Materials with ferroelectric and ferromagnetic properties with magneto-electric coupling properties are promising candidates for information technology and device fabrication. The preparation and characterization of multiferroic materials in which ferroelectricity and ferromagnetism coexist would represent a significant milestone for the development of highly functionalized materials and devices. Such compositions would present the possibility of electrically controlling magnetic memory devices and, conversely, magnetically manipulating electric devices. In particular, organic multiferoric materials may facilitate the development of a low nonvolatile, high density, and high-speed memory device exhibiting low power consumption that may be easily and inexpensively fabricated.
A major impediment to the development of such materials has been the lack of the ability of the devices formed of such materials to function at room temperature. Although single phase and composite multiferroic studies have been reported in cold temperatures, these multiferroic composite heterostructures have shown a very large extrinsic magneto-electric effect at room temperature. For example, the reported values for the magneto-electric coupling sensitivity range from 1 V/(cm×Oe) to 6 V/(cm×Oe), and up to 21 V/(cm×Oe) for bulk composites.
There remains a need therefore, for multiferroic materials in which ferroelectric and ferromagnetic properties may coexist at room temperature.
In accordance with an embodiment, the invention provides a ferromagnetic/ferroelectric heterostructure thin film that exhibits significant magneto-electric coupling. The ferromagnetic/ferroelectric heterostructure thin film includes a) a base layer of silicon substrate, b) a first copper layer deposited on the silicon substrate, c) a first iron layer deposited on the copper layer, d) first aluminum layer deposited on the first iron layer, e) a polymer layer exhibiting ferroelectrc properties deposited on the first aluminum layer, f) a second aluminum layer deposited on the polymer layer; g) a second iron layer deposited on the second aluminum layer, and h) a second copper layer deposited on the second iron layer.
The following description may be further understood with reference to the accompanying drawings in which:
The drawings are shown for illustrative purpose only.
Applicant has discover that compared with bulk magneto-electric composites, multiferroic magneto-electric films are attractive because they may be combined at an atomic level. Film materials such as PVDF-TrFE based multilayer films have shown a relatively large magneto-electric response. While significant progress has been made in studying the magneto-electric films, the origin of the magneto-electric coupling in polymer-based nanoscale heterostructures has not been clearly established.
A novel material consisting of a multiferroic thin film using ferromagnetic iron layers and ferroelectric polyvinylidene fluoride (PVDF) was demonstrated to have electric polarization tunability at room temperature by subjecting an external magnetic field to the material at room temperature. In the new material, changing the direction of the applied magnetic field resulted in the switching of electric polarization for the PVDF. Further, both the coercivity and polarization of the multiferroic PVDF polymer material displayed hysteretic features as the applied magnetic field is changed.
The invention described herein teaches the production of ferromagnetic/ferroelectric heterostructures fabricated by sandwiching a layer of PVDF polymer between two layers of iron thin films. Another aspect of the present invention is that other polymer materials having similar properties may be used. Such polymers include PVDF based ferroelectric copolymers. As shown herein, detailed measurements demonstrated that these heterostructures exhibited substantial magneto-electric effect at room temperature. The electric properties of the PVDF polymer may be tuned when a magnetic field is applied to the sample and this tuning effect showed clear hysteresis upon magnetic field. It has also been discovered that the thickness of the PVDF layer impacted the magneto-electric coupling strength in a linear response.
In the present invention, a new and simpler approach to making multiferroic heterostructures has been developed that includes ferromagnetic iron layers and ferroelectric polyvinylidene fluoride (PVDF) polymer layer. A schematic of one such heterostructured multilayer material is shown at 10 in
The multilayer material fabricated used a physical vapor deposition for magnetic layers and the Langmuir-Schaefer film fabrication method for PVDF layers. The thickness of each layer is precisely controlled and calibrated. A Radiant Technology Precision ferroelectric measurement system was used to measure the polarization versus electric field hysteresis loops of all the material samples. In performing the measurements, each sample was placed between the pole pieces of an electromagnet with the external magnetic field applied in parallel to the sample surface.
Novel Multiferroic Heterostructure that is Differentially Polarizable by an External Magnetic Field.
In contrast, the polarization versus electric field loop was taken at 93 mT magnetic field showed that the polarization was saturated at an electric field of 10.8 MV/m and it can be flipped at 7.9 MV/m. When the magnetic field goes back to zero from the maximum field of 93 mT, the electric polarization saturates at electric field of 8.9 MV/m and the coercivity is at 6.2 MV/m electric field. The polarization versus electric field loop taken at this zero magnetic field (labeled as 0 mT down in
To further characterize the magneto-electric coupling of the sample, a bias electric field of 6.0 MV/m was taken and plotted the polarization versus magnetic field. This result is shown as the upper inset of
Since the magneto-electric coupling was present in this sample, a series of samples with different PVDF polymer thickness were evaluated while the ferromagnetic iron layers were kept at a constant thickness. In order to compare the magneto-electric coupling strength in each of the samples, ΔEC, the width of the hysteresis curve of EC-H field graph (shown the black arrow), was plotted as a function of PVDF thickness shown as the lower inset of
The increase in ΔEC indicated that the magneto-electric coupling strength became substantially larger as the PVDF thickness increased. This cannot be explained by the simple strain effect. First, according to strain effect, the magnetostriction stress was kept the same for all our samples by keeping the ferric layers unchanged. When this same stress (or pressure) is applied to a thicker PVDF layer, the effect is expected to be smaller which is contradictory to our observed data. Second, magnetostriction should not be dependent upon the polarity of magnetic field for a strain effect, while these data showed sole dependency on the polarity of the magnetic field. It is believed that this is due to the significant magnetic field in the polymer layer generated by Fe ferromagnets. This magnetic field exerted a force on rotating dipoles of PVDF and affected the rotation of those dipoles. Further, the direction of this force was dependent on the polarity of the magnetic field. This magnetic force was able to affect and tune the polarization properties of the novel PVDF layer.
The magneto-electric coupling sensitivity is often used to characterize the performance of a magneto-electric material, and it is defined as
which quantifies the sensitivity for a ferroelectric layer as the applied magnetic field is changed. The sensitivity αE was estimated for each of samples analyzed. The change in the electric field of the polymer layer was estimated using the polarization versus magnetic field graphs. The values of magneto-electric coupling sensitivity αE of these experiments are 3700 V×cm−1×Oe−1, 30000 V×cm−1×Oe−1 and 41700 V×cm−1×Oe−1, for PVDF thickness of 35 nm, 52 nm, and 70 nm, respectively. The observed magneto-electric coupling sensitivities are as much as 2 orders of magnitude higher than previously reported values. When the thickness of PVDF is increased, the sensitivity increases. The thickness of the PVDF should reside between 20 nm and 100 nm.
In the prepared multiferroic film materials, it was demonstrated for the first time at room temperature that giant magneto-electric coupling in heterostructures could be easily produced by applying an external magnetic field. A further aspect of the invention is that one was able to tune the electric polarization of the ferroelectric PVDF layer. More importantly, as the applied magnetic field is varied, the properties of PVDF layer show hysteretic features. The variety of the material and affect was also shown that changing the thickness of the PVDF layer impacted linearly the magneto-electric coupling strength between the ferroelectric and ferromagnetic layers. The magneto-electric coupling sensitivity was estimated which is in the range of 3700 V/(cm×Oe) to 41700 V/(cm×Oe) for various samples.
Those skilled in the art will appreciate that numerous modifications and variations may be made to the above disclosed embodiments without departing from the spirit and scope of the present invention.
This invention was made with government support under Grant No.'s CCF-1017177, CCF-0311333 and ECCS-0931820 awarded by the National Science Foundation. The U.S. government has certain rights to this invention. The present invention is a U.S. National Stage filing under 35 U.S.C. 371(c) of International Application No. PCT/US13/43326 filed May 30, 2013, which claims priority to U.S. Provisional Appln. No. 61/653,864 filed on May 31, 2012, both of which are incorporated herein by reference in their entireties.
Filing Document | Filing Date | Country | Kind |
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PCT/US2013/043326 | 5/30/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/181370 | 12/5/2013 | WO | A |
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61653864 | May 2012 | US |