Search Advanced Filters Keyword - Any -FOS: Physical sciencesFOS: Physical sciencesFour wave mixingMaterials Science (cond-mat.mtrl-sci)Photonic crystalsRaman scatteringRing resonatorsSecond harmonic generationWhispering gallery modes AuthorTitleTypeYear ABCDEFGHIJKLMNOPQRSTUVWXYZ Applied Filters: First Letter Of Last Name: R Reset 26 Publications Rahi SJ, Rodriguez AW, Emig T, Jaffe RL, Johnson SG, Kardar M. 2008. Nonmonotonic effects of parallel sidewalls on Casimir forces between cylinders. PRA-rapid. 77:030101. Referenced from link.aps.org: Nonmonotonic effects of parallel sidewalls on Casimir forces between cylinders. Ramirez D, Rodriguez AW, Hashemi H, Joannopoulos JD, Soljacic M, Johnson SG. 2011. Degenerate four-wave mixing in triply-resonant nonlinear Kerr cavities. PRA. 83:033834. Referenced from pra.aps.org: Degenerate four-wave mixing in triply-resonant nonlinear Kerr cavities. Reed EJ, Rodriguez AW, Manaa R, Fried LE, Traver C. 2012. Ultrafast detonation of hydrazoic acid (HN$^3$). PRL. 109:038301. Referenced from prl.aps.org: Ultrafast detonation of hydrazoic acid (HN$^3$). Reid MTH, Miller OD, Polimeridis A, Rodriguez AW, Tomlinson EM, Johnson SG. 2017. Photon torpedoes and Rytov pinwheels: integral-equation modeling of non-equilibrium fluctuation-induced forces and torques on nanoparticles. arXiv:1708.01985. Referenced from arxiv.org: Photon torpedoes and Rytov pinwheels: integral-equation modeling of non-equilibrium fluctuation-induced forces and torques on nanoparticles. Reid MTH, Rodriguez AW, Johnson SG. 2013. Fluctuation-induced phenomena in nanoscale systems: harnessing the power of noise. Proc. IEEE. 101:531–545. Referenced from ieeexplore.ieee.org: Fluctuation-induced phenomena in nanoscale systems: harnessing the power of noise. Reid H, Rodriguez AW, White J, Johnson SG. 2009. Efficient computation of Casimir interactions between arbitrary three-dimensional objects. PRL. 103:040401. Referenced from link.aps.org: Efficient computation of Casimir interactions between arbitrary three-dimensional objects. Rodriguez AW, McCauley AP, Joannopoulos JD, Johnson SG. 2010. Theoretical ingredients of a Casimir analog computer. PNAS. 107:9531–9536. Referenced from www.pnas.org: Theoretical ingredients of a Casimir analog computer. Rodriguez AW, Munday J, Dalvit D, Capasso F, Joannopoulos JD, Johnson SG. 2008. Stable suspension and dispersion-induced transitions from repulsive Casimir forces between fluid-separated cylinders. PRL. 101:190404. Referenced from link.aps.org: Stable suspension and dispersion-induced transitions from repulsive Casimir forces between fluid-separated cylinders. Rodriguez AW, Joannopoulos JD, Johnson SG. 2008. Repulsive and attractive Casimir forces in a glide-symmetric geometry. PRA. 77:062107. Referenced from link.aps.org: Repulsive and attractive Casimir forces in a glide-symmetric geometry. Rodriguez AW, McCauley A, Avniel Y, Johnson SG. 2008. Computation and visualization of photonic quasicrystal spectra via Bloch s theorem. PRB. 77:104201. Referenced from link.aps.org: Computation and visualization of photonic quasicrystal spectra via Bloch s theorem. Rodriguez A, Ibanescu M, Iannuzzi D, Joannopoulos JD, Johnson SG. 2007. Virtual photons in imaginary time: computing exact Casimir forces via standard numerical-electromagnetism techniques. PRA. 76:032106. Referenced from link.aps.org: Virtual photons in imaginary time: computing exact Casimir forces via standard numerical-electromagnetism techniques. Rodriguez A, Johnson SG. 2007. Efficient generation of correlated random numbers using Chebychev-optimal magnitude-only IIR filters. arXiv:0703152. 99:80401. Referenced from arxiv.org: Efficient generation of correlated random numbers using Chebychev-optimal magnitude-only IIR filters. Rodriguez A, Soljacic M, Joannopoulos JD, Johnson SG. 2007. $\chi^(2)$ and $\chi^(3)$ harmonic generation at a critical power in inhomogeneous doubly resonant cavities. OE. 15:7303–7318. Referenced from www.opticsinfobase.org: $\chi^(2)$ and $\chi^(3)$ harmonic generation at a critical power in inhomogeneous doubly resonant cavities. Rodriguez A, Ibanescu M, Joannopoulos JD, Johnson SG. 2005. Disorder-immune confinement of light in photonic crystal cavities. OL. 30:3192–3194. Referenced from www.opticsinfobase.org: Disorder-immune confinement of light in photonic crystal cavities. Rodriguez AW, Hui PC, Woolf DN, Johnson SG, Loncar M, Capasso F. 2014. Classical and fluctuation-induced electromagnetic interactions in micronscale systems: designer bonding, antibonding, and Casimir forces. Annalen der Physik. 527:45–80. Rodriguez AW, Reid MTH, Intravaia F, Woolf A, Dalvit DAR, Capasso F, Johnson SG. 2013. Geometry-induced Casimir suspension of oblate bodies in fluids. PRL. 111:180402. Referenced from prl.aps.org: Geometry-induced Casimir suspension of oblate bodies in fluids. Rodriguez AW, Reid MTH, Johnson SG. 2013. Fluctuating surface-current formulation of radiative heat transfer for arbitrary geometries: theory and applications. PRB. 88:054305. Referenced from prb.aps.org: Fluctuating surface-current formulation of radiative heat transfer for arbitrary geometries: theory and applications. Rodriguez AW, Reid MTH, Varela J, Joannopoulos JD, Capasso F, Johnson SG. 2013. Anomalous near-field heat transfer between a cylinder and a perforated surface. PRL. 110:014301. Referenced from link.aps.org: Anomalous near-field heat transfer between a cylinder and a perforated surface. Rodriguez AW, Reid MTH, Johnson SG. 2012. Fluctuating surface-current formulation of radiative heat transfer for arbitrary geometries. PRB-rapid. 86:220302. Referenced from link.aps.org: Fluctuating surface-current formulation of radiative heat transfer for arbitrary geometries. Rodriguez AW, Ilic O, Bermel P, Celanovic I, Joannopoulos JD, Soljacic M, Johnson SG. 2011. Frequency-selective near-field enhancement of radiative heat transfer via photonic-crystal slabs: a general computational approach for arbitrary geometries and materials. PRL. 107:114301. Referenced from prl.aps.org: Frequency-selective near-field enhancement of radiative heat transfer via photonic-crystal slabs: a general computational approach for arbitrary geometries and materials. Rodriguez AW, Capasso F, Johnson SG. 2011. The Casimir effect in microstructured geometries. Nature Photonics. 5:211–221. Referenced from www.nature.com: The Casimir effect in microstructured geometries. Rodriguez AW, Woolf D, Hui P-C, Iwase E, McCauley AP, Capasso F, Loncar M, Johnson SG. 2011. Designing evanescent interactions to control the expression of Casimir forces in optomechanical structures. APL. 98:194105. Referenced from apl.aip.org: Designing evanescent interactions to control the expression of Casimir forces in optomechanical structures. Rodriguez AW, McCauley AP, Hui P-C, Woolf D, Capasso F, Loncar M, Johnson SG. 2011. Bonding, antibonding and tunable restoring optical forces in asymmetric membranes. OE. 19:2225–2241. Referenced from www.opticsinfobase.org: Bonding, antibonding and tunable restoring optical forces in asymmetric membranes. Rodriguez AW, Woolf D, McCauley AP, Capasso F, Johnson SG. 2010. Achieving a strongly temperature-dependent Casimir effect. PRL. 105:060401. Referenced from prl.aps.org: Achieving a strongly temperature-dependent Casimir effect. Rodriguez AW, McCauley AP, Woolf D, Capasso F, Joannopoulos JD, Johnson SG. 2010. Non-touching nanoparticle diclusters bound by repulsive and attractive Casimir forces. PRL. 104:160402. Referenced from prl.aps.org: Non-touching nanoparticle diclusters bound by repulsive and attractive Casimir forces. Rodriguez AW, McCauley AP, Joannopoulos JD, Johnson SG. 2009. Casimir forces in the time domain: Theory. PRA. 80:012115. Referenced from link.aps.org: Casimir forces in the time domain: Theory.
