 is formed from any suitable material that can function as a non-magnetic conductor or an electrical insulator. For example, the non-magnetic conductor may be formed using materials like Cu or Al and the insulator 110 may be formed from a material such as oxides or nitrides of at least one of Al, Mg, Si, Hf, Sr, or Ti. For purposes of the cell 100, insulator 110 serves as a magnetic tunnel barrier element, and the combination of free magnetic element 112, insulator 110, and fixed magnet element 108 form a magnetic tunnel junction.
In the illustrated embodiment, fixed magnet element 108 has a magnetization that is either parallel or anti-parallel, e.g., arrow 122, to the magnetization of free magnetic element 112. In one practical embodiment, fixed magnet element 112 is realized as a pinned synthetic antiferromagnetic that may include (not shown) a fixed magnetic layer, a spacer layer, pinned magnetic layer, and an antiferromagnetic layer. As depicted in
The optional select transistor 116 includes a first current electrode coupled to a voltage potential, a second current electrode coupled to the free magnetic layer 112 and a gate that, when selected, allows electrons to flow through the cell 100 to the first conductor 102.
In practice, the cell 100 may employ alternative and/or additional elements, and one or more of the elements depicted in
The other cells that share the first conductor 102 will not receive the current 118. Only the designated bit at the intersection of the first conductor 102 and the selected select transistor 116 will receive the current 118.
When an RF signal is received by the antenna cell 100, the RF signal strikes the free magnetic layer 112. Each antenna cell 100 has a characteristic resonance frequency that depends on the external magnetic field. The spins in the free magnetic layers precess at this resonance frequency, which is known as Larmor frequency. The energy corresponding to the resonance frequency is given by the equation E=μe. B, where μe is the magnetic moment of the electron and B is the external magnetic field. This external magnetic field that influences the spins in the free ferromagnetic layer is generated by a dc current line and the field generated by the fixed ferromagnetic layer. When the RF signal strikes the free magnetic layer 112, the electrons within start to undergo Bloch oscillations, giving rise to a modulation in the DC current 118 through the nanostructure. This change in DC current is detected by the detector 126 and would indicate the reception of the frequency of the RF signal. Hence the incoming RF signal is detected as a modulation in the DC current, thus providing a mechanism for RF detection in a simple and straightforward manner.
To improve the sensitivity of the antenna cell 100, a spiral antenna 142 is coupled by conductors 144, 146 (a side cross sectional view in
A practical architecture may include an array or matrix of the cells 100 having individual selectivity as described herein.
As discussed above, the device can be tuned to the desired frequency by simply changing the external magnetic field. This field is controlled by the DC current through the bias line that is fabricated next to each individual nanostructure. The change in the current causes a change in the magnetic field which in turn tunes the resonance frequency of the electron spins in the free magnetic layer. The selectivity of the device is determined by the line width of the resonance, or absorption spectrum, of the spins. This provides the mechanism for high selectivity in the detection of the frequency of interest. Multi-frequency detection can be achieved using an array of the magnetic nanostructures, where each individual nanostructure can be turned to a particular frequency of interest, thereby leading to multi-frequency detection. Change in the orientation of the free magnetic layer of individual nanostructures results in a mismatch of orientation with respect to the fixed magnetic layer, hence leading to a change in the resistance of the device. This results in a change in the current through the nanostructure device that can be detected.
Referring to
Referring to
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims.
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Number | Date | Country | |
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20080238779 A1 | Oct 2008 | US |