Templated electrokinetic directed chemical assembly for the fabrication of close-packed plasmonic metamolecules

Colloidal self-assembly combined with templated surfaces holds the promise of fabricating large area devices in a low cost facile manner. This directed assembly approach improves the complexity of assemblies that can be achieved with self-assembly while maintaining advantages of molecular scale control. In this work, electrokinetic driving forces, i.e., electrohydrodynamic flow, are paired with chemical crosslinking between colloidal particles to form close-packed plasmonic metamolecules. This method addresses challenges of obtaining uniformity in nanostructure geometry and nanometer scale gap spacings in structures. Electrohydrodynamic flows yield robust driving forces between the template and nanoparticles as well as between nanoparticles on the surface promoting the assembly of close-packed metamolecules. Here, electron beam lithography defined Au pillars are used as seed structures that generate electrohydrodynamic flows. Chemical crosslinking between Au surfaces enables molecular control over gap spacings between nanoparticles and Au pillars. An as-fabricated structure is analyzed via full wave electromagnetic simulations and shown to produce large magnetic field enhancements on the order of 3.5 at optical frequencies. This novel method for directed self-assembly demonstrates the synergy between colloidal driving forces and chemical crosslinking for the fabrication of plasmonic metamolecules with unique electromagnetic properties.

[1]  Yang Li,et al.  Manipulating magnetic plasmon propagation in metallic nanocluster networks. , 2012, ACS nano.

[2]  M. Veysi,et al.  Optical nanoantennas as magnetic nanoprobes for enhancing light-matter interaction , 2016, 2016 10th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (METAMATERIALS).

[3]  George T. Wang,et al.  Giant field enhancement in longitudinal epsilon-near-zero films , 2017, 1701.08870.

[4]  Filippo Capolino,et al.  Electric field enhancement with plasmonic colloidal nanoantennas excited by a silicon nitride waveguide. , 2016, Optics express.

[5]  Filippo Capolino,et al.  Surface enhanced Raman scattering for detection of Pseudomonas aeruginosa quorum sensing compounds , 2015, SPIE NanoScience + Engineering.

[6]  Lukas Novotny,et al.  Excitation of magnetic dipole transitions at optical frequencies. , 2015, Physical review letters.

[7]  F. Capolino,et al.  Bridging the Gap between Crosslinking Chemistry and Directed Assembly of Metasurfaces Using Electrohydrodynamic Flow , 2016, 1609.06964.

[8]  R. Ragan,et al.  Design of a versatile chemical assembly method for patterning colloidal nanoparticles , 2009, Nanotechnology.

[9]  M. Wegener,et al.  Single-slit split-ring resonators at optical frequencies: limits of size scaling. , 2006, Optics letters.

[10]  M. Bohmer In Situ Observation of 2-Dimensional Clustering during Electrophoretic Deposition , 1996 .

[11]  Cherie R. Kagan,et al.  Plasmon Resonances in Self-Assembled Two-Dimensional Au Nanocrystal Metamolecules. , 2017, ACS nano.

[12]  F. Capolino,et al.  Enhanced Magnetic and Electric Fields via Fano Resonances in Metasurfaces of Circular Clusters of Plasmonic Nanoparticles , 2014 .

[13]  S. Xiao,et al.  Different EDC/NHS activation mechanisms between PAA and PMAA brushes and the following amidation reactions. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[14]  Yu Zhang,et al.  Coherent Fano resonances in a plasmonic nanocluster enhance optical four-wave mixing , 2013, Proceedings of the National Academy of Sciences.

[15]  A Leinse,et al.  Probing the Magnetic Field of Light at Optical Frequencies , 2009, Science.

[16]  A. Ajdari,et al.  Electrically induced interactions between colloidal particles in the vicinity of a conducting plane. , 2002, Physical review. E, Statistical, nonlinear, and soft matter physics.

[17]  F. Capolino,et al.  Magnetic Nanoantennas Made of Plasmonic Nanoclusters for Photoinduced Magnetic Field Enhancement , 2017 .

[18]  F. Capolino,et al.  Non-lithographic SERS substrates: tailoring surface chemistry for Au nanoparticle cluster assembly. , 2012, Small.

[19]  Neus G Bastús,et al.  Kinetically controlled seeded growth synthesis of citrate-stabilized gold nanoparticles of up to 200 nm: size focusing versus Ostwald ripening. , 2011, Langmuir : the ACS journal of surfaces and colloids.

[20]  M. Veysi,et al.  Artificial magnetism via nanoantennas under azimuthally polarized vector beam illumination , 2016, 2016 Conference on Lasers and Electro-Optics (CLEO).