Jump to main content
Jump to site search

Volume 186, 2016
Previous Article Next Article

Designing disordered materials using DNA-coated colloids of bacteriophage fd and gold

Author affiliations

Abstract

DNA has emerged as an exciting binding agent for programmable colloidal self-assembly. Its popularity derives from its unique properties: it provides highly specific short-ranged interactions and at the same time it acts as a steric stabilizer against non-specific van der Waals and Coulomb interactions. Because complementary DNA strands are linked only via hydrogen bonds, DNA-mediated binding is thermally reversible: it provides an effective attraction that can be switched off by raising the temperature only by a few degrees. In this article we introduce a new binary system made of DNA-functionalized filamentous fd viruses of ∼880 nm length with an aspect ratio of ∼100, and 50 nm gold nanoparticles (gold NPs) coated with the complementary DNA strands. When quenching mixtures below the melt temperature Tm, at which the attraction is switched on, we observe aggregation. Conversely, above Tm the system melts into a homogenous particulate ‘gas’. We present the aggregation behavior of three different gold NP to virus ratios and compare them to a gel made solely of gold NPs. In particular, we have investigated the aggregate structures as a function of cooling rate and determine how they evolve as function of time for given quench depths, employing fluorescence microscopy. Structural information was extracted in the form of an effective structure factor and chord length distributions. Rapid cooling rates lead to open aggregates, while slower controlled cooling rates closer to equilibrium DNA hybridization lead to more fine-stranded gels. Despite the different structures we find that for both cooling rates the quench into the two-phase region leads to initial spinodal decomposition, which becomes arrested. Surprisingly, although the fine-stranded gel is disordered, the overall structure and the corresponding length scale distributions in the system are remarkably reproducible. Such highly porous systems can be developed into new functional materials.

Back to tab navigation

Supplementary files

Publication details

The article was received on 17 Aug 2015, accepted on 01 Oct 2015 and first published on 01 Oct 2015


Article type: Paper
DOI: 10.1039/C5FD00120J
Author version available: Download Author version (PDF)
Citation: Faraday Discuss., 2016,186, 473-488
  •   Request permissions

    Designing disordered materials using DNA-coated colloids of bacteriophage fd and gold

    Z. Ruff, S. H. Nathan, R. R. Unwin, M. Zupkauskas, D. Joshi, G. P. C. Salmond, C. P. Grey and E. Eiser, Faraday Discuss., 2016, 186, 473
    DOI: 10.1039/C5FD00120J

Search articles by author

Spotlight

Advertisements