The superparamagnetic effect poses a serious challenge for continuing to increase the areal density and storage capacity of disk drives. One of the most promising methods to circumvent the density limitations imposed by this is the use of patterned media. In conventional media, the magnetic recording layers is a thin film of magnetic alloy, which naturally forms a random mosaic of nanometer scale grains which behave as independent magnetic elements. Each recorded bit is made up of many of these random grains. In pattern and media, the magnetic layer is created as an ordered array of highly uniform islands, each island capable of storing an individual bit.
In conventional media, bit cells are fabricated on circular tracks on a disk. Each bit cell comprises many tiny magnetic grains. Each grain behaves like an independent magnet whose magnetization can be flipped by a write head during the data writing process. These grains are irregularly shaped and randomly oriented. If the grains are small relative to the size of the bit cell, the magnetic transitions are straight enough so that it is easy to detect the boundary between adjacent bit cells. Shrinking the bit cells to increase areal density, however, without shrinking the grain size makes the magnetic transitions harder to detect.
The traditional solution to this problem has been to shrink the grain size. However, there is a practical limit. The magnetization of very small grains is unstable. According to the superparamagnetic effect, the magnetization of a grain can flip spontaneously if the product of the grain volume and its anisotropy energy falls below a certain value. The result is a loss of data.
In patterned media, each bit is stored in a single deliberately formed magnetic switching volume. This may be one grain, or several exchange volume coupled grains, rather than a collection of random decoupled grains. Single switching volumes magnetic islands are formed along circular tracks with regular spacing. Magnetic transitions no longer meander between random grains but are distinct boundaries between precisely located islands.
An embodiment of the present invention provides a method comprising providing a pre-patterned substrate having an array of thick walls, depositing a conforming layer on the pre-patterned substrate, etching the conforming layer from the top of the thick walls and the space between the walls, and etching the thick walls while leaving thin walls of conforming layer.
Preferred embodiments of this invention is shown and described, simply by way of illustration of the best mode contemplated for carrying out this invention, in the following detailed description. As will be realized, this invention is capable of other and different embodiments, and its details are capable of modifications in various obvious respects, all without departing from this invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive.
a is a schematic illustration of a step in a method of fabricating thin walls for aligning diblock copolymers according to one aspect of the invention.
b is a schematic illustration of a step in a method of fabricating thin walls for aligning diblock copolymers according to one aspect of the invention.
c is a schematic illustration of a step in a method of fabricating thin walls for aligning diblock copolymers according to one aspect of the invention.
d is a schematic illustration of a step in a method of fabricating thin walls for aligning diblock copolymers according to one aspect of the invention.
a is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
b is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
c is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
d is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
e is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
f is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
g is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
h is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
i is a schematic illustration of a step in a method of fabricating a nano-stamper according to one aspect of the invention.
An embodiment of the present invention provides a method comprising providing a pre-patterned substrate having an array of thick walls, depositing a conforming layer on the pre-patterned substrate, etching the conforming layer from the top of the thick walls and the space between the walls, and etching the thick walls while leaving thin walls of conforming layer.
Another embodiment of the present invention includes a device comprising a substrate and an array of thin walls on the substrate, wherein the thin walls have a thickness of about 5 nm or less.
Another embodiment of the present invention includes a device comprising a substrate a pattern transfer layer on the substrate and an array of holes in the pattern transfer layer, wherein the holes are aligned with an array of regions lacking holes, and wherein the regions lacking holes have a thickness of about 5 nm or less.
a to 2d illustrate a method of fabricating thin walls for aligning diblock copolymers according to one aspect of the invention. In this embodiment, a pre-patterned substrate 200 comprising a substrate 210, a pattern transfer layer 220, an etch stop 230, and patterned thick walls 240 is provided (
A conforming layer 250 is deposited onto the pre-patterned substrate 200 (
In the next step (
In the final step of this embodiment of the invention, the patterned thick walls 240 are preferentially etched away. This results in an array of thin walls 260 of conforming layer material. Preferential etching may be performed by any suitable method, for example RIE. The thickness of the thin walls 260 is determined by the conforming film deposition process and may be extremely thin. Preferably, the thickness of the thin walls 260 may be approximately 5 nm or less. More preferably, the thickness of the thin walls 260 may be approximately 3 nm or less. Even more preferably, the thickness of the thin walls 260 may be approximately 1 nm or less.
In the next step, illustrated in
In the next step, illustrated in
In the last step, illustrated in
Another embodiment of the invention is illustrated in
In this embodiment of the invention, a pre-patterned substrate 300 is provided. Pre-patterned substrate 300 comprises a transparent substrate 210, an etch stop layer 230, and patterned thick walls 240. Preferably, the substrate is quartz, however any suitable transparent material may be used. Preferably, the etch stop layer comprises chromium, however any suitable metal or alloy material may be used. If the etch stop layer is made of chromium, preferably it is approximately 5 nm thick. The thickness of the etch stop layer, however, may vary depending on the material used.
A conforming layer 250 is deposited onto pre-patterned substrate 300 (
In the next step (
In the next step (
In the next step (
In the next step, illustrated in
In the next step, illustrated in
In the final step, the etch stop 230 is removed from the substrate 210. The result is a transparent nano-scale hard mask 330. The nano-scale hard mask 330 is suitable for use in nano-imprint lithography. It can, for example, be used in the method illustrated in
The implementations described above and other implementations are within the scope of the following claims.
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Number | Date | Country | |
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20100119778 A1 | May 2010 | US |