1. Technical Field
This patent application relates to a monolithically integrated electromagnetic energy collection device and related devices.
2. Background Information
The integration of photonic devices for low-cost on-chip optical interconnects is of great interest for high speed computing. Additionally, there is a desire in the solar energy industry to tap the potential high theoretical conversion efficiency of rectennas, where highly concentrated coherent light in a waveguide could enable higher rectenna efficiencies.
One of the key elements for both end uses is the efficient integration of a waveguide and a photodetector. Coupling of light from a planar waveguide to a monolithically integrated photodetector or rectenna can be accomplished in several ways, but it has remained a challenge to do so with high efficiency across a broad spectral band.
This application concerns the efficient coupling of light or other electromagnetic energy in a planar waveguide/photoconversion device. It augments the feature of spectral separation which is advantageous for both wavelength division multiplexing in optical communications to increase bandwidth, and solar conversion to increase efficiency. The structures provide evanescent coupling, butt coupling and vertically coupled total-internal-reflection (TIR) type arrangements.
A light or other electromagnetic energy concentrator module consists of a prism, a waveguide core, and uniform thickness gap layer disposed between them. Photovoltaics (in the case of a solar application) or nantenna structures (more generally) are disposed adjacent the waveguide core. An optional multi-layer cladding restricts angular deviation; certain optional embodiments also include gratings and spectrally filtered coupling.
More particularly, an electromagnetic energy concentrator includes a prism, and a waveguide aligned with the prism. The waveguide includes a waveguide core layer. A gap layer of uniform thickness may be disposed between the prism and waveguide. Energy detectors, which may be photovoltaics or nantenna elements, are disposed adjacent to and co-extensive with a second surface of the waveguide. The detectors may be placed in one or more cladding layers on the second surface of the waveguide.
In one arrangement, the detectors are operative in each of at least two bands, and the horizontal spacing between detectors operating in a given band depends on the wavelength of that given band. The detectors may also be vertically positioned with respect to the prism, such that that distance depends on 1/e.
The detectors may be disposed in a homogenous carrier layer, or may be disposed in two or more layers such that detectors operative in one band are disposed in a different layer than the detectors operative in another band.
In one arrangement, gratings may be disposed adjacent each detector such that the gratings each comprise multiple elements, with a spacing between adjacent grating elements depending on a position with respect to the waveguide that further depends on an operative wavelength of the adjacent detector. In this arrangement, the grating element spacing is preferably chirped; the size of the grating elements can also depends on their respective horizontal position.
Elongated strips of material are optionally disposed within the waveguide core such that the strips have an index of refraction the same as an index of refraction of the prism. This helps equalize dispersion of the prism to dispersion of the waveguide.
In yet another arrangement, a dichroic filter can be disposed adjacent the waveguide and the detectors wherein. The dichroic filter may be formed from a multiple layer material stack.
In still other implementations, one or more internal reflection mirrors are embedded in waveguide to efficiently direct solar energy to the detectors.
In still other implementations, the detectors include MIM rectennas disposed in vertical series adjacent and below each mirror.
The detectors may also include a plurality of bowtie shaped antenna elements arranged as an array in at least two dimensions.
The device can be made by locating a prism portion as a substrate; depositing a coupling layer on the prism; depositing a core waveguide on the coupling layer; and placing a set of periodically spaced photovoltaics on the core waveguide layer.
Other arrangements are possible, as described below and as particularly set forth in the claims that follow.
The foregoing will be apparent from the following more particular description of example embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments of the present invention.
There are many applications for coupling light into a thin optical waveguide. Most techniques for coupling, such as grating coupling and prism coupling, are inherently narrowband due to the dispersion of the waveguide. In the case of prism coupling, the incoming wave typically must be a plane wave, and must also be input at an angle that is commensurate with the effective index of the waveguide, given the prism's inherent dispersion over the spectral band of interest.
Incoming light reaches the prism 100 and is then coupled to the waveguide core 102 after travelling through the gap 101. The incoming light is coupled at angle θin to a prism face of angle θp to the horizontal plane. This angle Gin of coupling is defined in equation (1) (below) as a function of the index of refraction of materials (np for the prism, and neff for the effective index of the waveguide.
where
By optimizing the material used for the cladding 103 and geometric properties to control the desired effective index of the waveguide (neff), the collector can be optimized to produce a single or narrow range of angles that will allow a large spectral bandwidth to be efficiently coupled into the waveguide 102.
Previous attempts at altering the prism 101 material properties for a given waveguide have, via modelling, produced a 110 nm spectral bandwidth in the visible wavelength region. There a prescription for a fictitious material was designed; see Optics Communications 136(1997) 320-326, Mendes, Sergio B., et al., “Achromatic prism-coupler for planar waveguide”. With the structure in
As mentioned above, one or more dielectric cladding layers 103 is desired to abut the waveguide core 102. However, this can present a problem during integration and assembly of the waveguide 102 and photovoltaic cells 105. For better efficiency, the PV cells 105 should abut the waveguide core 102, and so they cannot be bonded to the cladding 103. In one embodiment therefore, there is no physical cladding layer 103 beneath the waveguide core; rather air is used as the dielectric “cladding”. This simplifies the manufacturing process by allowing the waveguide core 102 to be bonded directly to one or more PV cells 105. In this configuration, due to the lack of any physical cladding material, the air beneath the waveguide core is considered the cladding of the waveguide. This type of waveguide actually confines fields within the core to a greater degree than other arrangements.
This “air cladding” arrangement also lends itself to an improved manufacturing process. Using the bottom of prism 100 as a substrate, coupling layer 101 is first deposited. Next, the core waveguide 102 is deposited, and then a third layer consisting of periodically spaced photovoltaics 105 can be deposited or affixed to the core waveguide layer. An electrical backplane (not shown) can then be affixed to the assembly.
Continuing to refer to
In a preferred arrangement, there are multiple PVs disposed along the waveguide surface at one or more collector regions 106-1, 106-2, . . . , 106-5. For each distinct solar wavelength band of interest, there exist photovoltaic cells that are very efficient. Tuned dielectric coatings (not shown in
The solar wavelength bands can be divided in any number of ways, including 1) multiple single-junction, single-band PV devices, 2) multiple multi-junction, multi-band PV devices or 3) any combination thereof. The actual division and distribution of these options is optimized based on the responsivity of each device, with respect to overall efficiency across the entire solar band.
In the structure shown in
As shown in
In the illustrated implementation the spacing between the 400 nm photovoltaic detectors is 50 microns. The PVs operating at longer wavelengths are disposed with progressively wider spacing to coherently absorb more light while maintaining a 0.5 degree beamwidth. For example, the spacing of the 800 nm detectors can be 100 microns, and that of the 1200 nm detectors 150 microns. Thus, the spacing between PV's in layer(s) 103 depends on the respective operating bands of the PVs as well as the desired beamwidth.
In another arrangement, a single composite photovoltaic layer 103-c is seen in
There is possibly a sight wavelength dependency in the coupling layer 101 if the operating wavelength range is from 400 nm to 1200 nm. That dependency, if considered critical, can be mitigated by implementing a three layer coupling layer 101 in some embodiments, using the configuration shown in
The aforementioned waveguide design was intended for the capture and concentration of solar energy, although the design can be tailored for operating in other optical wavelength regions, such as those used for optical communication systems.
Evanescent coupling of light within the waveguide to photovoltaic cells 105 can be further encouraged by matching the PV cells' 105 penetration (e.g., vertical position) in the waveguide 102 to their respective 1/e field strength confinement location. This location is defined as the depth (or penetration) into the waveguide at which the cross-sectional power is 1/e of its peak value. The power density for the lower wavelengths is greater at the core 102 center; this is because as the wavelength increases, more energy travels down into the cladding layers 103. The result is that the light activating the relatively high energy band gap cells 105-h (those which are operative at the shorter wavelengths) will penetrate the furthest into the waveguide, and the light activating the lower band gap energy cells 105-l (operative at the longer wavelengths) will penetrate the least, as shown in
As higher band gap cells 105-h typically have a higher absorption coefficient, the coupling length is shorter, and these cells will be smaller in width along the horizontal. If one considers the PV as elements in an antenna array, it will be seen that the separation between the PVs will be commensurate with their wavelength band or band gap. This is also depicted in
Selectively choosing the relative depth position of the PV 105 within the waveguide thus acts as a spectral filter for coupling the desired portion of the spectrum to the respective PV cell 105. This allows for maximum efficiency of the spatially separated band gap optimized cell architecture. It also potentially alleviates the need to place band pass filters on the PVs 105.
The distance between the PV 105 and the waveguide core 102 is optimized such that the PVs can absorb the maximum amount of energy per unit length from the waveguide 102, without impeding or affecting the adjacent band.
Shown specifically is a region such as region 106-3 containing all three band gap PVs. In
The propagation to each respective photovoltaic 105 is governed by the element spacing of each grating 210. For a given element spacing, the longer the wavelength and the less propagation, until finally a cutoff wavelength is reached where propagation is zero. For example, the element spacing for grating 210-h is chosen such that is can direct all of the light energy at 400-580 nm into its corresponding 400-580 photovoltaic 105-h, while light at the longer wavelengths is not. The same can be said of the grating 210-m, which delivers all energy it receives at 580-840 nm into its corresponding photovoltaic 105-m, with the 840-1200 nm band energy passing through unattenuated until it reaches grating 210-l.
Towards this end, the spacing of the elements that make up each grating preferably changes along the length of each grating 210, in a chirp like fashion. Comparing the various gratings 210-h, 210-m, 210-l, it is also preferred that they collectively exhibit a chirp taper to their element lengths.
The size of the elements that make up each grating 210 can also similarly vary. For example, the grating element size used for grating 210-h used with the 400 nm PV 105-h can be ⅓ the size of the grating element 210-l used for the 1200 nm PV 105-l. Tapering the element size in this way acts as a high pass filter between the waveguide 102 and the photovoltaics 105, since Rayleigh scattering is involved where the element response is 1/(wavelength) to the fourth power.
The chirp spacing between elements of each grating can be determined by λ/2 where A is the wavelength at the center of the band of interest of each respective photovoltaic, and where there are approximately 10 grating elements per photovoltaic.
The size of the larger elements can also be made relative to the element size chosen for the shorter wavelengths (e.g., 400-500 nm). See
For the traveling wave structure to receive solar energy over a broad band, high efficiency in receive must be achieved without changing the elevation angle. To do this, one should achieve a uniform mode match for both horizontal and vertical polarizations across frequency, between the wedge and the waveguide. Because most materials suitable for use as the prism 100 are inherently dispersive across the solar band, we correct for dispersion within the waveguide to “mode match” across the entire band. This mode match involves matching dispersion curves of the prism 100 and waveguide 102. When this is achieved, the concentrator has high receive efficiency at the same receive angle across all wavelengths of interest. The concentrator is then aimed at the source (the sun) at this angle.
This mode matching can be achieved over a broadband and over polarization by inserting strips of material 230, preferably rectangular in shape, within the waveguide 102 that have the same dispersion characteristics of the prism 100.
The illustrated example involved a TiO2 (titanium dioxide) prism 100 and a core 102 waveguide formed of SiO2 (silicon dioxide). The correcting strips 230 (made of TiO2) are embedded into the SiO2 and optimized to obtain the desired performance.
The performance can be characterized by the equation
where the β's are the respective propagation constants of the waveguide 102 and the wedge 100. The sizes of the strips 230 are adjusted until the ratio is constant over all wavelengths of interest and both the horizontal and vertical polarizations.
When the desired mode matching is achieved, receive efficiency lines up within the same angular region, as depicted in the receive efficiency chart in
The device can also achieve dispersion tailoring using a multi-layered cladding 103, applicable to both the solar case and operation at other wavelength regions. The particular region chosen for proof of design was 400 nm to 1200 nm.
Given a prism 100 made from Ohara S-LAH65 with a 55 degree angle (θp), the waveguide 102 design is expected to produce a single angle of incidence coupling over a 400 nm to 1200 nm range by using five (5) closely spaced refractive index layers 103 of specifically designed thickness to tailor the waveguide effective index for a constant ratio of neff/np over the wavelength range.
The optimum effective index of the waveguide of
A multijunction photovoltaic structure that monolithically integrates the waveguide while physically and spectrally separating the junctions is shown in
It is known that the lattice and current matching constraints of monolithic multi-junction solar cells limit their efficiency, while mechanically stacking the junctions or spatially separating the junctions allows more freedom of cell design and band gap optimization for improved efficiency. However, mechanically stacking these cells increases the complexity by introducing additional insulation layers and the handling and processing of thin junction layers. Very often the cells must go through substrate removal, carrier bonding, and thin wafer handling which are not trivial and affect the yield and cost of the devices. Also, creating separate junctions accessed by refractive optics and filters have alignment sensitivities that increase with the number of cells. Shown here is a way to utilize a special monolithically grown multi-junction cell in a spatially and spectrally separated waveguide that retains the simplicity of the monolithic multi-junction cell, while providing the benefits of spatial and spectral separation.
The geometry of a device such as shown in
Unlike prior art that seeks omnidirectional reflection across a broad wavelength region, the design of this dichroic filter stack 120 is specific to the mode angles used within the waveguide commensurate with the solar spectrum. This skews the angles of interest to those exceeding the critical angles within the waveguide. The waveguide design is also unique in that it minimizes dispersion across the solar spectrum when used in conjunction with the particular prism (material dispersion).
The specific geometry used within this integrated device, and the integration of the waveguide 102, filter 120, and photovoltaic structure 110 make this device unique. It is the only known multi-junction solar cell device that incorporates light concentration, filtering and band gap optimized photovoltaic conversion in one device. The device is producible via standard wafer fabrication techniques such as metal oxide chemical vapor deposition (MOCVD) and reactive ion etching (RIE).
Details of the construction of the dichroic filter stack are shown in the illustration below the main element. Alternatively, layers of TiO2 and SiO2 are provided with the illustrated thickness and indexes to provide the illustrated reflected spectral response (Wo±Wo/3). Here the thickness of the short wavelength absorbing region may need to be extended via a buffer layer 250 to match the thickness of the filter if the filter is thicker than the short wavelength absorbing region.
The electrical conversion devices (detectors) 105 can be discrete devices, one for every mirror element 130, or they can be designed to be continuous and defined by their electric contacts 133 as shown in
An enhanced version of this device can further include intrawaveguide elements that enable the spectral separation of light into different photodetectors operating in different bands.
A simulation of the waveguide incorporating both the TIR mirrors 130 and a nominal low Q multilayer dielectric filter shown generally in
HFSS simulations show that the light spectrum is selectively directed to the optimized detector via these intrawaveguide components.
The
In measurements taken of one embodiment adapted for optical signal detection (indoors), five discrete laser wavelengths (405 nm, 632 nm, 808 nm, 532 nm and 975 nm) having a maximum input angle of 0.35° resulted in an angle measurement accuracy of ±0.1° for a normalized beamwidth from 0.4 to 2.5°.
Note that a multi-layer waveguide may preferably be used as was described in
In another embodiment, one or more MIM rectennas 170 are placed vertically in series underneath the waveguide TIR mirror (as per
It was shown in a full-wave FEM simulation (HFSS) that the stacking of different bands of antennas in a vertical arrangement causes little effect on the other band. In
The MIM bowties could be arrayed periodically in x and y, and in z (separated by different layers or groups of layers corresponding to different frequency bands) as shown in
It can thus be understood that, in lieu of lateral spectral filtering along the waveguide as described above, vertical spectral filtering can be accomplished with the TIR mirror alone, and the filtering occurs naturally by the propagation of light through resonant arrayed MIM nantenna structures or even bandgap optimized multijunction solar cells.
The vertical array stack of
The teachings of all patents, published applications and references cited herein are incorporated by reference in their entirety.
While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
This application claims the benefit of a U.S. Provisional Patent Application Ser. No. 61/962,396 filed Nov. 6, 2013 entitled “MONOLITHICALLY INTEGRATED PLANAR BROADBAND WAVEGUIDE AND SOLAR PHOTODETECTOR”, and is also a continuation-in-part of copending U.S. patent application Ser. No. 14/078,755, entitled “WIDEBAND LIGHT ENERGY WAVEGUIDE AND DETECTOR” filed Nov. 13, 2013, which in turn claims the benefit of U.S. Patent Application 61/725,732, which was filed on Nov. 13, 2012, by Patricia Bodan et al. for a BASIC SOLAR CONCENTRATOR MODULE, commonly assigned U.S. Patent Application Ser. No. 61/756,524, which was filed on Jan. 25, 2013, by Patricia Bodan et al. for a WIDE SPECTRAL BANDWIDTH PRISM-COUPLED OPTICAL WAVEGUIDE WITH SPECTRAL FILTERING TO PHOTOVOLTAIC DEVICES, commonly assigned U.S. Patent Application Ser. No. 61/782,992, which was filed on Mar. 14, 2013, by Patricia Bodan et al. for a WIDE SPECTRAL BANDWIDTH PRISM-COUPLED OPTICAL WAVEGUIDE FOR PHOTOVOLTAIC DEVICES, and commonly assigned U.S. Patent Application Ser. No. 61/900,434, which was filed on Nov. 6, 2013, by Patricia Bodan et al. for a MONOLITHICALLY INTEGRATED PLANAR BROADBAND WAVEGUIDE AND SOLAR PHOTODETECTOR. The entire contents of each of the above-referenced patent applications are hereby incorporated by reference. Portions of this patent application may also relate to U.S. patent application Ser. No. 13/357,451 filed Jan. 24, 2012 entitled “Leaky Solar Array with Spatially Separated Solar Collectors”; the entire contents of which are also hereby incorporated by reference.
Number | Date | Country | |
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61962396 | Nov 2013 | US | |
61725732 | Nov 2012 | US | |
61756524 | Jan 2013 | US | |
61782992 | Mar 2013 | US | |
61900434 | Nov 2013 | US |
Number | Date | Country | |
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Parent | 14078755 | Nov 2013 | US |
Child | 14533614 | US |