Altering infrared metamaterial performance through metal resonance damping

Infrared metamaterial design is a rapidly developing field and there are increasing demands for effective optimization and tuning techniques. One approach to tuning is to alter the material properties of the metals making up the resonant metamaterial to purposefully introduce resonance frequency and bandwidth damping. Damping in the infrared portion of the spectrum is unique for metamaterials because the frequency is on the order of the inverse of the relaxation time for most noble metals. Metals with small relaxation times exhibit less resonance frequency damping over a greater portion of the infrared than metals with a longer relaxation time and, subsequently, larger dc conductivity. This leads to the unexpected condition where it is possible to select a metal that simultaneously increases a metamaterial’s bandwidth and resonance frequency without altering the geometry of the structure. Starting with the classical microwave equation for thin-film resistors, a practical equivalent-circuit model is develo...

[1]  Javier Alda,et al.  Planar infrared binary phase reflectarray. , 2008, Optics letters.

[2]  William L. Schaich,et al.  Measurement of the resonant lengths of infrared dipole antennas , 2000 .

[3]  M. Cuhaci,et al.  Novel photonically-controlled reflectarray antenna , 2006, IEEE Transactions on Antennas and Propagation.

[4]  G. Boreman,et al.  Modeling parameters for the spectral behavior of infrared frequency-selective surfaces. , 2001, Applied optics.

[5]  Ling Li,et al.  The design and fabrication of planar multiband metallodielectric frequency selective surfaces for infrared applications , 2006, IEEE Transactions on Antennas and Propagation.

[6]  Javier Alda,et al.  The effect of metal dispersion on the resonance of antennas at infrared frequencies , 2009 .

[7]  Ben A. Munk,et al.  Frequency Selective Surfaces: Theory and Design , 2000 .

[8]  Charles M. Rhoads,et al.  Mid-infrared filters using conducting elements. , 1982, Applied optics.

[9]  G. Boreman,et al.  Phase Characterization of Reflectarray Elements at Infrared , 2007, IEEE Transactions on Antennas and Propagation.

[10]  James C. Ginn,et al.  Relaxation time effects on dynamic conductivity of alloyed metallic thin films in the infrared band , 2008 .

[11]  Vladimir M. Shalaev,et al.  Stochastic optimization of low-loss optical negative-index metamaterial , 2007 .

[12]  B. A. Munk,et al.  Reflection properties of periodic surfaces of loaded dipoles , 1971 .

[13]  K. Malloy,et al.  Experimental demonstration of near-infrared negative-index metamaterials. , 2005, Physical review letters.

[14]  William L. Schaich,et al.  Resonant enhancement of emission and absorption using frequency selective surfaces in the infrared , 2002 .

[15]  Richard J. Langley,et al.  Active frequency-selective surfaces , 1996 .

[16]  Erich N. Grossman,et al.  First THz and IR characterization of nanometer-scaled antenna-coupled InGaAs/InP Schottky-diode detectors for room temperature infrared imaging , 2007, SPIE Defense + Commercial Sensing.

[17]  J. Tharp,et al.  Demonstration of a single-layer meanderline phase retarder at infrared. , 2006, Optics letters.

[18]  Lukas Novotny,et al.  Effective wavelength scaling for optical antennas. , 2007, Physical review letters.

[19]  R. Marhefka,et al.  Ohmic loss in frequency-selective surfaces , 2003 .

[20]  B. Monacelli,et al.  Infrared frequency selective surface based on circuit-analog square loop design , 2005, IEEE Transactions on Antennas and Propagation.

[21]  M. Fox Optical Properties of Solids , 2010 .