Directing fluorescence with plasmonic and photonic structures.

Fluorescence technology pervades all areas of chemical and biological sciences. In recent years, it is being realized that traditional fluorescence can be enriched in many ways by harnessing the power of plasmonic or photonic structures that have remarkable abilities to mold the flow of optical energy. Conventional fluorescence is omnidirectional in nature, which makes it difficult to capture the entire emission. Suitably designed emission directivity can improve collection efficiency and is desirable for many fluorescence-based applications like sensing, imaging, single molecule spectroscopy, and optical communication. By incorporating fluorophores in plasmonic or photonic substrates, it is possible to tailor the optical environment surrounding the fluorophores and to modify the spatial distribution of emission. This promising approach works on the principle of near-field interaction of fluorescence with spectrally overlapping optical modes present in the substrates. In this Account, we present our studies on directional emission with different kinds of planar metallic, dielectric, and hybrid structures. In metal-dielectric substrates, the coupling of fluorescence with surface plasmons leads to directional surface-plasmon-coupled emission with characteristic dispersion and polarization properties. In one-dimensional photonic crystals (1DPC), fluorophores can interact with Bloch surface waves, giving rise to sharply directional Bloch surface wave-coupled emission. The interaction of fluorescence with Fabry-Pérot-like modes in metal-dielectric-metal substrates and with Tamm states in plasmonic-photonic hybrid substrates provides beaming emission normal to the substrate surface. These interesting features are explained in the context of reflectivity dispersion diagrams, which provide a complete picture of the mode profiles and the corresponding coupled emission patterns. Other than planar substrates, specially fabricated plasmonic nanoantennas also have tremendous potential in controlling and steering fluorescence beams. Some representative studies by other research groups with various nanoantenna structures are described. While there are complexities to near-field interactions of fluorescence with plasmonic and photonic structures, there are also many exciting possibilities. The routing of each emission wavelength along a specific direction with a given angular width and polarization will allow spatial and spectral multiplexing. Directional emission close to surface normal will be particularly useful for microscopy and array-based studies. Application-specific angular emission patterns can be obtained by varying the design parameters of the plasmonic/photonic substrates in a flexible manner. We anticipate that the ability to control the flow of emitted light in the nanoscale will lead to the development of a new generation of fluorescence-based assays, instrumentation, portable diagnostics, and emissive devices.

[1]  Giorgio Volpe,et al.  Unidirectional Emission of a Quantum Dot Coupled to a Nanoantenna , 2010, Science.

[2]  J. Lakowicz,et al.  Directional Emission from Metal-Dielectric-Metal Structures: Effect of Mixed Metal Layers, Dye Location and Dielectric Thickness. , 2015, The journal of physical chemistry. C, Nanomaterials and interfaces.

[3]  G. Rao,et al.  High-resolution surface plasmon coupled resonant filter for monitoring of fluorescence emission from molecular multiplexes , 2009 .

[4]  Joseph R. Lakowicz Plasmon-controlled fluorescence: A new paradigm in fluorescence spectroscopy , 2008 .

[5]  Shuo-Hui Cao,et al.  Surface plasmon-coupled emission: what can directional fluorescence bring to the analytical sciences? , 2012, Annual review of analytical chemistry.

[6]  Wei-Peng Cai,et al.  Surface plasmon-coupled directional emission based on a conformational-switching signaling aptamer. , 2009, Chemical communications.

[7]  J. Joannopoulos,et al.  Electromagnetic Bloch waves at the surface of a photonic crystal. , 1991, Physical review. B, Condensed matter.

[8]  Zygmunt Gryczynski,et al.  Radiative decay engineering 4. Experimental studies of surface plasmon-coupled directional emission. , 2004, Analytical biochemistry.

[9]  L. Scaltrito,et al.  Surface-Wave-Assisted Beaming of Light Radiation from Localized Sources , 2014 .

[10]  J. Lombardi,et al.  Active Plasmonic Nanoantennas for Controlling Fluorescence Beams , 2013 .

[11]  Mark L Brongersma,et al.  Plasmonic beaming and active control over fluorescent emission. , 2011, Nature communications.

[12]  E. Yablonovitch,et al.  Inhibited spontaneous emission in solid-state physics and electronics. , 1987, Physical review letters.

[13]  N. Calander Surface plasmon-coupled emission and Fabry-Perot resonance in the sample layer: A theoretical approach. , 2005, The journal of physical chemistry. B.

[14]  J. Lakowicz,et al.  Steering Fluorescence Emission with Metal-Dielectric-Metal Structures of Au, Ag and Al. , 2013, The journal of physical chemistry. C, Nanomaterials and interfaces.

[15]  J Enderlein,et al.  Highly efficient optical detection of surface-generated fluorescence , 1999, Photonics West - Biomedical Optics.

[16]  W. Cai,et al.  Plasmonics for extreme light concentration and manipulation. , 2010, Nature materials.

[17]  Xiaocong Yuan,et al.  Direct image of surface-plasmon-coupled emission by leakage radiation microscopy. , 2010, Applied optics.

[18]  Rashid Bashir,et al.  A detection instrument for enhanced-fluorescence and label-free imaging on photonic crystal surfaces. , 2009, Optics express.

[19]  H. Ming,et al.  Effect of metal film thickness on Tamm plasmon-coupled emission. , 2014, Physical chemistry chemical physics : PCCP.

[20]  N. Arnold,et al.  Spectral and directional reshaping of fluorescence in large area self-assembled plasmonic-photonic crystals. , 2013, Nano letters.

[21]  J. Lakowicz,et al.  Surface-plasmon induced polarized emission from Eu(III)--a class of luminescent lanthanide ions. , 2014, Chemical communications.

[22]  F. Michelotti,et al.  Bloch surface waves-controlled fluorescence emission: Coupling into nanometer-sized polymeric waveguides , 2012 .

[23]  J. Lakowicz,et al.  Effects of Sample Thickness on the Optical Properties of Surface Plasmon-Coupled Emission. , 2004, The journal of physical chemistry. B.

[24]  Glenn P. Goodrich,et al.  Plasmonic enhancement of molecular fluorescence. , 2007, Nano letters.

[25]  H. Ming,et al.  Back focal plane imaging of directional emission from dye molecules coupled to one-dimensional photonic crystals , 2014, Nanotechnology.

[26]  C. Geddes,et al.  Directional surface plasmon coupled luminescence for analytical sensing applications: which metal, what wavelength, what observation angle? , 2009, Analytical chemistry.

[27]  Joseph R Lakowicz,et al.  Radiative decay engineering 3. Surface plasmon-coupled directional emission. , 2004, Analytical biochemistry.

[28]  T. Ebbesen,et al.  Plasmonic antennas for directional sorting of fluorescence emission. , 2011, Nano letters.

[29]  A. Requicha,et al.  Plasmonics—A Route to Nanoscale Optical Devices , 2001 .

[30]  J. Lakowicz,et al.  Radiative decay engineering 6: fluorescence on one-dimensional photonic crystals. , 2013, Analytical biochemistry.

[31]  I Gryczynski,et al.  Application of surface plasmon coupled emission to study of muscle. , 2006, Biophysical journal.

[32]  J. Lakowicz,et al.  Tamm State-Coupled Emission: Effect of Probe Location and Emission Wavelength , 2014, The journal of physical chemistry. C, Nanomaterials and interfaces.

[33]  Zygmunt Gryczynski,et al.  Ultraviolet surface plasmon-coupled emission using thin aluminum films. , 2004, Analytical chemistry.

[34]  J. Lakowicz,et al.  Tuning Fluorescence Direction with Plasmonic Metal-Dielectric- Metal Substrates. , 2013, The journal of physical chemistry letters.

[35]  J. Lakowicz,et al.  Radiative decay engineering 7: Tamm state-coupled emission using a hybrid plasmonic-photonic structure. , 2014, Analytical biochemistry.

[36]  B. MacCraith,et al.  Surface plasmon-coupled emission (SPCE)-based immunoassay using a novel paraboloid array biochip. , 2010, Biosensors & bioelectronics.

[37]  W. Vos,et al.  Fluorescence Lifetime of Emitters with Broad Homogeneous Linewidths Modified in Opal Photonic Crystals , 2008 .

[38]  Q. Zhan,et al.  Highly sensitive beam steering with plasmonic antenna , 2014, Scientific Reports.

[39]  I. Shelykh,et al.  Lossless interface modes at the boundary between two periodic dielectric structures , 2005 .

[40]  J. M. Chamberlain,et al.  Tamm plasmon-polaritons: Possible electromagnetic states at the interface of a metal and a dielectric Bragg mirror , 2007 .

[41]  Shuo-Hui Cao,et al.  Electric field assisted surface plasmon-coupled directional emission: an active strategy on enhancing sensitivity for DNA sensing and efficient discrimination of single base mutation. , 2011, Journal of the American Chemical Society.

[42]  A. Polman,et al.  Nanoscale Excitation Mapping of Plasmonic Patch Antennas , 2014 .

[43]  Jérôme Wenger,et al.  Plasmonic band structure controls single-molecule fluorescence. , 2013, ACS nano.