G W Slater
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Explore the profile of G W Slater including associated specialties, affiliations and a list of published articles.
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Articles
53
Citations
238
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Recent Articles
1.
Wang H, Slater G
J Chem Phys
. 2024 May;
160(19).
PMID: 38747436
Even though dilute (unentangled) polymer solutions cannot act as gel-like sieving media, it has been shown that they can be used to separate DNA molecules in capillary electrophoresis. The separation...
2.
Bohemier C, Ignacio M, Lamy X, Slater G
Int J Pharm
. 2023 Feb;
634:122674.
PMID: 36736966
Drug release experiments and numerical simulations only give access to partial release data (i.e., within a finite time range t∈[0,t]). In this article, we propose fitting-based procedures to estimate the...
3.
Ignacio M, Bagheri M, Chubynsky M, de Haan H, Slater G
Phys Rev E
. 2022 Jul;
105(6-1):064135.
PMID: 35854606
Lattice Monte Carlo (LMC) simulations are widely used to investigate diffusion-controlled problems such as drug-release systems. The presence of an inhomogeneous diffusivity environment raises subtle questions about the interpretation of...
4.
Shendruk T, Slater G
J Chromatogr A
. 2014 Mar;
1339:219-23.
PMID: 24674643
Hydrodynamic chromatography (HC) and field-flow fractionation (FFF) separation methods are often performed in 3D rectangular channels, though ideal retention theory assumes 2D systems. Devices are commonly designed with large aspect...
5.
Slater G, Shendruk T
J Chromatogr A
. 2012 Aug;
1256:206-12.
PMID: 22885044
One way to potentially modify the performance of field-flow fractionation (FFF) would be to move the position of the maximum flow velocity away from the mid-point of the channel, for...
6.
Shendruk T, Slater G
J Chromatogr A
. 2012 Mar;
1233:100-8.
PMID: 22381891
Through a careful consideration of the retention ratio for field-flow fractionation (FFF), we show that a single unified ideal retention theory can predict a wide range of separation behaviours including...
7.
Gauthier M, Slater G
Eur Phys J E Soft Matter
. 2008 Feb;
25(1):17-23.
PMID: 18236003
The detection of linear polymers translocating through a nanoscopic pore is a promising idea for the development of new DNA analysis techniques. However, the physics of constrained macromolecules and the...
8.
Bertrand M, Slater G
Eur Phys J E Soft Matter
. 2007 May;
23(1):83-9.
PMID: 17534575
For a polyelectrolyte undergoing electrophoretic motion, it is predicted (D. Long, J.L. Viovy, A. Ajdari, Phys. Rev. Lett. 76, 3858 (1996); D. Long, A. Ajdari, Electrophoresis 17, 1161 (1996)) that...
9.
Nedelcu S, Meagher R, Barron A, Slater G
J Chem Phys
. 2007 May;
126(17):175104.
PMID: 17492889
The conjugation of an uncharged polymer to DNA fragments makes it possible to separate DNA by free-solution electrophoresis. This end-labeled free-solution electrophoresis method has been shown to successfully separate ssDNA...
10.
Kenward M, Slater G
Eur Phys J E Soft Matter
. 2006 Jun;
20(2):125-41.
PMID: 16779525
We present a study of the dynamics of single polymers colliding with molecular obstacles using Molecular-dynamics simulations. In concert with these simulations we present a generalized polymer-obstacle collision model which...