Improvement of shock resistance for solid immersion lens-based near field recording system using air-bearing surface

Yonghyun Lee; Yong Eun Lee; Sang Jik Lee; Ki Hoon Kim; Seokhwan Kim; No Cheol Park; Young Pil Park; Kyoung Su Park

doi:10.1143/JJAP.49.08KC05

Improvement of shock resistance for solid immersion lens-based near field recording system using air-bearing surface

Yonghyun Lee, Yong Eun Lee, Sang Jik Lee, Ki Hoon Kim, Seokhwan Kim, No Cheol Park, Young Pil Park, Kyoung Su Park

Department of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

A solid immersion lens (SIL)-based near-field recording (NFR) device is regarded as the next-generation optical storage device that can achieve an areal density of more than 100 Gbyte/in. ². However, the NFR system is very weak to external shock because of the extremely small gap between the SIL and the disc. To solve this problem, we proposed a new method of using an air-bearing surface (ABS) to avoid collision between the SIL and the disc, and investigated the effect of the ABS on shock resistance in our previous study. In our current study, we optimize an initial ABS model using the results of our previous study and achieve an optimal ABS model with an improved shock resistance. We also verify the improvement of shock resistance for the optimal ABS model by finite element (FE) analysis, by applying the ABS model to a gap servo control system, and by experimental shock testing.

Original language	English
Article number	08KC05
Journal	Japanese journal of applied physics
Volume	49
Issue number	8 PART 3
DOIs	https://doi.org/10.1143/JJAP.49.08KC05
Publication status	Published - 2010 Aug

All Science Journal Classification (ASJC) codes

Engineering(all)
Physics and Astronomy(all)

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10.1143/JJAP.49.08KC05

Cite this

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title = "Improvement of shock resistance for solid immersion lens-based near field recording system using air-bearing surface",

abstract = "A solid immersion lens (SIL)-based near-field recording (NFR) device is regarded as the next-generation optical storage device that can achieve an areal density of more than 100 Gbyte/in. 2. However, the NFR system is very weak to external shock because of the extremely small gap between the SIL and the disc. To solve this problem, we proposed a new method of using an air-bearing surface (ABS) to avoid collision between the SIL and the disc, and investigated the effect of the ABS on shock resistance in our previous study. In our current study, we optimize an initial ABS model using the results of our previous study and achieve an optimal ABS model with an improved shock resistance. We also verify the improvement of shock resistance for the optimal ABS model by finite element (FE) analysis, by applying the ABS model to a gap servo control system, and by experimental shock testing.",

author = "Yonghyun Lee and Lee, {Yong Eun} and Lee, {Sang Jik} and Kim, {Ki Hoon} and Seokhwan Kim and Park, {No Cheol} and Park, {Young Pil} and Park, {Kyoung Su}",

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AU - Lee, Yonghyun

AU - Lee, Yong Eun

AU - Lee, Sang Jik

AU - Kim, Ki Hoon

AU - Kim, Seokhwan

AU - Park, No Cheol

AU - Park, Young Pil

AU - Park, Kyoung Su

PY - 2010/8

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N2 - A solid immersion lens (SIL)-based near-field recording (NFR) device is regarded as the next-generation optical storage device that can achieve an areal density of more than 100 Gbyte/in. 2. However, the NFR system is very weak to external shock because of the extremely small gap between the SIL and the disc. To solve this problem, we proposed a new method of using an air-bearing surface (ABS) to avoid collision between the SIL and the disc, and investigated the effect of the ABS on shock resistance in our previous study. In our current study, we optimize an initial ABS model using the results of our previous study and achieve an optimal ABS model with an improved shock resistance. We also verify the improvement of shock resistance for the optimal ABS model by finite element (FE) analysis, by applying the ABS model to a gap servo control system, and by experimental shock testing.

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Improvement of shock resistance for solid immersion lens-based near field recording system using air-bearing surface

Abstract

All Science Journal Classification (ASJC) codes

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