Effect of humidity on the interactions between probes and ultra-thin liquid lubricant films in an environmentally controlled atomic force microscope

Tagawa, Norio; Hatakeyama, Jun-ichi; Mori, Atsunobu

doi:10.1007/s00542-009-0857-7

Cited by 3 publications

(3 citation statements)

References 12 publications

(9 reference statements)

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“…The magnitudes of the pull-in and pull-out forces are rather similar between the baked and the unbaked Zdols, respectively, and range between 7-8 nN and 14-18 nN, respectively. The magnitude of the Zdol forces is consistent with other literature values [14,15]. The forces do not exhibit a strong tip loading rate dependence, Fig.…”

Section: Resultssupporting

confidence: 92%

Contact Hysteresis Between Two Surfaces Separated by a Zdol Boundary Layer

et al. 2013

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Section: Resultssupporting

confidence: 92%

Contact Hysteresis Between Two Surfaces Separated by a Zdol Boundary Layer

et al. 2013

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“…At low load rates, the pullout force for Zdol is approximately 15 nN (Table 2), approximately twice as large as limited data extant in the literature [30,31]. The pull-out force and the final rupture distances increase with increasing molecular polarity ( Fig.…”

Section: Unbaked Pfpesmentioning

confidence: 86%

AFM Force–Distance Curves for Perfluoropolyether Boundary Lubricant Films as a Function of Molecular Polarity

Waltman

Guo

2011

Tribol Lett

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AFM force-distance curves on 10-Å films of Zdol, Z-Tetraol, and ZTMD were investigated using a carbon-modified AFM tip. The forces were non-specific dominated by adhesive and/or capillary forces. The snap-to distances for unbaked Zdol, Z-Tetraol, and ZTMD were 1.9, 1.0, and 0.8 nm, respectively, and decreased with increasing molecular polarity. ZTMD allowed the closest approach before snap-to, by approximately 1 nm. However, annealed samples showed an identical 1.6 nm snap-to distance, indicating that an identical perfluoropolyether backbone was presented to the AFM tip at the PFPE/air interface. The pull-out forces for unbaked Zdol, Z-Tetraol, and ZTMD were in the 15-40 nN range and increased with increasing molecular polarity and loading rate. After annealing, the pull-out forces for the baked Zdol, Z-Tetraol, and ZTMD were significantly reduced to 10-20 nN, indicating that the polar end groups were less involved by bonding to the underlying surface. Force-distance curves for single-chain unbinding and entropic elasticity were computed to be near 300 and \100 pN, respectively, indicating that the force-distance curves for the experimental tip-PFPE interactions originated from multiple PFPE interactions with the tip.

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“…However, the numerically simulated FH drop is only about 0.1 nm. A sub-nanometerthick water-film covering the disk lubricant at high humidity is considered to influence the head-disk interaction and disk TDH (Tagawa et al 2010). The thickness was estimated to be about 0.3 nm at a relative humidity (RH) of 80% (Karis and Tawakkul 2003).…”

Section: Methods For Evaluating Clearancementioning

confidence: 99%

Humidity effect on head-disk clearance

Aoki

Takahashi

et al. 2011

Microsyst Technol

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The mechanism of head-disk-clearance change due to a humidity effect was investigated experimentally. The head-disk clearance was measured by moving the head elements towards the disk by thermal flying-height-control technology until the head touched the disk while monitoring them with an acoustic-emission sensor in an environmentally controlled component tester. Measured clearance change from 3% RH to 80% RH reached about -0.6 nm at 25°C and about -1.6 nm at 60°C. Head-disk clearance change caused by humidity was classified as the slider-flying-height change and disk-touch-down-height (TDH) change to clarify the mechanism of the clearance change. Slider FH change was dominated by absolute humidity rather than relative humidity. On the other hand, the humidity effect on disk TDH change was classified as a ''water-film effect'' and a ''lubricant-mogul effect'', which both depend on relative humidity. Both effects caused clearance change of about 0.4 nm for lubricant A, which is a lubricant with two hydroxyl functional groups at the end of the main chain. These effects were assumed to be caused by water adsorption onto the surface of lubricant. Reduction of the number of free hydroxyl groups which attract water molecules could suppress the disk TDH change related to the humidity effect.

show abstract

Effect of humidity on the interactions between probes and ultra-thin liquid lubricant films in an environmentally controlled atomic force microscope

Cited by 3 publications

References 12 publications

Contact Hysteresis Between Two Surfaces Separated by a Zdol Boundary Layer

Contact Hysteresis Between Two Surfaces Separated by a Zdol Boundary Layer

AFM Force–Distance Curves for Perfluoropolyether Boundary Lubricant Films as a Function of Molecular Polarity

Humidity effect on head-disk clearance

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