KR100469246B1 - optical recording slider - Google Patents

Abstract

According to the present invention, the optical recording pickup has a slider which allows the head portion including the condenser lens to float by rotation of the optical recording disk, and is in the form of a powder in which the slider component is sintered, thereby making it possible to obtain a very small amount of powder particles. It creates voids of size (volumes), and when these discs are filled with liquid lubricant, they are not exposed to the surface of the slider that goes to the optical recording disc when the disc is not rotating. Being present has the effect of minimizing exposure to contamination.

Description

Optical recording slider

The present invention relates to an optical recording method capable of recording and reproducing information using a laser light source, and more particularly, to an optical pick-up slider used for recording and reproducing information using a near field of light.

With the advent of the information age, the development of information storage systems is also rapidly developing.

In recent years, with the advent of digital broadcasting, high-definition TV (HD-TV), and mobile application consumer products, the demand for high-density and reliable optical recording methods and systems for information recording has recently emerged. For example, the trend is growing.

In order to achieve such a high density, a conventional approach has been to use a laser diode (LD) having a short wavelength of a light source or a numerical aperture (NA) of an objective lens located at the bottom of an optical pickup. Increasing the size of the beam to minimize the size of the beam at the focal point.

However, these methods belong to the domain of diffraction optics, and it is impossible to improve the recording density beyond the diffraction limit.

In order to overcome the limit recording density in the diffraction optical domain, a new concept of the proposed technique has been proposed. The main contents are summarized as follows.

First, near-field optical recording using near-field optics

Secondly, planar aperture array type smaller than optical fiber or diffraction limit

Third, SIL (Solid Immersion Lens)

Fourth, an optical flying head that performs vertical servo by a flying type used in a magnetic thin film hard-disk drive (HDD).

Among them, SIL is attached to the optical flying head so that information can be read and reproduced while floating at a height (tens of nanometers) very close to the surface of the media to increase density and speed simultaneously. Has received great attention.

However, there are some key technical challenges that must be addressed before this approach can be put to practical use.

First, in order to overcome the existing diffraction limit using near field optics, a small beam waist below the diffraction limit due to the near field must be created, and the small beam below this diffraction limit can be recorded or recorded. You must bring it to the location.

However, one difficulty here is that the exponential function decreases the intensity and the size of the beam as it moves away from the light source (lower lens or optical fiber tip) due to the nature of the near field beam. There is a growing problem.

Therefore, in order to take advantage of the near field light formed, the distance between the light source (such as an optical pickup including a lens) and the medium (exactly the information recording layer of the medium) must be kept very close (tens of nanometers).

This causes the media and the lens to be close enough to physical contact with each other by self-vibration or external forces, causing a crash (lens crash, similar to a head-crash on an HDD).

So in order to minimize the possible tragedy, the surface of the medium has a structure coated with a protective film (eg, Diamond-Like Carbon (DLC)) and a lubricant film.

Eventually, in order to overcome the diffraction limit, the near field of light must be used, but the collision between the lens and the medium is maintained by keeping the flying height low to keep the intensity and beam size small, which are the properties of the near field. This happens.

Secondly, in order to control the environment in which information is recorded and reproduced from contaminants (dust, heads or debris away from the surface of the media), the magnetic hard disk drive (HDD), which is sealed from the outside, is controlled. In contrast, in the optical recording method, there is a problem in that the recording and reproducing areas must be exposed in the air in order to make use of the removability of inserting and removing the media from the drive.

At this time, it can be put in the cartridge to prevent fingerprints or dust on the surface of the media while handling the media, but there are many sources of contamination including dust of various sizes, so it is very likely to be exposed to contamination. high.

In particular, the lubricant layer covering the surface of the medium exists in a low-viscosity liquid phase in order to minimize the side effects caused by lens collision, which is like a gum when the dust comes close to the surface of the medium. It has the effect of scraping off the media surface.

As a result, the surface roughness of the medium is changed, and as the intensity of the power from the light source of the optical pickup passes through this contaminant layer, the reduced power reaches the recording layer so that the size of the recorded mark becomes smaller and jitter. It causes an increase.

In particular, jitter tolerance in high density information storage media is very tight, making it difficult to meet the specification of the Bit Error Rate (BER).

In the end, a lubricant layer should be used to reduce the specific polarity during lens collisions, but the presence of this layer usually causes the adverse effect of scraping dust.

Third, when light energy as a light source propagates through the medium, part of the light energy is converted into thermal energy because the absorption coefficient k of the material placed in the path is not zero, resulting in low melting point. Part of the lubricating oil is vaporized by laser radiation to cover the surface of the lens, so that there is a problem that contaminants such as dust accumulate later on the lens surface.

This problem must be solved by causing additional problems in succession once occurring.

Accordingly, the present invention has been made to solve the above problems, using near-field optics to implement ultra-high density optical recording by overcoming the diffraction limit for determining the critical recording density in the diffraction optical domain. It is an object to provide a near-field optical recording apparatus.

1 is a side view of a slider of a floating optical recording system according to the present invention.

2A to 2C are enlarged views of the lower surface of the slider close to the disk surface in the floating recording slider for optical recording;

3 is a diagram showing the structure of an optical recording disc according to the present invention;

* Explanation of symbols for main parts of the drawings

10 optical disc 11 substrate

12: reflective layer 13, 15: dielectric layer

14: information recording layer 16: protective film

20: Slider 21: Slider Construct

22: microvoid 23: lubricant

30: optical record pickup

A feature of the optical recording slider according to the present invention for achieving the above object is an optical recording device having a flying head for recording information in such a way that the floating motion on the medium in accordance with the rotational movement of the optical recording medium, The flying head includes a slider member for allowing floating movement on the medium, wherein the slider member includes the member in which lubricant contained in the member is opposed to the surface of the medium by a Bernoulli effect by the rotational movement of the medium. It is configured to leak to the surface of the.

The slider member includes a sintering agent powder of alumina (Al ₂ O ₃ ) and titanium carbide (TiC), but the voids are formed between the powder particles constituting the member.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of the optical recording slider according to the present invention will be described below with reference to the accompanying drawings.

1 is a side view of a slider of a floating optical recording system according to the present invention.

1, an optical recording disk 10 in which information is recorded and reproduced by a laser light source, and a plurality of powders of different components are sintered adjacent to the optical recording disk 10 to be adjacent to each other. A slider 20 in which micropores are formed between contacted powder particles and an optical recording pickup 30 in which a condenser lens (not shown) is integrally formed.

As shown in FIG. 3, the optical recording disk 10 includes a reflective layer 12, a first dielectric layer 13, an information recording layer 14, a second dielectric layer 14, and a protective film 16 on a substrate 11. ) And the optical recording pickup 30 is slanted at less than 1 to 5 ° so that the header portion including the condenser lens may float due to the rotation of the optical recording disk 10. Forming.

The condenser lens (not shown) is composed of SIL (Solid Immersion Lens), and the height of the lower end of the condenser lens is formed at a predetermined height or higher than the height of the lower end of the slider 20.

2a to 2c are schematic views showing an enlarged surface of the lower end of the slider close to the disk surface in the floating recording slider for optical recording. As shown in FIG. 2a, the slider 20 is powdered alumina (Al ₂ O ₃ ) and titanium. Microvoids 22 exist between the slider structure 21 formed of carbide (TiC) and the powder body which is each slider structure 21.

As shown in FIG. 2B, the slider 20 injects the liquid lubricant 23 into the micropores 22 formed by alumina (Al ₂ O ₃ ) and titanium carbide (TiC) in powder form.

This is because the optical recording disc 10 does not expose the lubricant 23 to the surface of the slider 20 when the optical recording disc 10 does not rotate, that is, when information is not read or written, as shown in FIG. 2B. When the rotation is started, that is, reading or writing information, the lubricant 23 is exposed to the surface of the slider 20 by the effect of Bernoulli as shown in FIG. 2C.

Accordingly, the side of the optical recording disk 30 and the optical recording disk 10 due to the vibration of the disk generated during the high-speed rotation of the optical recording disk 10 to minimize the side effects and at the same time, the optical recording disk The influence of the surface contamination degree by the lubricant 23 formed on the surface at the time of the stop of 10 can be reduced.

The driving operation of the optical recording slider according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, the optical recording pickup 30 constitutes a slider 20 so that the head portion formed integrally with the condenser lens (eg, SIL) can float by the rotation of the optical recording disk 10.

At this time, the head portion is formed by tilting the head portion to less than 1 ~ 5 ° to rise.

When the slider 20 sinters alumina (Al ₂ O ₃ ) and titanium carbide (TiC) 21 in powder form, the process is completed after the neck-growth is completed. Thus, very small voids 22 exist between the powder particles that are in close contact with each other, as shown in FIG. 2A.

The liquid lubricant is sucked into the micro voids 22 formed in the slider 20 formed in this way by a capillary phenomenon, or the lubricant is introduced into the slider body by introducing the lubricant in a vacuum.

Accordingly, when the optical recording disk 10 rotates, the lubricant 23 flows out by itself to form the lubricating layer 24 as shown in FIG. 2C by the Bernoulli effect, and the rotation of the optical recording disk stops. As shown in FIG. 2B, the lubrication layer 24 disappears again into the air gap 22.

In more detail, the lubricant 23 is exposed to the surface of the slider 20 that faces the optical recording disk 10 when the optical recording disk 10 is not rotating, i.e. when not reading or writing information. When the optical recording disk 10 rotates, Bernoulli's effect is that the flow velocity is faster than other parts at the interface between the head portion and the optical recording disk 10, and the pressure here is lower than the pressure in other places. Will be generated.

The lubricating oil 23 flows out of the surface of the slider 20 by the Bernoulli effect, thereby forming the lubricating layer 24.

In addition, when the rotation of the optical recording disk 10 is stopped, the lubricating oil 23 on the surface of the slider 20 flows back into the microcavity 22 again.

As a result, when not in use, the liquid lubricant 23 does not exist on the surface of the slider 20, and when it is in use, that is, when the contact between the head portion and the optical recording disk 10 is expected, the lubricant is applied to the surface of the slider 20. By (23) coming out to form the lubrication layer 24, the lubricating oil 23 can be minimized the time to be exposed to contamination due to ambient dust or the like.

In addition, even when the dust touches the electrically conductive DLC, which is the protective film 16, the static electricity in the dust flows into the DLC protective film, thereby easily falling off the optical recording disk 10.

Then, the height of the lower end of the condensing lens formed integrally with the slider 20 is configured to be equal to or higher than the height of the lower end of the slider 20, so that the lubrication layer 24 is in contact with the head portion and the optical recording disk 10. Is present between the head portion and the optical recording disk 10, but the situation where the lubricating material covers the surface of the light condensing lens is prevented.

Accordingly, when light energy as a light source propagates through the optical recording disk 10, the absorption coefficient k of the material lying on the path of the laser light is not zero due to the lubrication layer 24. Part of the light energy is converted into thermal energy, and as a result, a part of the lubricating layer 24 having a low melting point is vaporized by irradiation of laser light to cover the surface of the condenser lens.

Afterwards, dust or vaporized materials accumulate on the surface of the light collecting lens, which is solved by preventing the lubrication layer 24 from being present when the light source passes through the optical recording disk 10.

As described above, the optical recording disk 10 according to the present invention has a high hardness at the top layer, which has the advantage of the optical recording disk compared with the conventional disk, and has a low coefficient of friction and low electrical conductivity. Lubricating layer, which has been pointed out as a major disadvantage, while maintaining the DLC (Diamond-Like Carbon) protective film 16 which has excellent electrical conductivity, and is optically transparent and chemically inert. The lubricant layer 24 has a structure that does not exist.

The optical recording slider according to the present invention as described above has the following effects.

First, due to self-vibration generated by high-speed rotation in the optical recording disk through the adjustment of the lubrication layer formation, it is necessary to expose the recording and reproducing areas to the air. By simultaneously solving the problem, the distance between the light source and the information recording layer can be kept very close.

Second, when light energy, a light source, propagates through the medium, the problem of being accumulated by vaporization of the lubricating layer on the surface of the lens is solved.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (3)

An optical recording apparatus having a flying head for recording information in such a manner as to float on the medium in accordance with a rotational movement of an optical recording medium. The flying head includes a slider member that enables floating motion on the medium, wherein the slider member is formed by the Bernoulli effect of the liquid lubricant contained in the void formed in the member by the rotational motion of the medium. And an optical recording slider structure configured to leak to an opposing surface of the member. The method of claim 1, wherein the slider member At least one void formed by a neck-growth between the powder particles constituting the slider member, including a sintering agent powder of alumina (Al ₂ O ₃ ) and titanium carbide (TiC). And a liquid lubricant is added to the formed voids. 2. The lubricant of claim 1 wherein the lubricant contained in the slider member And the inside of the member when there is no rotational motion of the medium.