Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation
The technology of heat-assisted magnetic recording (HAMR) has improved the storage density of hard disc drives. The PFPE molecules of lubricant layer adhered on the disc can transfer from the lubricant layer and form the lubricant bridge which can deteriorate the stability of read/write process. In...
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sg-ntu-dr.10356-1424712020-06-22T08:16:45Z Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation Dai, Xiangyu Li, Hui Lei, Xiao Shen, Shengnan Wu, Shijing Liu, Sen Du, Hejun School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Lubricant Bridge Head-disc Interface The technology of heat-assisted magnetic recording (HAMR) has improved the storage density of hard disc drives. The PFPE molecules of lubricant layer adhered on the disc can transfer from the lubricant layer and form the lubricant bridge which can deteriorate the stability of read/write process. In this paper, the formation and breaking of lubricant bridge at the head–disc interface (HDI) affects HAMR stability and deserves to be investigated. Using molecular dynamic simulation, a full-atom model was built to evaluate the behaviour of the lubricant bridge. Moreover, the effects of lubricant temperature, heating-up time, disc rotation speed and bearing pressure on the HDI were studied. It has been found that the amount of transferring atoms sharply increased when the lubricant temperature was above 700 K. The loss rate of lubricant layer decreased gradually during the heating process and it took about 2.2 ns for the remaining lubricant to reach stability. Furthermore, transferring PFPE molecules can form the lubricant bridge. A shorter heating-up time makes the lubricant bridge thicker and more robust. And the duration of lubricant bridge is notably affected by heating-up time, rotation speed and bearing pressure. A shorter heating-up time leads to a longer duration of lubricant bridge, whereas a higher rotation speed and bearing pressure reduces the duration of lubricant bridge. 2020-06-22T08:16:45Z 2020-06-22T08:16:45Z 2017 Journal Article Dai, X., Li, H., Lei, X., Shen, S., Wu, S., Liu, S., & Du, H. (2018). Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation. Molecular Simulation, 44(2), 94-99. doi:10.1080/08927022.2017.1342124 0892-7022 https://hdl.handle.net/10356/142471 10.1080/08927022.2017.1342124 2-s2.0-85021155932 2 44 94 99 en Molecular Simulation © 2017 Informa UK Limited, trading as Taylor & Francis Group. All rights reserved. |
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Engineering::Mechanical engineering Lubricant Bridge Head-disc Interface Dai, Xiangyu Li, Hui Lei, Xiao Shen, Shengnan Wu, Shijing Liu, Sen Du, Hejun Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| description |
The technology of heat-assisted magnetic recording (HAMR) has improved the storage density of hard disc drives. The PFPE molecules of lubricant layer adhered on the disc can transfer from the lubricant layer and form the lubricant bridge which can deteriorate the stability of read/write process. In this paper, the formation and breaking of lubricant bridge at the head–disc interface (HDI) affects HAMR stability and deserves to be investigated. Using molecular dynamic simulation, a full-atom model was built to evaluate the behaviour of the lubricant bridge. Moreover, the effects of lubricant temperature, heating-up time, disc rotation speed and bearing pressure on the HDI were studied. It has been found that the amount of transferring atoms sharply increased when the lubricant temperature was above 700 K. The loss rate of lubricant layer decreased gradually during the heating process and it took about 2.2 ns for the remaining lubricant to reach stability. Furthermore, transferring PFPE molecules can form the lubricant bridge. A shorter heating-up time makes the lubricant bridge thicker and more robust. And the duration of lubricant bridge is notably affected by heating-up time, rotation speed and bearing pressure. A shorter heating-up time leads to a longer duration of lubricant bridge, whereas a higher rotation speed and bearing pressure reduces the duration of lubricant bridge. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Dai, Xiangyu Li, Hui Lei, Xiao Shen, Shengnan Wu, Shijing Liu, Sen Du, Hejun |
| format |
Article |
| author |
Dai, Xiangyu Li, Hui Lei, Xiao Shen, Shengnan Wu, Shijing Liu, Sen Du, Hejun |
| author_sort |
Dai, Xiangyu |
| title |
Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| title_short |
Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| title_full |
Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| title_fullStr |
Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| title_full_unstemmed |
Modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| title_sort |
modeling of formation and breaking of lubricant bridge in the head–disk interface by molecular dynamic simulation |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/142471 |
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1681059588213833728 |