DE19644484A1 - Magnetic disc arrangement for hard disc drive - Google Patents

Abstract

The magnetic disc comprises a data zone for writing and reading of data, and a Contact-Start-Stop (CSS) zone which includes a take-off/landing area and a stop area for a contacting of a magnetic head on the disc. Several projections are provided in the CSS zone, whose heights in the take-off/landing area decrease in a radial direction from the center of the disk towards the data area. An average gradient of the height of the projections in the take-off/landing area is around 1*10<->6 to 5*10<->5, and the maximum height of the projections in the CSS zone is larger than the altitude of the magnetic head in the data zone. The minimum height of the projections in the CSS zone is less than the altitude of the magnetic head in the data zone.

Description

The present invention relates to a magnetic disk and a Data writing / reading process, and particularly concerns one Magnetic disk for performing the writing in / reading out of Data through a so-called system with contact at the start and at the stop (CSS system), as well as a Data registration / readout procedure.

Usually the writing and / or reading out of Information to / from a magnetic disk through a magnetic head carried out. In a drive for rigid magnetic disks the magnetic disk rotated at high speed so that the magnetic head "flies" or hovers. With the magnetic disk there is a mechanical polishing process, essentially concentric in the circumferential direction of the magnetic disk to a Manufacturing trace (a surface texture pattern) form their surface (hereinafter referred to as "mechanical Surface structure ") to the magnetic To improve properties. Usually it will mechanical surface structure on the surface of a non-magnetic substrate or on an underlayer, which consists of Ni-P or Cr, and arranged on the substrate is.  

With increasing amount of information and the need for Downsizing and after training the storage device with the linear recording density and the track density increased so that by the existing Surface structure caused scratches with high Probability to lead to errors. Therefore proposed a method in which the mechanical surface structure only created in one zone in which a process with contact at start and stop is carried out (in a so-called CSS zone), on Inner circumference of the magnetic disk, while one Data recording zone (data registration zone) unchanged remains. However, the surface of the Data write zone higher than the surface of the CSS zone trained, and since it is difficult to transition between the data registration zone and the CSS zone smooth and with With a gentle inclination, the difficulty arises that the magnetic head hits or crashes during the search process.

Furthermore, instead of the mechanical surface structure a method for generating a surface structure pattern suggested by a laser beam (so-called laser Surface structure). For example, U.S. patents suggest No. 5,062,021 and 5,108,781 the procedure before, locally a Ni-P layer through the beam of a Q-switch laser (Nd- YAG) to melt, this laser beam being a very narrow one Has pulse width and a very high energy density, whereby a crater-shaped protrusion is created, whereby the CSS properties related to the magnetic head by the circular rim of the crater can be improved.

With the laser surface structure described above can only this structure or surface texture  the CSS zone of the magnetic recording medium will. However, the protrusions must be in the CSS zone have at least a certain height, so none Eating process between the magnetic head and the disk is caused, so that the levitation of the head by the height of the protrusions is determined. Because the levitation of the Recording medium through the hovering height in the CSS zone is determined, is therefore the height of the head in the Data write zone too high, which leads to the problem that the recording density cannot be increased sufficiently.

In the data registration / readout process for one Magnetic disk is therefore essential, like the stable one Flying height of the magnetic head in the data write zone is reduced, or like an eating process at a stop Position of the magnetic head is prevented.

As a result of the experiments carried out by the present inventors, it was found that the magnetic head can perform a stable CSS operation in the search operation when using a disk drive having a magnetic head for writing / reading data into / from a magnetic disk, wherein the magnetic head hovers or flies at a predetermined flying height, the magnetic disk has a zone with contact at start and stop (CSS zone), which has a take-off / landing area and a stop area, for an operation with contact at start and stop of the magnetic head, and a data zone for writing / reading out data, wherein a plurality of protrusions are provided in the CSS zone, the height of the protrusions in the take-off / landing area decreases from the inside to the outside in the radial direction of the plate, the mean gradient of the height of the protrusions in the take-off / Landing area is 1 × 10 ^-5 to 4 × 10 ^-5 , the maximum height of the projections in the CSS zone h is higher than the flying height of a magnetic head in the data zone and the minimum height of the protrusions in the CSS zone is lower than the flying height of the magnetic head in the data zone. The present invention has been accomplished based on these results.

An object of the present invention is Provision of a magnetic disk for a magnetic High density recording, and one Data registration / readout process, which the services of the Can fully utilize the recording medium.

To achieve this goal, according to a first aspect of the present invention, there is provided a magnetic disk for performing data writing / reading out by a system with contact at start and stop (CSS system), which has a data zone for writing in / reading out data Data and a zone with contact at start and stop (CSS zone), which has a take-off / landing area and a stop area, for an operation with contact at start and stop (CSS operation) of a magnetic head,
where there are several protrusions in the CSS zone, the height of the protrusions in the take-off / landing area decreases in the radial direction from the center of the magnetic disk to the data write-in zone, the mean gradient of the height of the protrusions in the take-off / landing area is 1 × 10 ^-5 to 5 × 10 ^-5 , the maximum height of the protrusion in the CSS zone is higher than the flying height of the magnetic head in the data zone, and the minimum height of the protrusions in the CSS zone is lower than the flying height of the magnetic head in the data zone.

In a second aspect of the present invention, there is provided a method for performing data writing / reading out by a system with contact at start and stop, which comprises the following steps:
Use of a magnetic disk having a data zone for writing / reading out data and a zone with contact at start and stop (CSS zone), which is provided with a take-off / landing area and a stop area, for an operation with contact at start and stop (CSS operation) of a magnetic head,
a plurality of protrusions are provided in the CSS zone, the height of the protrusions in the take-off / landing area decreases from the center of the magnetic disk in the direction of the data write-in zone in the radial direction, the average gradient of the height of the protrusions in the take-off / landing area 1 × 10 ^{- 6} to 5 × 10 ^-5 , the maximum height of the projections in the CSS zone is greater than the flying height of the magnetic head, and the minimum height of the projections in the CSS zone is lower than the flying height of the magnetic head,
Performing a head search with contact and reducing / increasing the rotational speed of the plate on the bevelled protrusions, and
Performing a record / read operation by flying the magnetic head at a height less than the maximum height of the protrusions.

The invention is illustrated below with reference to drawings illustrated embodiments explained, from which further advantages and features emerge. It shows:

FIG. 1 is an explanatory diagram showing the basic construction of an embodiment of a laser beam irradiation device; and

Fig. 2 (a) is a perspective view showing the shape of a projection which is formed by laser surface structure in Example 1, and

Fig. 2 (b) is a vertical cross sectional view of a plane which passes through the center of the protrusion obtained in Example 1 and in which the scanning direction of a laser beam lies.

Below are further details of the present Invention explained. First, a magnetic disk according to the described the present invention. The magnetic disk according to The present invention is a magnetic disk which Writing / reading data using a system with Contact at start and stop (CSS system). The Magnetic disk according to the present invention has several Tabs on what conditions in the CSS zone are enough.

The magnetic disk has at least one magnetic layer on, optionally with a lower layer and one on top located intermediate layer, on a non-magnetic Substrate, and as desired a protective layer on the magnetic layer. The protrusions can at least either with the substrate, the lower layer, the  Intermediate layer, the magnetic layer and the Protective layer may be provided.

An aluminum alloy substrate, a glass substrate or a Silicon substrate can be used as the substrate, but it a substrate can also be used, which consists of a other metal such as copper and titanium, or a Carbon substrate, a ceramic substrate or a Synthetic resin substrate. A substrate can be used as the silicon substrate pure silicon as well as a substrate from a Silicon compound can be used, the trace proportions of Contains elements to increase strength.

If the projections are irradiated with a high-energy beam, such as from a laser, is a material with low reflectivity on the Surface and low heat diffusion are suitable as substrates, considering the relationship of heat generation by Irradiation and heat dissipation through heat conduction. In addition, a substrate is preferably used, the by polishing as flat as possible to make the reduce stable flight altitude on the data zone.

The magnetic recording medium can thereby be obtained that the magnetic layer is directly on the surface of the substrate is formed, but usually the magnetic layer provided on an underlayer, the is on the surface of the substrate. As Bottom layer is suitable a non-magnetic bottom layer which consists of a Ni-P alloy, and such Normally, the lower layer is replaced by an electroless one Plating process or a sputtering process.  

The thickness of the underlayer is usually between 50 and 20,000 nm, preferably between 10 and 15,000 nm.

An intermediate layer, for example a Cr layer or a Cu layer, can be between the substrate or the underlayer or the magnetic layer can be provided. The thickness of the Intermediate layer is usually between 20 and 200 nm, preferably 50 to 100 nm. The magnetic layer (the magnetic recording layer) has one ferromagnetic alloy thin film, for example made of an alloy based on Co-P, Co-Ni-P, Co- Ni-Cr, Co-Ni-Pt, Co-Cr-Ta, Co-Cr-Pt or Co- Cr-Ta-Pt, and is for example by electroless Plating, electrical plating, sputtering or Vapor deposition (vacuum evaporation) produced. The fat the magnetic recording layer is usually in the Range from about 30 to 70 nm.

Usually a protective layer is placed on the surface of the manganese recording layer. The Protective layer has a carbon film, one Hydrocarbon film, a carbide film made of TiC or SiC, a nitride film such as SiN or TiN or an oxide film about from SiO, Al₂O₃ or ZrO, and is for example by means of Vapor deposition (vacuum evaporation), sputtering, plasma CVD, Ion plating or a wet process. As A carbon-containing film is preferred over the protective layer especially a hydrocarbon film or a Carbonitride film is preferable.

Furthermore, there is usually a layer of lubricant on the Surface of the protective layer arranged. As a lubricant For example, a liquid lubricant  Fluorocarbon base used, and the lubricant layer is usually on the surface of the protective layer for example, manufactured by an immersion process. Becomes however, a magnetic head with a diamond-like one Carbon layer used on a sliding surface, so it is not always necessary the protective layer or the Lubricant layer to be provided because the tribological Properties between the magnetic head and the magnetic Recording medium are improved.

As a method of forming protrusions in the CSS zone in which the magnetic head performs the CSS operation, laser surface structure processing using a laser beam irradiation device can be used. Fig. 1 explains the basic structure of an embodiment of a laser beam irradiation device. The laser beam irradiation device shown by way of example in FIG. 1 mainly has a generation device 1 for a pulsed laser beam, a light condenser device 2 , a point movement device 3 , a substrate movement device 4 and a substrate rotation device 5 , 5 .

The pulsed laser beam generator 1 functionally includes a laser beam generator using a solid-state laser source and an optical modulation device for modulating the laser beam to generate a pulsed laser beam. In the drawing, reference numeral 6 denotes a substrate. Although two substrate rotators 5 are shown, any number of substrate rotators may be provided.

Any normal condenser device (objective lens) can be used as the light condenser device 2 , provided that a desired small point is obtained. The light condenser device is normally used in combination with an auto focusing system (AF system). For example, a linear sliding device can be used as the point moving device 3 and the substrate moving device 4 . The point moving device 3 carries the generating device 1 for the pulsed laser beam and the light condensing device 2 , and moves together with these parts in the linear direction. The substrate moving device 4 carries the substrate rotating device 5 explained in more detail below, and moves together with the rotating device in the linear direction.

The point moving device 3 has the task of constantly changing the position of the point on the manufacturing surface. Such a change in position has a relative relationship between the point and the manufacturing surface. Therefore, it may be sufficient if the laser beam irradiation device shown in FIG. 1 contains either only the point moving device 3 or only the substrate moving device 4 . Usually, it is preferred to move the point itself through the substrate moving device 4 .

For example, a spindle motor is used as the substrate rotating device 5 , and the substrate 6 is held by a rotating shaft of the spindle motor, and is moved at a constant speed or constant linear speed.

Fig. 2 (a) shows in perspective view the shape of a protrusion obtained by laser surface treatment in Example 1, and Fig. 2 (b) is a vertical cross sectional view taken along a plane through the center of one obtained in Example 1 Protrusion passes, and in which the scanning direction of a laser beam lies. The mechanism of the projection formation by the laser surface structure processing is not yet fully understood, but can be understood as follows.

Here, a point portion that is locally heated on the surface on which the protrusion is to be formed is partially melted, and the melted portion is moved by the rotation of the substrate or the scanning of the laser beam. A section originally irradiated by the beam leads to a temperature gradient as a result of the subsequent temperature drop. Since the surface tension is generally higher on the lower temperature side, the initially melted and then cooled to a lower temperature bulges out by taking up a liquid melt from a section which is then melted due to the difference in surface tension, so that the shape of a projection results, as shown in Fig. 2. Therefore, an indentation occurs in the final melted portion. In this case, an indentation is often present behind a convex projection in the scanning direction of the laser beam.

Furthermore, the indentation can sometimes be due to the extent of Be brought about by Heat shrinkage, depending on whether the  Scanning speed of the laser beam or the Rotation speed of the substrate is low, or the Power of the laser beam high. Although this phenomenon has not yet been fully understood, it can be explain as follows. Because the locally heated Point section expands, but its circumference cools and is less deformable, the extended section becomes direct cooled by the ambient air so that it acts as a projection is left. Then the indentation is through Heat shrinkage is generated on the circumference of the protrusion.

The height of the projection can be adjusted as desired the intensity of the laser beam, the middle one Irradiation time and the linear velocity of the substrate being controlled. The density of the protrusions can vary depending on Desired to be controlled by the number of Tabs per round is set that Radiation interval of the pulsed laser in the radial direction, and the conditions for controlling the height of the protrusions. Under the height of the protrusions, such a height is the Protrusions with respect to a center line for one To understand roughness curve as it passes through the Surface roughness is defined in accordance with JIS (B0601-1982). Furthermore, the density of the protrusions does not denote that average density over the entire medium, but the density the projections per unit area in an area in which protrusions are present.

Usually it is preferable that the intensity (power) of the laser is between 20 and 500 mW, the middle one Irradiation time between 0.05 to 100 µsec, the Spot diameter of the laser beam between 0.2 and 4 microns, and the linear velocity of the substrate between 0.8 and 14  m / sec. If, however, spiral projections in the form of a Mountain range are generated, the laser beam is used for this caused to oscillate continuously while the Scanning is carried out by the laser beam in the radial direction.

In the magnetic disk according to the present invention, a plurality of protrusions are provided in the CSS zone, which includes a take-off / landing area and a stop area, the height of the protrusions in the take-off / landing area decreasing radially from the center of the magnetic disk toward the data writing zone , the average gradient of the height of the projections in the take-off / landing area is 1 × 10 ^-6 to 5 × 10 ^-5 , preferably 5 × 10 ^-6 to 2 × 10 ^-5 , the maximum height of the projections in the CSS zone is higher than the flying height of the magnetic head in the data zone, and the minimum height of the protrusions in the CSS zone is less than the flying height of the magnetic head in the data zone. Here, the mean gradient = (the difference between the height of the protrusions that are closest to the center of the magnetic disk in the radial direction in the CSS zone and the height of the protrusions that are closest to the data write-in zone in the radial direction in the CSS zone ) (width of the CSS zone). The upper limit of the flying height of the magnetic head according to the present invention is preferably 60 nm, and the lower limit of the flying height of the magnetic head according to the present invention is preferably 1 nm.

In a stop area (for example about 1 mm) of the magnetic head which is present in the CSS zone in the radial direction, the stop area being an area in the CSS zone which is closer to the center of the magnetic disk, the height of the projections preferably decreases Center of the magnetic disk towards the data write zone in the radial direction, the maximum height of the protrusions is not greater than 200 nm, preferably between 20 and 50 nm, the protrusion density is between 10 and 10 ^-6 N / mm², and the average gradient is Height of the protrusions in the CSS zone 5 × 10 ^-6 to 2 × 10 ^-5 . For a smooth landing and lifting of the magnetic head in the search state, the mean gradient of the height of the projections in the stop area is preferably 5 × 10 ^-6 to 2 × 10 ^-5 .

The average gradient is preferably the height of the Projections in the stop area equal to the middle one Gradient of the height of the protrusions in the Take off / landing area, and the slope (the "Slope") the height of the protrusions in the stop area and the take off / landing area steadily. Furthermore, it is preferable that the height of the protrusions in the stop area at the Maximum height of the projections in the take-off / landing area flat is trained.

Preferably, the magnetic disk according to the present Invention several protrusions by scanning the Energy beam are formed in the CSS zone, the average height of the projections provided in the same track in the CSS zone is between 1 and 60 nm, the Projection density is 10 to 10⁸ mm², and the average Area of a figure by an edge line at a height surrounded by 1 nm below the tip of each of the protrusions is (hereinafter referred to as "edge line area") is more than 1 µm², and the vertical cross-sectional shape a plane that goes through the center of the ledge, and the scanning direction of the energy beam contains one Has indentation on one side at the bottom of the projection.  

If the average height of the same track in the CSS zone existing projections exceeds 60 nm, the CSS properties can be satisfactory, however, the stable Flight height of the head can not be reduced. On the other hand the average height of the same track in the CSS zone existing projections smaller than 1 nm, so the Projections in the inevitable, small Bumps in the substrate are hidden, causing the Achieving the desired effect becomes difficult. If the The density of the protrusions is not larger than 10 (N / mm²) it also difficult the bottom surface of the Support the magnetic head only by the projections, as a result waviness and the like of the substrate. Exceeds on the other hand, the density of the projections is 10⁸ (N / mm²), so it becomes difficult to get an even height of the protrusions to achieve. If the edge line area is larger than 1 µm² is seized on the magnetic Recording medium occur and the magnetic head tilts a decrease in CSS characteristics.

It is essential that the magnetic disk according to the present invention has protrusions in the CSS zone, in which the magnetic head performs the CSS operation, where the height of the protrusions towards the Data registration zone decreases. If such a magnetic disk is used and the magnetic recording device remains stationary, so the magnetic head is on a section the CSS zone, in which the height of the projections is high, making it less for clinging or seizing tends. Then when a drive device is put into operation the magnetic head moves to a portion of the CSS zone in which the height of the protrusions is less with progressive rotation of the plate. this section  causes a seizure when the magnetic head is on the Magnetic disk stops, but is designed so that the Frictional force in the state of the sliding movement sufficiently small is. Since the protrusion density is high, one results here excellent wear resistance. Reaches the number of Revolutions of the medium a predetermined high speed, so the magnetic head leaves the medium completely and can move freely on the data entry zone.

Assuming that the standard deviation of the height of the projections, which are present in an optionally provided radial region with a width of 50 μm on the magnetic plate, is equal to σ, the magnetic plate according to the present invention preferably has a value 2 σ of no longer than 15%. This means that preferably the height of the protrusions on the surface of the magnetic disk is less
Has scatter, and a more preferred value for 2σ is less than 10%.

Furthermore, preferably as a magnetic disk according to the present invention uses a magnetic disk which is the protrusion density in the take off / landing area (Landing area) of the magnetic head is higher than that Projection density in the stop area of the magnetic head. A Such magnetic disk is preferred because the abrasion a portion of the protrusions after the start of the CSS operation can be reduced. The ratio of the projection density in a freely selectable location in an area with a width of 1 mm compared to the data entry zone in the CSS zone in Radial direction to the projection density on a freely selectable Location in the area (stop area) with a width of 1 mm further inside of that closest to the center in the CSS zone the magnetic disk is located in the radial direction  usually greater than 1 and not greater than 100 preferably between 2 and 20, particularly preferably between 2 and 10.

A description is given below Data enrollment / readout procedure according to the present Invention.

In the data registration / readout procedure according to The present invention will read / write Data through the magnetic head into the magnetic disk through the CSS system implemented. In the method according to the invention has a used plate protrusions in a CSS zone in which a magnetic head performs a CSS operation, and is the writing / reading carried out by: lets the magnetic head fly at a height that is less than the maximum height of the protrusions. The above described magnetic disk according to the present invention is suitable for such an operation.

Usually the ratio of the height (Hs) is for the Stop area of the magnetic head in the CSS zone at flight altitude (Hf) of the magnetic head in the data write zone inside a range of more than 1 to not less than 100, preferably more than 1 to not less than 50, especially preferably more than 1 to not less than 10. The values for Hs and Hf can be measured with a slide tester be determined using a plate with Standard increases that have a standardized amount.

As described above, according to the present Invention preferred that the magnetic head perform the CSS operation performs while searching. If the  Magnetic head that performs the CSS operation is therefore the Magnetic head caused by the beveled section to take off or land on the ledge while he seeks. When the magnetic plate stops and stops moves, the magnetic head is moved to a higher section of the Moving ahead in reducing the Speed of rotation during the search, and the Rotation of the magnetic disk is at the final stationary position of the magnetic head stopped.

While the magnetic recording device is being driven, is when the magnetic head is not searching the data write zone, the magnetic head preferably in the standby state in the CSS zone, in which is the height of the protrusions less, for emergencies such as irregularities in the mains voltage supply and the like. Therefore, the CSS zone is preferred lower height of the projections on a sliding height, which in is substantially the same as that of the data registration zone. If the magnetic recording device in the driven state to stop, the magnetic head lands first while he is in the search process, in the beveled area the CSS zone, in which the height of the protrusions gradually rises, and then moves to a section in which the height of the protrusions is greater, associated with one Reduction of the speed of the magnetic disk.

The magnetic disk according to the present invention can the magnetic head is stable during the search process Carry out CSS operation because convex protrusions in one CSS zone are present, in which the magnetic head one CSS operation performs the amount of protrusion towards the data write zone is reduced, the slope of the  Projection is sufficiently small in a section that at is in high speed contact with a magnetic head, and the protrusion density is large in a portion which is in the Contact with a magnetic head at high speed reached.

Because the magnetic head moves at low speed of the medium and a final stop or stop area of the Magnetic head with a section with convex projections is the height of the projections, when stopping the Magnetic head caused no seizure. If the magnetic head the data zone searches, the flight altitude can be as far as can be reduced, and the magnetic head after the Stop arranged on a sufficiently high ledge be, so that a magnetic recording device with high density by practically the same Procedure as used in the usual CSS operation.

In summary, according to the present invention Data registration / readout procedure provided, which the adhesive properties of the magnetic head on the Surface of the medium can improve, and the flight altitude of the Magnetic head in a data registration zone as much as possible can decrease while satisfactory CSS characteristic is maintained.

EXAMPLES

The present invention will be further hereinafter Details described with examples on which however, the present invention is not limited.  

Example 1 and Comparative Examples 1 to 2

An Al substrate with a diameter of 90 mm, coated with a Ni-P underlayer was made by creating a mechanical surface structure polished in the circumferential direction, the surface roughness (Ra) in data zones and CSS zones to decrease to not more than 1 nm.

Then a pulsed argon laser (at 488 nm) was left, the Intensity with high accuracy to that in Table 1 to Table 3 specified values was regulated on a CSS zone irradiate the Ni-P layer to form protrusions, their height gradually towards the data registration zone decreased. The protrusion density was in a section in the CSS zone with a height of the protrusions corresponding to the Flying height of the magnetic head increased. The Irradiation conditions and the height of the protrusions in each Radius are given in Tables 1 to 3. The numeric Aperture (NA) of objective lenses is in each case in the tables specified. A point diameter in which 84% of the energy concentrated, results from 1.22 × k / NA. The Cross-sectional area of the protrusion is a cross-sectional area in a section 1 nm below the upper end of the Lead.

Then an Cr intermediate layer (100 nm) was applied magnetic film (50 nm) made of a Co-Cr-Ta alloy and a carbon protective film (20 nm) in succession on the Substrate formed by a sputtering process, and then was immersed in a thickness of 2 nm by an immersion method liquid fluorine-based lubricant ("DOL-2000", manufactured by Monte Edison Co.) piled up to a Get magnetic disk.  

In the magnetic disk produced in this way, the static coefficient of friction before the CSS attempt (Static friction) and the frictional force after 20,000 CSS cycles measured. The results are shown in Table 4. By doing CSS experiment was a thin film head with a load of 6 Gram (sliding material: Al₂O₃ TiC) used, and the measurement was at a head flight height of 0.8 µinch carried out (1 inch = 25.4 mm). Furthermore, the stable Flying height (sliding height) of the magnetic head in the Data enrollment zone using a Sliding test device determined. The magnetic disk at the Comparative Example 1 had a sliding height of 1.5 µinch, whereas the magnetic disk in Comparative Example 2 one Had a sliding height of 0.7 µinch in the CSS zone.

Tables 1 to 3 show characteristic values of the magnetic disks, and Table 4 shows the results of the CSS experiment. In Table 1, "r" denotes a distance from the center of the magnetic disk, with a CSS zone (3 mm) in R = 18-21 mm. The standard deviation value 2σ in Table 1 gives a value of 2σ (%) when the standard deviation is denoted by σ. In Tables 1 to 3, the protrusion density ( 1 ) is the density of the protrusions at a freely selectable location in an area 1 mm wide from the boundary area adjacent to the data write zone, and the protrusion density ( 2 ) is the density of the protrusions on one freely selectable location in an area with a width in the radial direction of 1 mm in relation to the innermost circumference of the CSS zone.

Table 1

Table 2

Table 3

Table 4

In example 1 is because the magnetic head at Seeks to perform a CSS operation on the bottom of the Magnetic head in contact with the inclined surface of Projections in a radial section between 21 and 20 mm and at a protrusion height of 6 to 15 nm, and moves in this state towards the higher section of the Height of the protrusions. The initial landing section points a high protrusion density and sufficient Abrasion resistance even if the magnetic head is a Performs sliding movement at high speed. Since the Gradient the height of the protrusions is sufficiently small even with the initial contact with the magnetic head Crash caused.

The static friction and the friction force after 20 000 cycles Example 1 are values in the range in which the Magnetic head finally stops, i.e. in a range of 19 to 18 mm in the radial direction, and the search speed of the Magnetic head in the CSS zone was set as 1 mm / sec in  Radial direction. In contrast, in the CSS zone of the Comparative Example 1 no gradient in the height of the protrusions is present and the height of the protrusions is greater than that Flying height of the magnetic head in the data write-in zone a head crash after several cycles of the CSS operation evoked. In the CSS zone in Comparative Example 2 became none after the search of the magnetic head Head crash caused because the height of the protrusions is low is, however, ate up after repeating the CSS operation or when stopping the magnetic head this firmly, and could the magnetic head stops moving.

Claims (21)

1. Magnetic disk for performing data writing / reading by a system with contact at start and stop, which has a data zone for writing / reading data and a zone with contact at start and stop, which has a take-off / landing area and a stop area , for an operation with contact when starting and stopping a magnetic head,
where there are a plurality of protrusions in the start and stop contact zone, the height of the protrusions in the take-off / landing area decreases from the center of the magnetic disk towards the data write-in zone in the radial direction, an average gradient of the height of the projections in the take-off / landing area 1 × 10 ^-6 to 5 × 10 ^-5 , the maximum height of the protrusions in the contact zone at start and stop is higher than the flying height of the magnetic head in the data zone, and the minimum height of the protrusions in the contact zone at start and stop is less than the flying height of the magnetic head in the data zone. 2. Magnetic plate according to claim 1, characterized in that the average height of a circle in Circumferential direction in the zone with contact at start and Stop existing protrusions is between 1 and 60 nm, the protrusion density between 10 and 108 N / mm², and one average area of a figure by a circumference at a height of 1 nm below the top of each of the Protrusions are surrounded, is not larger than 1 µm².   3. Magnetic plate according to claim 1, characterized in that the projections by scanning with a Energy beam are formed, and a Vertical cross-sectional shape of a plane through the Center of the projection goes, and in which the The scanning direction of the energy beam is one Indentation on one side at the bottom of the projection having. 4. Magnetic disk according to claim 1, characterized in that the average gradient of the height of the projections in the take-off / landing area is 5 × 10 ^-6 to 2 × 10 ^-5 . 5. Magnetic plate according to claim 1, characterized in that a value of 2σ is within 15% if a Standard deviation value of σ for the height of the Projections apply in a freely selectable area Radial direction with a width of 50 µm on the Magnetic plate are present. 6. Magnetic plate according to claim 1, characterized in that the protrusion density in the take off / landing area of the Magnetic head is higher than the projection density in the Stop area for the magnetic head. 7. Magnetic plate according to claim 1, characterized in that the average gradient of the height of the protrusions in the Stop area equal to the average gradient of the height the protrusions in the take off / landing area, and that the slope of the height of the protrusions in the Stop area and in the take off / landing area is steady.   8. Magnetic plate according to claim 1, characterized in that the height of the protrusions in the stop area at the maximum height of the protrusions in the take-off / landing area just runs. 9. Magnetic plate according to claim 1, characterized in that a ratio of the protrusion density at one free selectable location in an area with a width of 1 mm compared to the data registration zone in the zone with Contact at start and stop in radial direction to the Projection density in a freely selectable location in one Area with a width of 1 mm on the inside opposite the location of the zone with contact at the start and Stop that radially closest to the center of the Magnetic disk is larger than 1 and not larger than 100 is. 10. Method for performing data writing / reading by a system with contact at start and stop with the following steps:
Using a magnetic disk having a data zone for writing / reading out data and a zone with contact at start and stop, which has a take-off / landing area and a stop area, for an operation with contact at start and stop of a magnetic head,
where there are a plurality of protrusions in the start and stop contact zone, the height of the protrusions in the take-off / landing area decreases radially from the center of the magnetic disk towards the data write-in zone, an average gradient of the height of the projections in the take-off / landing area Is 1 × 10 ^-6 to 5 × 10 ^-5 , the maximum height of the protrusions in the zone with contact at start and stop is greater than the flying height of the magnetic head, and the minimum height of the protrusions in the zone with contact at start and stop is lower than the flying height of the magnetic head,
Performing a search by contacting the head and reducing / increasing the speed of the disk on the inclined projections, and
Performing a record / read operation in which the magnetic head flies or hovers at a height less than the maximum height of the protrusions. 11. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which the middle Height of the protrusions on a circle in Circumferential direction in the zone with contact at start and Stop are present that is between 1 and 60 nm Projection density is between 10 and 108 N / mm², and a mean area of a figure that of a Borderline at a height of 1 nm below the tip each of the protrusions is surrounded, not more than 1 µm² is. 12. Procedure for writing data in / out Claim 10, characterized in that a Magnetic plate is used in which the projections formed by scanning with an energy beam  and a vertical cross-sectional shape of a plane that goes through the center of a ledge, and in which the scanning direction of the energy beam is one Indentation on one side at the bottom of the protrusion having. 13. A method for writing / reading data according to claim 10, characterized in that a magnetic disk is used, in which the mean gradient of the height of the projections in the take-off / landing area is 5 × 10 ^-6 to 2 × 10 ^-5 . 14. Procedure for writing data in / out Claim 10, characterized in that a Magnetic plate is used in which a value for 2σ is within 15% if a standard deviation σ the height of the protrusions is present in a free selectable radial area with a width of 50 µm the magnetic disk are present. 15. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which the Projection density in the take off / landing area for the Magnetic head is larger than the projection density in the Stop area for the magnetic head. 16. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which the middle Gradient of the height of the protrusions in the stop area equal to the average gradient of the height of the protrusions is in the take-off / landing area, and the slope  the height of the protrusions in the stop area and the Take off / landing area is steady. 17. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which the height of the Protrusions in the stop area at the maximum height the protrusions in the take-off / landing area are flat. 18. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which a ratio the projection density at a freely selectable location in an area 1 mm wide from the Data registration zone in the zone with contact at start and stop in the radial direction to the projection density a freely selectable location in an area with a Width of 1 mm on the inside of the closest to Radial center of the magnetic disk Location of the zone with contact at start and stop more than 1 and not more than 100. 19. Procedure for writing data in / out Claim 10, characterized in that a Magnetic disk is used, in which a ratio the projection density at a freely selectable location in an area 1 mm wide from the Data registration zone in the zone with contact at start and stop in the radial direction to the projection density a freely selectable location in an area with a Width of 1 mm on the inside of the closest in Radial direction at the center of the magnetic disk  Location of the zone with contact at start and stop larger than 1 and not greater than 100. 20. Procedure for writing data in / out Claim 10, characterized in that the stationary Stopping the magnetic disk the magnetic head into one higher section of the height of the protrusions Reduction of the speed during the search process is moved, and that the rotation of the magnetic disk the final, fixed position of the magnetic head is stopped. 21. Procedure for writing data in / out Claim 10, characterized in that the ratio the height for the stop area of the magnetic head in the Zone with contact at start and stop at the altitude of the Magnetic head in the data write zone greater than 1 and is not greater than 100.