Spontaneous emission extraction and Purcell enhancement from thin-film 2-D photonic crystals

Boroditsky, M.; Vrijen, R. B.; Krauss, Thomas F.; Coccioli, R.; Bhat, R.; Yablonovitch, Eli

doi:10.1109/50.803000

Cited by 279 publications

(233 citation statements)

References 33 publications

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“…The bilayer slab (Fig.2a) LDOS is approximately 80% of the n = 1.7 conventional LSC, consistent with previous experimental and theoretical work on dielectric slabs [26]. The PC-LSC LDOS (Fig.2b) falls between that of n = 1.5 and n = 1.7 conventional LSCs, but does not exceed the n = 1.7 conventional LSC [24]. The TE-like (blue) and TM-like (red) contributions to the total LDOS confirm that the LDOS enhancement lies at the Van Hove singularity corresponding to the M -point (Fig.…”

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confidence: 76%

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Nanophotonic luminescent solar concentrators

Rousseau

Wood

2013

Applied Physics Letters

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We investigate the connection between photonic local density of states and luminescent solar concentrator (LSC) performance in two manufacturable nanocavity LSC structures, a bilayer slab and a slab photonic crystal. Finite-difference time-domain electromagnetic simulations show that the waveguided luminescence photon flux can be enhanced up to 30% for the photonic crystal design over a conventional LSC operating in the ray optic limit assuming the same number of excited lumophores. Further photonic engineering could realize an increase of up to one order of magnitude in the flux of waveguided luminescence.The luminescent solar concentrator (LSC) could decrease the installed cost of solar energy through building integration [1]. The LSC, a semi-transparent waveguide with embedded lumophores, concentrates sunlight by frequency downconversion; the lumophores absorb diffuse incident sunlight and luminesce at a redder, Stokesshifted wavelength. The majority of the luminescence is emitted into modes that can be guided by total internal reflection (TIR) to the waveguide edges, upon which small-area, high efficiency solar cells are normally fastened.Despite the LSC's simplicity, the concept has not been commercialized due to low performance. Experimental realizations have demonstrated a twelve-fold concentration of solar flux [2] and power conversion efficiency of 7.2%, well below the theoretical predictions of a flux concentration in excess of 100 [3] and power conversion efficiency of 26.8% [4]. Reabsorption of luminescence and subsequent re-emission into non-waveguided modes has been identified as the primary performance bottleneck [5][6][7][8][9].While prior work has demonstrated that LSCs consisting of lumophores embedded in optical nanocavities exhibit enhanced waveguiding [10] and reduced reabsorption [11], the nanocavity modifies the photonic local density of states (LDOS) and therefore the spatial and temporal luminescence distributations [12,13]. Here, we investigate the effect of the modified LDOS on LSC performance using first-principles simulations of Maxwell's equations in two realistic nanocavity LSC designs (Fig. 1, insets). After establishing a link between photonic LDOS and LSC performance, we use finite difference time domain (FDTD) simulations to show that a nanocavity LSC can increase the flux of waveguided luminescence photons by up to 30% over a conventional LSC. Finally, we assess the maximum theoretical performance gains from LDOS engineering in the LSC.First, we define a metric of LSC performance, con- * Electronic address: vwood@ethz.ch nect the performance metric to the photonic LDOS, and determine the conditions under which LSC performance comparisons can be made on the basis of the photonic LDOS. Luminescence photons are spontaneously emitted into one of many photonic modes of the LSC. These can be divided into two groups based on the wavevector in the LSC plane (k ): non-waveguided (ω ≥ c|k |) and total internally reflected (TIR, ω < c|k |) modes. In conventional LSCs, lumophore-filled w...

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confidence: 76%

“…The maximum TIR LDOS enhancement of spontaneous emission is limited by lumophore photoluminescence spectrum linewidth (Q m = ω 0 /∆ω) to Q m /4f tir [24]. LSC lumophore Q m -factors range from three to seven for organics (Fig.…”

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confidence: 99%

Nanophotonic luminescent solar concentrators

Rousseau

Wood

2013

Applied Physics Letters

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“…The characterization of 2D photonic crystals has been made mostly by measuring the spectrum of photoluminescence 4,5,13 and electroluminescence. 14 These techniques are useful and relatively easy to perform due to the fact that the light is generated inside the cavity.…”

Section: Introductionmentioning

confidence: 99%

Separation of radiation and absorption losses in two-dimensional photonic crystal single defect cavities

Alvarado-Rodriguez

Yablonovitch

2002

Journal of Applied Physics

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We have characterized the optical modes present in a two-dimensional photonic crystal single defect cavity fabricated in an InP/In 0.53 Ga 0.47 As/InP double heterostructure thin film on a glass slide. The cavity resonance was tuned to different frequencies in the 1.55 m spectral region. Radiation losses and material absorption influence the measured value of cavity quality factor Q. We separated these two loss mechanisms by performing a curve fit of the loss rate 1/Q versus the wavelength-dependent absorption coefficient of In 0.53 Ga 0.47 As. By extrapolating this curve to zero absorption, the radiation loss rate 1/Q rad is obtained.

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“…In wavelength-sized microresonator structures, semiconductor material luminescence can be either suppressed or enhanced, and they also enable narrowing of the spectral linewidth of the emitted light (Haroche, 1989;Yokoyama, 1992;Yamamoto, 1993;Vahala, 2003). Since 1946, when it was first proposed that the spontaneous emission from an excited state of an emitter can be significantly altered if it is placed into low-loss wavelength-scale cavity (Purcell, 1946), various microresonator designs for efficient control of spontaneous emission have been explored including microdisk Baba, 1997Baba, , 1999Backes, 1999;Cao, 2000;Fujita, 1999Fujita, , 2001Fujita, , 2002Zhang, 1996), microsphere Shopova, 2004;Rakovich, 2003) and micropost (Pelton, 2002;Reithmaier, 2004;Santori, 2004;Solomon, 2001;Gayral, 1998) resonators as well as PC defect cavities Boroditsky, 1999;Gayral, 1999). Depending on the Q-factors (resonance linewidths) of the modes supported by the microresonator in the spontaneous emission range of the resonator material, the two situations illustrated in Fig.…”

Section: 4mentioning

confidence: 99%

“…2c), formed, e.g., as arrays of air holes etched into a slab, have been demonstrated to simultaneously exhibit high Q-factors and ultra-small, wavelength-scale modal volumes Benisty, 1999;Chow, 2000;Yoshie, 2001;Akahane, 2003;Srinivasan, 2004;Noda, 2000;Boroditsky, 1999). In these cavities, the photonic-bandgap effect (fulfilment of the Bragg reflection conditions for all the propagation directions in a certain frequency range) is used for strong light confinement in the cavity plane, and TIR, for light confinement at the air-slab interface (Russel, 1996;.…”

Section: Mechanisms Of Light Confinement and Resonator Basic Featuresmentioning

confidence: 99%

Micro-Optical Resonators for Microlasers and Integrated Optoelectronics

Benson

Boriskina

Sewell

et al.

Frontiers in Planar Lightwave Circuit Technology

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Abstract:Optical microcavities trap light in compact volumes by the mechanisms of almost total internal reflection or distributed Bragg reflection, enable light amplification, and select out specific (resonant) frequencies of light that can be emitted or coupled into optical guides, and lower the thresholds of lasing. Such resonators have radii from 1 to 100 µm and can be fabricated in a wide range of materials. Devices based on optical resonators are essential for cavityquantum-electro-dynamic experiments, frequency stabilization, optical filtering and switching, light generation, biosensing, and nonlinear optics.

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Spontaneous emission extraction and Purcell enhancement from thin-film 2-D photonic crystals

Cited by 279 publications

References 33 publications

Nanophotonic luminescent solar concentrators

Nanophotonic luminescent solar concentrators

Separation of radiation and absorption losses in two-dimensional photonic crystal single defect cavities

Micro-Optical Resonators for Microlasers and Integrated Optoelectronics

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