2004
DOI: 10.1103/physrevlett.93.026001
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Single-File Diffusion of Colloids in One-Dimensional Channels

Abstract: We study the diffusive behavior of colloidal particles which are confined to one-dimensional channels generated by scanning optical tweezers. At long times t, the mean-square displacement is found to scale as t 1=2 , which is expected for systems where single-file diffusion occurs. In addition, we experimentally obtain the long-time, self-diffusive behavior from the short-time collective density fluctuations of the system as suggested by a recent analytical approach [M. Kollmann, Phys. Rev. Lett. 90, 180602 (… Show more

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Cited by 258 publications
(228 citation statements)
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“…The temperature and interaction strength are such that Γ ranges as in experiments [9,15,16,24] and numerical simulations [26,27,32]. The interest of the simulations is to get acces to parameter values that are difficult or impossible to obtain experimentally.…”
Section: B Algorithmmentioning
confidence: 99%
See 3 more Smart Citations
“…The temperature and interaction strength are such that Γ ranges as in experiments [9,15,16,24] and numerical simulations [26,27,32]. The interest of the simulations is to get acces to parameter values that are difficult or impossible to obtain experimentally.…”
Section: B Algorithmmentioning
confidence: 99%
“…4-a) and Fig. 4-b)], being replaced by a Dt scaling with D given by (16), and the collective regime begins by a t 2 evolution [see III C and (17)]. The time τ coll may thus be estimated by…”
Section: Crossover Timesmentioning
confidence: 99%
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“…Many-particle systems may exhibit some features not found in the single-particle counterparts, such as phase transitions, spontaneous ratchet effects, and negative mobility [9][10][11][12][13][14]. The interacting Brownian ratchets been proposed for a variety of applications, including molecular motors [2], friction [16], diffusion of dimers on surfaces [17], diffusion of colloidal particles [18], DNA translocation through a nanopore [19], charge density waves [20], and arrays of Josephson junctions [21].…”
mentioning
confidence: 99%