JPH0524566B2 - - Google Patents

Description

[Detailed description of the invention]

INDUSTRIAL APPLICATION FIELD The present invention relates to a method for recording and erasing signals on a rewritable optical information recording medium, and more particularly to a method (overwriting) for erasing old signals and recording new signals at the same time. 2. Description of the Related Art Two methods have been proposed for overwriting a rewritable phase-change optical information recording medium. One is to irradiate a recording medium with a laser beam that is modulated between two levels: a recording level and an erasing level, thereby erasing the old signal that has already been written and recording a new signal directly on top of it. (Japanese Unexamined Patent Publication No. 145530/1983). In other words, the area irradiated with high laser power melts and then rapidly cools down to become amorphous.
The parts irradiated with a lower laser power are annealed and crystallized without exceeding the melting point. With this method, a new signal can be recorded regardless of whether the material was amorphous or crystalline before irradiation with the laser beam, that is, it can be overwritten with a single laser spot. be. The other method is to install two or more laser spots on a track, erase the old signal at the preceding spot, and record a new signal at the following spot (Procedures of S.P. Proceedings of SPIE Volume 420 P.173~
P.177 (1983)). That is, erasing and recording are performed at independent spots, and pseudo overwriting is performed. Problems to be solved by the invention The overwriting function using a single laser spot has the advantage of a simple optical system and a simple control system, but on the other hand, it does not provide a sufficient erasing rate. There was a problem. In addition, the method of installing two or more laser spots on a track and recording and erasing signals at independent spots has a greater effect than overwriting with a single laser spot due to the effect of the preceding spot dedicated to erasing. The erasure rate can be obtained. However, tracking control is generally performed for only one spot to simplify the system, and other spots are designed to follow. Therefore, it becomes more difficult to accurately install two or more spots on a track with a gap between them as the spacing between the spots increases, which becomes a big problem especially when mass production is considered. Means for Solving the Problem Two or more circular or nearly circular spots are placed close to each other on the recording track, and old signals are erased by increasing the power of the first spot to a level higher than that of melting the recording thin film. New signals are recorded by modulating subsequent spots with the signal to change the cooling rate of the portion melted by the leading spot. Function In a phase change type rewritable recording medium, by once melting the irradiated part, the history of that part can be almost erased. Therefore, the first spot sufficiently erases the old signal, and the subsequent spots control the cooling rate of the molten part to achieve two states, crystalline and amorphous, and record the signal. This method provides a high erasure rate and, at the same time, because the laser spots are placed very close together (sometimes even partially overlapping), they can easily be placed on the same track. Become. Example The reason why the erasure rate is low in the case of overwrite recording with a single laser spot is considered to be that traces of old signals remain as differences in crystal grain size. That is, in the portion annealed below the melting point, the crystalline state differs depending on whether or not a recording bit was previously recorded, and this results in a difference in optical properties. In other words, in order to sufficiently erase old signals, it is sufficient to melt the recording track by continuously irradiating it with laser light and erase the history up to that point. This is the role of the leading spot in the present invention. Whether the portion continuously irradiated with laser light ultimately becomes an amorphous state or a crystalline state depends on the recording thin film. In the present invention, a recording thin film that becomes an amorphous state is used (whether it ultimately becomes an amorphous state or a crystalline state is not determined only by the composition of the recording thin film; for example, the thickness of the recording thin film, the thickness of the protective film, etc.) (It can also be controlled by changing the material, etc.) This is achieved when the cooling rate is too high to allow crystallization. Here, if the cooling rate could be temporarily reduced, that portion should be able to be crystallized. This is the second (or after the second)
This is the role of the laser spot. That is, 2
When the second laser spot is off, the molten part cools rapidly and becomes an amorphous state, but when it is on, the molten part cools slowly and becomes a crystalline state.
In other words, by modulating the second laser spot between on and off in response to the signal, a new signal can be recorded. This method records a new signal by controlling the cooling rate of the area irradiated by the erase spot, and uses two or more conventional laser spots to erase the old signal at the preceding spot and then record it again at the subsequent spot. The way to record new signals is different. In the conventional example, the erasing spot and the recording spot needed to be spaced so that they did not affect each other thermally, but with the present invention, they can be placed very close together, making positioning of the laser spot very easy. There are merits. FIG. 1 shows an example of the configuration of a laser spot and the irradiation method for carrying out the optical information recording/erasing method of the present invention. FIG. 1a shows an embodiment in which two circular laser spots are arranged on the track 3. The preceding laser spot 1 is for temporarily melting the recording thin film, and is continuously irradiated with constant power. Further, the subsequent laser spot 2 is modulated by the recording signal, and the temperature profile when it is on is as shown in Figure 1b, and the temperature profile when it is off is as shown in Figure 1c. Become. That is, when in the on state, the irradiated part slowly cools and crystallizes, but when in the off state, it rapidly cools and becomes amorphous, so it is possible to create a state of high reflectance and a state of low reflectance depending on the modulation signal. Note that all laser spot diameters in this specification are expressed in terms of the half width of the energy density. Furthermore, since it is easier to install two spots on the track at the same time if the spots are as close as possible, this embodiment shows a case where spots 1 and 2 partially overlap. However, as long as the condition that the signal is recorded by controlling the cooling rate of the molten portion is satisfied, spots 1 and 2 may be separated. Further, in this embodiment, the spots are both circular in shape, but may be substantially circular. In particular, if the subsequent spot 2 has a substantially circular shape that is long in the track direction, the difference in cooling rate between when the spot 2 is on and when it is off becomes large. Even a thin recording film can be sufficiently crystallized. However, since the shortest recording bit length is approximately proportional to the length of the spot 2 in the track direction, making it too long in the track direction will increase the shortest recording bit length and reduce the recording density.
We must be careful about this. Considering that the light emitting pattern of laser diodes currently in practical use is approximately circular with an elliptical ratio of about 1:2, if the shape of spot 2 is selected to be approximately circular, a simple lens system can be created. It is possible to efficiently collect light. In other words, it is possible to realize an optical system with high transmission efficiency and low cost. The optical information recording/erasing method of the present invention can be effectively applied to any recording medium to which reversible phase change between amorphous and crystal or crystal and crystal is applied. Among the phase change materials between amorphous and crystal, GeTe, GeSb ₂ Te ₄ , Ge ₂ are materials that crystallize very rapidly.
Sb ₂ Te ₅ , InSe series, InSeTlCo series, etc. GeSnTeAu series, materials that crystallize relatively quickly
GeSbTeSe series, GeSnTeO series, SeTeSn series, etc. can be used. Further, as the crystal-crystal phase change material, InSb-based, AgZn-based, etc. can be used. Next, the present invention will be explained in detail using specific examples. Example 1 FIG. 2 shows a cross-sectional view of the optical disk used in the experiment. A 100 nm ZnS protective layer 2 and a 60 nm GeSb ₂ on a polycarbonate substrate 1 with a thickness of 1.2 mm and a diameter of 130 mm.
Te ₄ recording layer 3, 200nm ZnS protective layer 4, 20nm
Au reflective layers 5 were sequentially laminated, and a back cover 7 made of the same polycarbonate as the substrate was laminated thereon with an adhesive 6 to prepare an optical disk. Each layer is 1x
It was formed by vapor deposition under a vacuum of about 10 ^-4 P. Three sources are used to form the recording layer, and each deposition rail is controlled so that the substrate is rotated to pass over each source in turn. Track grooves for light guides are preformed on the substrate. Record erasure tests using disks were conducted while comparing a dynamic tester (deck) equipped with a laser spot according to the present invention and a dynamic tester equipped with a conventional laser spot. The configuration of a laser spot according to the invention is shown in FIG. 3a. In other words, as the preliminary spot 8 for melting the recording film, a laser beam with a wavelength of 830 nm was focused into a circular light spot with a half width of 0.9 um. The cooling rate is controlled by signal modulation, and as the subsequent spot 9 for recording information, a laser beam with a wavelength of 780 nm was focused into a round optical spot with a half width of 0.8 um. The distance between the centers of the two spots is approximately
Since the thickness was set to 0.7 μm, some parts overlapped. Therefore, the distance from the beginning to the end of the two spots is about 1.5 μm. The configuration of a conventional laser spot is shown in FIG. 3b. Leading oval spot (wavelength
830 nm, half width of about 1×7 μm) is for erasing, and the old signal is erased by slowly heating and cooling the track groove to crystallize the amorphous mark.
Subsequent spots (wavelength 780nm, half width approx. 0.8μm)
is for recording, and records signals by raising the temperature of the recording film above its melting point and then rapidly cooling it to form an amorphous mark. In this case, the erasing spot and the recording spot were placed approximately 5 μm apart so that the quenching conditions of the irradiated part of the recording spot were not disturbed. That is, the distance from the beginning to the end of the two spots is approximately 13 μm. The disk rotates at 3600rpm and has a linear velocity of
An overwrite experiment was conducted at a point of 15m/sec. The experimental procedure is shown below. a. First, record a signal with a frequency of 5MHz on the track. The signal-to-noise ratio (C/N) at this time was approximately 53 dB. b Record a new 3MHz signal while erasing the 5MHz signal by overwriting. At this time, in the case of the configuration of the present invention, the power of each spot is
Leading spot is 16mW, trailing spot is 7mW,
In the case of the conventional configuration, the leading spot is
20mW, followed by 18mW. c Measure and evaluate the erasure rate of the erased 5MHz signal and the C/N of the newly recorded 3MHz signal using a spectroanalyzer. The experimental results are shown in Table 1.

[Table] As can be seen from Table 1, the configuration according to the present invention has a higher erasing rate and comparable C/N than the conventional example. The reason why the configuration according to the present invention has a higher erasing rate is considered to be because the recording film is once melted by the preceding spot, so that the old signal can be almost completely erased. In other words, it can be seen that according to the present invention, recording and erasing characteristics equivalent to or better than those of the conventional example can be achieved with the two spots placed very close together (approximately 0.7 μm in this example). Effects of the Invention According to the present invention, a high erasure rate can be obtained, and at the same time, since the laser spots are installed very close to each other (in some cases, they partially overlap), they can be installed on the same track. This makes it possible to provide an optical information recording/reproducing/erasing device that is easy to mass-produce.

[Brief explanation of the drawing]

FIG. 1 is a diagram explaining the shape and arrangement of a laser beam spot applied to the optical information recording/erasing method of the present invention and its role, FIG. 2 is a sectional view showing the structure of an optical disc, and FIG. FIG. 2 is a diagram showing a spot configuration according to the present invention used in a specific example and a spot configuration according to a conventional example. 1... Spot 1, 2... Spot 2, 3...
Track groove.

Claims (1)

[Claims] 1. Erasing old signals on a reversible optical information recording medium that has a thin film of phase-change recording material on a substrate, the optical characteristics of which change reversibly in response to light irradiation conditions. In this method, two or more circular or nearly circular spots are placed close to each other on the recording track, and the old signal is erased by applying a power that melts the recording thin film to the first spot. A new signal is recorded by modulating the subsequent spots with a signal at a lower power density than the first spot, changing the cooling rate of the part melted by the first spot. 1. An optical information recording erasing method characterized in that the method is carried out by 2. The optical information recording and erasing method according to claim 1, wherein two or more circular or substantially circular spots overlap each other. 3. The optical information recording and erasing method according to claim 1, wherein the number of spots is two. 4 The shape of the subsequent laser spot has an ellipticity of 1:
2. The optical information recording and erasing method according to claim 1, wherein the optical information recording and erasing method has a substantially circular shape with a ratio of 1 to 2:1. 5. The optical information recording and erasing method according to claim 1, characterized in that the thin film of phase change type recording material is one in which reversible phase change between amorphous crystals is applied.