We demonstrate the controlled enhancement of photoresponsivity in a graphene photodetector by coupling to slow light modes in a long photonic crystal linear defect cavity. Near the Brillouin zone (BZ) boundary, spectral coupling of multiple cavity modes results in broad-band photocurrent enhancement from 1530 nm to 1540 nm.Away from the BZ boundary, individual cavity resonances enhance the photocurrent eight-fold in narrow resonant peaks. Optimization of the photocurrent via critical coupling of the incident field with the graphene-cavity system is discussed. The enhanced photocurrent demonstrates the feasibility of a wavelength-scale graphene photodetector for efficient photodetection with high spectral selectivity and broadband response. a) These authors contribute equally to this work 1 arXiv:1311.2080v1 [cond-mat.mes-hall] 8 Nov 2013The unique properties of graphene have generated strong interest in developing optoelectronics devices based on the material 1,2 . Examples include graphene-based high speed electro-optical modulators 3,4 , photodetectors 5,6 , saturable absorbers 7,8 , and nonlinear media for four-wave mixing 9-11 . Intrinsic graphene exhibits absorption of 2.3% 12 in the infrared to visible spectra range. While this absorption coefficient is remarkably high for a single atomic layer, for practical applications, a larger absorption coefficient is needed. To increase the light-matter interactions in graphene, approaches to date have included the integration of graphene with optical micro-cavities 13-17 , plasmonic nanostructures 18-22 and silicon photonic waveguides 3,4,23,24 .In this paper, we demonstrate a graphene photodetector integrated in a linear defect cavity defined in a planar photonic crystal (PPC). A single graphene layer strongly couples to the cavity evanescent field, increasing the light-matter interaction in graphene 25 for photocurrent generation. Coupled mode theory predicts maximal absorption into the graphene absorber when the intrinsic cavity loss rate, κ c , equals the loss rate into the graphene sheet, κ cg 25 .Upon optimization of the cavity design, we obtain nearly critical coupling with κ cg /κ c ≈ 1.3 and observe an eight-fold enhancement of photocurrent in the graphene photo-detector. The observed reflectivity and photocurrent spectra in the graphene detector agree well with the coupled graphene-cavity model. Spatial mapping of the photocurrent allows us to compare the response of the graphene detector with and without optical enhancement via the PPC cavity.The PPC cavity-integrated graphene photodetector is illustrated in Fig. 1(a). An airsuspended PPC cavity was fabricated on a silicon-on-insulator wafer with a 260 nm thick silicon (Si) membrane, using a combination of electron beam lithography (EBL) and dry/wet etching steps. The PPC has a lattice spacing of a = 450 nm and hole radius of 0.29a. A linear defect in the center of the PPC lattice forms a long cavity ( Fig. 1(b)), producing bounded cavity modes. A layer of 20 nm hafnium oxide (HfO 2 ), deposited by atomic...
