Plasmonic near-field transducer for heat-assisted magnetic recording

Abstract Plasmonic devices, made of apertures or antennas, have played significant roles in advancing the fields of optics and opto-electronics by offering subwavelength manipulation of light in the visible and near infrared frequencies. The development of heat-assisted magnetic recording (HAMR) opens up a new application of plasmonic nanostructures, where they act as near field transducers (NFTs) to locally and temporally heat a sub-diffraction-limited region in the recording medium above its Curie temperature to reduce the magnetic coercivity. This allows use of very small grain volume in the medium while still maintaining data thermal stability, and increasing storage density in the next generation hard disk drives (HDDs). In this paper, we review different plasmonic NFT designs that are promising to be applied in HAMR. We focus on the mechanisms contributing to the coupling and confinement of optical energy. We also illustrate the self-heating issue in NFT materials associated with the generation of a confined optical spot, which could result in degradation of performance and failure of components. The possibility of using alternative plasmonic materials will be discussed.

[1]  Duane C. Karns,et al.  Heat-assisted magnetic recording by a near-field transducer with efficient optical energy transfer , 2009 .

[2]  Xianfan Xu,et al.  Plasmonic effects in near-field optical transmission enhancement through a single bowtie-shaped aperture , 2006 .

[3]  Paul M. Jones,et al.  Effect of fly height and refractive index on the transmission efficiency of near-field optical transducers , 2006 .

[4]  M. Stockman,et al.  Nanofocusing of optical energy in tapered plasmonic waveguides. , 2004, Physical review letters.

[5]  Matteo Staffaroni,et al.  Circuit Analysis in Metal-Optics, Theory and Applications , 2011 .

[6]  A. Kildishev,et al.  Local heating with lithographically fabricated plasmonic titanium nitride nanoparticles. , 2013, Nano letters.

[7]  W. Challener,et al.  Near-Field Optics for Heat-Assisted Magnetic Recording (Experiment, Theory, and Modeling) , 2009 .

[8]  Y. Ashizawa,et al.  Highly Efficient Waveguide Using Surface Plasmon Polaritons for Thermally Assisted Magnetic Recording , 2013 .

[9]  H. Lezec,et al.  Extraordinary optical transmission through sub-wavelength hole arrays , 1998, Nature.

[10]  Chubing Peng,et al.  Optical Transducers for Near Field Recording , 2006 .

[11]  Fumihiro Tawa,et al.  Optical head with a butted-grating structure that generates a subwavelength spot for laser-assisted magnetic recording , 2007 .

[12]  P. Lalanne,et al.  Quasi-cylindrical wave contribution in experiments on extraordinary optical transmission , 2012, Nature.

[13]  S. N. Piramanayagam,et al.  Developments in Data Storage: Materials Perspective , 2011 .

[14]  J. A. Bain,et al.  Evanescent Coupling Between Dielectric and Plasmonic Waveguides for HAMR Applications , 2011, IEEE Transactions on Magnetics.

[15]  Daniel E. Prober,et al.  Optical antenna: Towards a unity efficiency near-field optical probe , 1997 .

[16]  M. Brereton Classical Electrodynamics (2nd edn) , 1976 .

[17]  M. Fatih Erden,et al.  Heat Assisted Magnetic Recording , 2008, Proceedings of the IEEE.

[18]  Mingsheng Zhang,et al.  Light Delivery System for Heat-Assisted Magnetic Recording , 2009, IEEE Transactions on Magnetics.

[19]  Henri Lezec,et al.  Diffracted evanescent wave model for enhanced and suppressed optical transmission through subwavelength hole arrays. , 2004, Optics express.

[20]  D. Pozar Microwave Engineering , 1990 .

[21]  E. Jin,et al.  Cutoff wavelength of ridge waveguide near field transducer for disk data storage. , 2008, Optics express.

[22]  L Martin-Moreno,et al.  Mechanisms for extraordinary optical transmission through bull's eye structures. , 2011, Optics express.

[23]  Sang‐Hyun Oh,et al.  Tip‐based plasmonics: squeezing light with metallic nanoprobes , 2013 .

[24]  N. F. Hulst,et al.  Moulded photoplastic probes for near‐field optical applications , 2001, Journal of Microscopy.

[25]  A. Kildishev,et al.  Demonstration of Al:ZnO as a plasmonic component for near-infrared metamaterials , 2012, Proceedings of the National Academy of Sciences.

[26]  C. Peng Efficient excitation of a monopole optical transducer for near-field recording , 2012 .

[27]  Harry A. Atwater,et al.  Low-Loss Plasmonic Metamaterials , 2011, Science.

[28]  Christophe Mihalcea,et al.  Light Delivery Techniques for Heat-Assisted Magnetic Recording , 2003 .

[29]  W. Challener,et al.  Near‐field radiation of bow‐tie antennas and apertures at optical frequencies , 2003, Journal of microscopy.

[30]  Katsuyuki Naito,et al.  Thermally assisted magnetic recording on a bit-patterned medium by using a near-field optical head with a beaked metallic plate , 2008 .

[31]  Xiaobin Wang,et al.  HAMR Recording Limitations and Extendibility , 2013, IEEE Transactions on Magnetics.

[32]  T. Rausch,et al.  HAMR Drive Performance and Integration Challenges , 2013, IEEE Transactions on Magnetics.

[33]  S. Maier Plasmonics: Fundamentals and Applications , 2007 .

[34]  Harukazu Miyamoto,et al.  Integrated head design using a nanobeak antenna for thermally assisted magnetic recording. , 2012, Optics express.

[35]  Wei Bao,et al.  Mapping Local Charge Recombination Heterogeneity by Multidimensional Nanospectroscopic Imaging , 2012, Science.

[36]  Xianfan Xu,et al.  Enhanced optical near field from a bowtie aperture , 2006 .

[37]  Vladimir M. Shalaev,et al.  Searching for better plasmonic materials , 2009, 0911.2737.

[38]  Xianfan Xu,et al.  Finitte-Difference Time-Domain Studies on Optical Transmission through Planar Nano-Apertures in a Metal Film , 2004 .

[39]  Gordon S. Kino,et al.  Optical antennas: Resonators for local field enhancement , 2003 .

[40]  M. Raschke,et al.  Nano-optical imaging and spectroscopy of order, phases, and domains in complex solids , 2012 .

[41]  D. A. Dunnett Classical Electrodynamics , 2020, Nature.

[42]  Chengwu An,et al.  Relationship Between Near Field Optical Transducer Laser Absorption and Its Efficiency , 2012, IEEE Transactions on Magnetics.

[43]  Dieter W. Pohl,et al.  Bow-tie optical antenna probes for single-emitter scanning near-field optical microscopy , 2007 .

[44]  T Matsumoto,et al.  Writing 40 nm marks by using a beaked metallic plate near-field optical probe. , 2006, Optics letters.

[45]  J. Bain,et al.  The influence of media optical properties on the efficiency of optical power delivery for heat assisted magnetic recording , 2011 .

[46]  Y. Wang,et al.  Flying plasmonic lens in the near field for high-speed nanolithography. , 2008, Nature nanotechnology.

[47]  Lambertus Hesselink,et al.  Ultrahigh light transmission through a C-shaped nanoaperture. , 2003, Optics letters.

[48]  F. Keilmann,et al.  Near-field microscopy by elastic light scattering from a tip , 2004, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[49]  D. Bogy,et al.  On the lifetime of plasmonic transducers in heat assisted magnetic recording , 2012 .

[50]  H. Bethe Theory of Diffraction by Small Holes , 1944 .

[51]  G. Zhu,et al.  Engineering of low-loss metal for nanoplasmonic and metamaterials applications , 2009 .

[52]  Xianfan Xu,et al.  High transmission nanoscale bowtie-shaped aperture probe for near-field optical imaging , 2007 .

[53]  Xianfan Xu,et al.  Nanoscale ridge aperture as near-field transducer for heat-assisted magnetic recording. , 2011, Applied optics.

[54]  R. W. Christy,et al.  Optical constants of transition metals: Ti, V, Cr, Mn, Fe, Co, Ni, and Pd , 1974 .

[55]  R. W. Christy,et al.  Optical Constants of the Noble Metals , 1972 .

[56]  P. Srisungsitthisunti,et al.  Extraordinary transmission from high-gain nanoaperture antennas , 2010 .

[57]  A. Urbas,et al.  Organic materials with negative and controllable electric permittivity , 2011, CLEO: 2011 - Laser Science to Photonic Applications.

[58]  V. Shalaev,et al.  Alternative Plasmonic Materials: Beyond Gold and Silver , 2013, Advanced materials.

[59]  Jordan A. Katine,et al.  Magnetic recording at 1.5 Pb m −2 using an integrated plasmonic antenna , 2010 .

[60]  C. Peng,et al.  Surface-Plasmon Resonance Characterization of a Near-Field Transducer , 2012, IEEE Transactions on Magnetics.

[61]  K. Şendur Perpendicular oriented single-pole nano-optical transducer. , 2010, Optics express.

[62]  James A. Bain,et al.  Ridge waveguide as a near-field optical source , 2003 .

[63]  Chubing Peng,et al.  Near-field radiation from a ridge waveguide transducer in the vicinity of a solid immersion lens. , 2005, Physical review letters.

[64]  Vladimir M. Shalaev,et al.  Performance analysis of nitride alternative plasmonic materials for localized surface plasmon applications , 2012 .

[65]  A. Otto Excitation of nonradiative surface plasma waves in silver by the method of frustrated total reflection , 1968 .

[66]  Baoxi Xu,et al.  Thermal issues and their effects on heat-assisted magnetic recording system (invited) , 2012 .

[67]  Alexandra Boltasseva,et al.  Oxides and nitrides as alternative plasmonic materials in the optical range [Invited] , 2011 .

[68]  M. Sharrock,et al.  Time-dependent magnetic phenomena and particle-size effects in recording media , 1990 .

[69]  Lambertus Hesselink,et al.  Nano-aperture with 1000x power throughput enhancement for very small aperture laser system (VSAL) , 2002, Optical Data Storage.

[70]  Chubing Peng,et al.  HAMR Areal Density Demonstration of 1+ Tbpsi on Spinstand , 2013, IEEE Transactions on Magnetics.

[71]  R A Linke,et al.  Beaming Light from a Subwavelength Aperture , 2002, Science.

[72]  Yuan Wang,et al.  A two-stage heating scheme for heat assisted magnetic recording , 2014 .

[73]  Fumihiro Tawa,et al.  Generation of nanosized optical beams by use of butted gratings with small numbers of periods. , 2004, Applied optics.