RU2510084C1 - Method of recording and reproducing information - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: in the method, the surface of the recorded sample layer is exposed to circularly polarised light, which is input into a waveguide by a near-field scanning optical microscope. The sample used is a nanostructured film of transition metal silicides on silicon. The sample is tested for suitability by magnetic force microscopy with minimal resolution, which enables to display the nanostructure of the sample, wherein the size of the nanostructures must not exceed 50 nm. The sample must have magnetic response and must be in a single-domain magnetisation state. The surface of the sample is brought closer, with precision, to an optical probe with optical efficiency of not less than 10^-6 and exposed to circularly polarised radiation with energy of not less than 3 mJ/cm² and continuous radiation power of about 1 mW. Information is read out using the scanning probe of the microscope in magnetic force microscopy mode in semi-contact mode by identifying magnetic properties of the nanostructured film.

EFFECT: high density of recording information.

2 cl, 4 dwg

Description

The invention relates to the accumulation of information, in particular to methods for superdense recording-playback of digital information.

A known method of recording and reproducing binary information by applying an energy beam to an amorphous layer containing silicon on the surface of the substrate and registering areas of change in the conductivity (or phase state) of this layer using a scanning tunneling microscope (STM) (EPO patent No. 0360337, G11B 9 / 00, 1990) or an impurity doped silicon semiconductor substrate, a silicon oxide film on the substrate, and a silicon nitride film on a silicon oxide film are used as a carrier. As a recording layer, a semiconductor or insulating substance formed by plasma spraying of hydrogen-containing silicon in vacuum can be used (EPO patent No. 4338256, G11B 9/00, 1991). As a result, a high density storage device is implemented.

However, this method does not allow to realize the benefits of STM for efficient and high-density recording-playback.

In part, this drawback is eliminated by a method based on recording by applying an electric beam to an amorphous silicon material obtained by hydrogen technology using carbon and germanium, and metal or glass or a silicon semiconductor single crystal as a substrate (RF patent No. 2042982, G11B 9/00, 1995) or the carrier is made in the form of a thin film of silicon oxynitride on substrates of low-resistance single-crystal silicon (RF patent No. 2044345, G11B 9/00, 1995).

Known methods for super-dense recording of information on a magnetic medium based on near-field interaction: magnetization reversal using circularly polarized light and magnetization reversal with a magnetic force microscope probe.

A known method of recording information in which the magnetization reversal was carried out by single pulses of duration 40 fs, a repetition rate of 1 kHz when the laser moves along the sample at a speed of 50 mm / s, so that each laser pulse hits a new point in the sample. Two passes were carried out - with different directions of polarization of light. In this case, the magnetization reversal occurred only in the domain in which the magnetic field of the domain was directed oppositely to the direction of the field created by circularly polarized light (Stanciu CD All-Optical Magnetic Recording with Circularly Polarized Light // Phys. Rev. Lett-2007. -v.99.- P.047601). The method of recording circularly polarized light demonstrates the maximum recording speed, but does not demonstrate a high recording density, since the diameter of the laser beam reaches tens of microns.

To increase the recording density in magneto-optical devices, it was proposed to use a near-field probe for recording / reading information (Betzig E. Near-field magneto-optics and high density data storage / Betzig E., JK Trautman, R. Wolf [et.al. ] // Appl.Phys.Lett-1992.-V.61., No. 2-P.). The recording principle in this method was assumed to be magnetic - laser radiation and a heated near-field probe heated the film to a Curie temperature, and magnetization reversal was carried out due to an applied external magnetic field.

In the patent US 8164988, 2012 proposed to combine two approaches - the use of circularly polarized light for magnetization reversal and near-field probe to increase the recording density. In this case, it was proposed to use substrates with ordered metallic magnetic islands separated by a nonmagnetic dielectric as an information carrier.

This technical solution is the closest in technical essence. The disadvantage of this technical solution is the use of information materials with islands of magnetic alloys in a dielectric matrix as a data carrier, which requires a rather complicated manufacturing technology. Also, such materials are not oriented towards integration with silicon microelectronics and the development of fundamentally new memory devices. As a result, this technical solution is aimed at creating an external storage device, with a scope similar to existing DVD / Blu-ray disc / read-only devices.

The problem to which this technical solution is directed is to use new magnetic materials compatible with silicon microelectronics for ultra-dense recording and reproduction of information.

The technical result consists in expanding the field of application of magnetic nanostructured transition metal silicides films for superdense recording and reproduction of information.

The technical result is achieved by the fact that the method of recording and reproducing information consists in exposing the surface of the recorded layer of the sample to circularly polarized light introduced into the waveguide by a near-field scanning optical microscope. According to the invention, a nanostructured transition metal silicide film on silicon is used as a sample, the region of the sample is pre-marked using magnetic coating scribing, the sample is examined by magnetic force microscopy using a range with a minimum resolution that ensures the display of the nanostructure of the sample, and the size of the nanostructures should not exceed 50 nm, the sample must have a magnetic response and be in a single-domain state of magnetization, the surface of the sample is precision aligned with an optical probe with an optical efficiency of no worse than 10 ^-6 and is exposed to circular light exposure with energy -polarized radiation of at least 3 mJ / cm ^2, a capacity of continuous radiation of ~ 1 mW, information reading is performed using kaniruyuschego probe microscope mode magnetic force microscopy in tapping mode by identifying the magnetic properties of the nanostructured film.

As transition metals, Ni and Co are used. Self-organized nanostructures of nickel and cobalt silicides obtained on silicon in a localized gas discharge and have magnetic properties as a result of the size effect (RF patent No. 2458181, С23С 14/40, 2012).

Exposure to circularly polarized light changes the magnetization state of the self-organized nanostructures of nickel and cobalt silicides.

Figure 1 shows a model of transitions between states in clusters of silicides Ni and Co; figure 2 - installation diagram for implementing the method; figure 3 is a topography of the surface (a) and the distribution of magnetization (b) in the Ni-Si system; figure 4 - the topography of the surface (a) and the distribution of magnetization (b) in the Ni-Si system after recording the image of the letter "V".

Let at the initial moment of time the magnetization of the cluster is directed downward (Fig. 1) and corresponds to the ground state of the electronic system. Magnetic quantum number m = -S. As a result of irradiation with light, a quantum transition occurs, accompanied by a change in the quantum numbers S »S - 1, -m> -m + 1. In Fig.1, this process is shown by the arrow a ₀ b ₀ . Being in an excited state, the electronic system begins to relax. One of the relaxation channels is a nonradiative transition to the ground state, in which the energy of the excited state passes into the energy of phonons. This process can occur without changing the magnetic quantum number m. It is depicted by the horizontal arrow b ₀ a ₁ . The energies of states a ₀ , a ₁ , and ₂ , ... differ by a relatively small value, the energy of the spin-orbit interaction. With further lighting, the process repeats. Thus, if the equilibrium spin of the electron system is equal to S, then the absorption of helically polarized 2S photons leads to magnetization reversal of the cluster. Therefore, this mechanism can be the basis for recording information.

The method can be implemented on the installation, the scheme of which is presented in figure 2.

The setup consists of an optical bench 1, holder 2, table 3, base of umbrella 4, holder of semiconductor laser 5, semiconductor laser 6, Fresnel rhombus 7, lens 8, positioner 9, holder of quarter-wave plate 10, quarter-wave plate in frame 11, holder of linear polarizer 12, a linear polarizer 13, a holder of photodiodes fd-24k 14, a laser power supply 15, a digital microammeter 16. Elements 10-14, 16 are used to configure an optical umbrella. When recording information, they are replaced by a sample for recording information with a system for bringing the sample to the umbrella.

To demonstrate the applicability of the obtained nanostructured films of transition metal silicides to fully optical recording by circularly polarized light, the following experiment was carried out on the setup shown in Fig. 2.

A sample with a nanostructured nickel silicide film was previously demagnetized and studied by magnetic force microscopy. The topography of the surface and the distribution of magnetization are presented in figure 3. The sample is a homogeneous nanostructured film with a narrow size distribution of nanostructures in the range of 30-50 nm. In the picture of the distribution of magnetization, the signal level does not exceed the noise level.

The previously studied sample was exposed to circularly polarized radiation in the setup shown in Fig. 2, where on the table 3 instead of elements 10-14, 16 a sample was installed to record information with the system for summing the sample with a precision linear encoder (Renishaw SIGNUM RELM). The approach of the umbrella to the sample was carried out using a stage with a micrometer screw and was monitored using a microscope. The accuracy of the draw was 2 μm.

A sample exposed to light was re-examined using magnetic force microscopy (using SPM Solver P47-Pro) to read information. For this, the sample was removed from the recording setup holder and installed in the holder of a scanning probe microscope. Using a marker on the sample, a search was made for the area in which information was recorded. In the selected region of the sample using the two-pass dynamic magnetic force microscopy technique, the magnetic properties of the nanostructured film of the sample were identified. To reduce the magnetization reversal of the sample at this stage, both passes were made in the semi-contact mode. In the picture (figure 4) of the distribution of magnetization, the result of recording the letter “V” with a laser beam is clearly visible. The line width is 1 μm, which correlates well with the proximity of the probe and the sample surface.

The result of a fully optical magnetization reversal of a nanostructured nickel silicide film, which has magnetic properties as a result of the size effect, was obtained for the first time.

To achieve the maximum recording density with full optical magnetization reversal, a precise approach of the optical probe to the surface and the choice of radiation power and exposure duration, which provide the maximum recording speed and do not cause damage to the optical probe, are necessary.

The required power at the input of the optical probe, which allows you to demonstrate a completely optical record of information according to the works (Zhdanov G.S. Optics inside the diffraction limit: principles, results, problems / Physics – Uspekhi. - 1998. - T. 168., No. 7. - C. 801-804; La Rosa AH Origins and effects of thermal processes on near-field optical probes / Appl.Phys.Lett.-1995.-V.67, No. 18.-P.2597-2599) at the laser input should be ~ 1 mW. This value is typical when using near-field probes and does not damage them even during continuous operation of the laser.

Thus, the use of near-field optical magnetization reversal with a continuous input radiation power of ~ 1 mW and an optical efficiency of the probe no worse than 10 ^{-6 is} possible at a magnetization reversal rate of 100 μm / s. To increase the magnetization reversal rate, it is necessary to increase the optical efficiency of the probe and increase the input radiation power.

Claims (2)

1. The method of recording and reproducing information consists in exposing the surface of the recorded layer of the sample to circularly polarized light, introduced into the waveguide by a near-field scanning optical microscope, according to the invention, a nanostructured transition metal silicide film on silicon is used as a sample, the region of the sample is pre-marked using magnetic scribing coatings, examine the sample by magnetic force microscopy for suitability with a minimum resolution, ensuring displaying the nanostructure of the sample, and the nanostructure size should not exceed 50 nm, the sample must have a magnetic response and be in a single-domain state of magnetization, the surface of the sample is precision aligned with an optical probe with an optical efficiency of no worse than 10 ^-6 and exposed to circularly polarized radiation with energy light exposure of at least 3 mJ / cm ² , continuous radiation power ~ 1 mW, information is read using a scanning probe of a microscope in the mode of magnetic force microscopy in tapping mode by identifying the magnetic properties of a nanostructured film. 2. The method according to claim 1, characterized in that Ni and Co are used as transition metals.

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