Nanophotonic integrated circuit and fabrication thereof

US 20060158230A1
Filed: 01/19/2006
Published: 07/20/2006
Est. Priority Date: 10/24/2002
Status: Active Grant

First Claim

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1. A nanophotonic integrated circuit comprising:

an input section, an amplifier section and a multiplexing/demultiplexing unit arranged on a substrate;

the input section having a plurality of input waveguides, a coupler portion for coupling two of the plurality of input waveguides to the amplifier section, and the remaining input waveguides being connected to the multiplexing/demultiplexing, the amplifier section having a continuous folded waveguide connected at a first end to the coupler portion of the input waveguide and connected at a second end to the multiplexing/demultiplexing unit;

the multiplexing/demultiplexing unit having a plurality of input/output waveguides, a slab waveguide, an array waveguide, and a reflective mirror;

the plurality of input/output waveguides arranged for simultaneously inputting at least one signal to and outputting at least one signal for demultiplexing a multiplexed optical signal in to n different constituent wavelengths and for combining n input optical signals composed of n different constituent wavelengths in to a multiplexed signal;

a slab waveguide having a first end and a second end, the first end coupled to the plurality of input/output waveguides to focus the at least one input signal to the second end, and the second end coupled to an array waveguide, for focusing the at least one output signal to the input/output interface through the first end;

the array waveguide comprising a plurality of waveguides for coupling the one or more input signals, separating the one or more input signals into the n different constituent wavelengths and focusing the n different constituent wavelengths back on to the slab waveguide first end coupling to the input/output interface, the plurality of waveguides of the array waveguide being optically coupled at one end with the second end of the slab waveguide, and terminated at an opposing end of the array waveguide by a reflective mirror, each waveguide of said array waveguide having a predetermined path difference between successive waveguides, and a reflective mirror disposed at the opposing end of the array waveguide for reflecting the one or more signals.

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Abstract

A class of nanophotonic integrated circuit (nPIC) has been disclosed that is a platform technology for fiberoptic communication and computing, that is fabricated from waveguides that are based on natural index contrast (NIC) principle. A multifunctional nPIC and its fabrication details have been described. The nPIC is also known as an “optical processor”. A novel nanomaterial “dendrimer” is highlighted as the key ingredient that enables the fabrication of the nPICs and its multifunctionality from the same basic process. Other nanomaterials such as spin-on glass, nano-silica sol, and a combination of any of these materials can also be used via the natural index contrast method. Several preferred embodiments of the nPIC are described.

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23 Claims

1. A nanophotonic integrated circuit comprising:
- an input section, an amplifier section and a multiplexing/demultiplexing unit arranged on a substrate;
  
  the input section having a plurality of input waveguides, a coupler portion for coupling two of the plurality of input waveguides to the amplifier section, and the remaining input waveguides being connected to the multiplexing/demultiplexing, the amplifier section having a continuous folded waveguide connected at a first end to the coupler portion of the input waveguide and connected at a second end to the multiplexing/demultiplexing unit;
  
  the multiplexing/demultiplexing unit having a plurality of input/output waveguides, a slab waveguide, an array waveguide, and a reflective mirror;
  
  the plurality of input/output waveguides arranged for simultaneously inputting at least one signal to and outputting at least one signal for demultiplexing a multiplexed optical signal in to n different constituent wavelengths and for combining n input optical signals composed of n different constituent wavelengths in to a multiplexed signal;
  
  a slab waveguide having a first end and a second end, the first end coupled to the plurality of input/output waveguides to focus the at least one input signal to the second end, and the second end coupled to an array waveguide, for focusing the at least one output signal to the input/output interface through the first end;
  
  the array waveguide comprising a plurality of waveguides for coupling the one or more input signals, separating the one or more input signals into the n different constituent wavelengths and focusing the n different constituent wavelengths back on to the slab waveguide first end coupling to the input/output interface, the plurality of waveguides of the array waveguide being optically coupled at one end with the second end of the slab waveguide, and terminated at an opposing end of the array waveguide by a reflective mirror, each waveguide of said array waveguide having a predetermined path difference between successive waveguides, and a reflective mirror disposed at the opposing end of the array waveguide for reflecting the one or more signals.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18)
- - 2. The nanophotonic integrated circuit of claim 1, wherein also includes an external array interface portion attached to the input section, for connecting external fibers for input and output of signals to the nPIC.
  - 3. The nanophotonic integrated circuit of claim 1, wherein the external array interface portion is precisely aligned to the input section and fixed to a side of the nanophotonic integrated circuit as part of a packaged module.
  - 4. The nanophotonic integrated circuit of claim 1, wherein the amplifier section having a core comprised of a dendrimer material doped with amplifying ions.
  - 5. The nanophotonic integrated circuit of claim 4, wherein the amplifying ions are selected from the group consisting of Er³⁺, Yt³⁺ and similar rare earth ions.
  - 6. The nanophotonic integrated circuit of claim 1, wherein the continuous folded waveguide is composed of a plurality of straight segments and a plurality of curved segments, wherein the curved segments have a predetermined minimum radius of curvature.
  - 7. The nanophotonic integrated circuit of claim 6, wherein R is in the range of about 1 to 6 millimeters for dendrimer polymeric material and from about 4 to 5 mm for glassy materials.
  - 8. The nanophotonic integrated circuit of claim 1, wherein each waveguide of the array waveguide is tapered at one end adjacent to the reflective mirror to couple light into and out of the array waveguide.
  - 9. The nanophotonic integrated circuit of claim 8, wherein each waveguide of the array waveguide is tapered at an opposing end adjacent to the slab waveguide.
  - 10. The nanophotonic integrated circuit of claim 1, also including a modulator array portion comprised of at least one modulator configured to modulate at least one input/output signals from the input/output waveguides, the modulator array being connected between the input/output waveguides and the multiplexing/demultiplexing unit.
  - 11. The nanophotonic integrated circuit of claim 10, wherein the at least one modulator of the modulator array portion is an electro-optic phase modulator configured so that an electric excitation can be applied across the modulator over a predetermined length.
  - 12. The nanophotonic integrated circuit of claim 11, wherein the electro-optic phase modulator includes a top electrode and a bottom electrode, the separation between the top and the bottom electrodes being within a range of about 2 to 8 microns.
  - 13. The nanophotonic integrated circuit of claim 10, wherein the at least one modulator of the modulator array portion is a Mach-Zehnder (MZ) structure, wherein each MZ structure includes a pair of phase modulators arranged in parallel to produce amplitude modulation.
  - 14. The nanophotonic integrated circuit of claim 10, wherein the modulators of the modulator array portion have a transmittance that can be controlled from a minimum power P_minto a maximum power P_max, and output power, P_out, can be controlled by the applied voltage V according to the following equation:
  - 15. The nanophotonic integrated circuit of claim 10, wherein the modulator array portion is comprised of a combination of electro-optic phase modulators and MZ amplitude modulators.
  - 16. The nanophotonic integrated circuit of claim 10, wherein the modulator array portion is comprised of a plurality of MZ amplitude modulators, each MZ amplitude modulator corresponding to an output channel of the integrated circuit.
  - 17. The nanophotonic integrated circuit of claim 1, wherein the input section, amplifier section and multiplexing/demultiplexing unit are comprised of a PAMAM dendrimer material suitable for guiding light in the range of approximately 1000 to 1600 nanometer range, the PAMAM dendrimer being selected from the group consisting of generation zero through generation 10.
  - 18. The nanophotonic integrated circuit of claim 1, wherein the input section, amplifier section and multiplexing/demultiplexing unit are comprised of PAMAMOS dendrimer material suitable for guiding light in the range of approximately 1000 to 1600 nanometer range, the PAMAMOS dendrimer being selected from the group consisting of generation zero through generation 10.

19. A nanophotonic integrated circuit comprising:
- an input section, an amplifier section and a splitter section arranged on a substrate;
  
  the input section configured to connect an input signal to the amplifier section, the amplifier section being configured to amplify the input signal and transmit the amplified input signal into an input of the splitter section; and
  
  the splitter section is coupled to a plurality of output channels configured to split the amplified input signal into a plurality of output signals of N branches.
- View Dependent Claims (20)
- - 20. The nanophotonic integrated circuit of claim 19, also including a modulator section, wherein the modulator section is configured to modulate the plurality of output signals.

21. A method for tuning the wavelength ranges for amplification in an optical circuit, comprising:
- doping a dendrimer material with at least one of a preselected rare-earth ion;
  
  dissolving a salt of the preselected rare earth ion in a solution of the dendrimer and methanol; and
  
  amplifying light waves in a range which is characterized by the the 1500-1600 nm range.
- View Dependent Claims (22, 23)
- - 22. The method of claim 21, wherein the dendrimer is doped by using concentrations of Er³⁺, in the range of about 200 ppm to about 40,000 ppm.
  - 23. The method of claim 21, wherein the rare earth ions are selected from the group consisting of Erbium for amplify light waves in the 1500-1600 nm range, Neodymium (Nd³⁺) for amplifying light waves in the 1060 nm range, Praseodymium (Pr³⁺) for amplifying light waves in the 1250-1300 nm range, Thorium (Th³⁺) for amplifying light waves in the 1300-1400 nm range. Holmium (Ho³⁺) for amplifying light waves in the 1300-1400 nm range, and Terbium (Tb³⁺) for amplifying light waves in the 1400-1500 nm range.

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Current Assignee
Applied Research And Photonics, Inc.
Original Assignee
Applied Research And Photonics, Inc.
Inventors
Rahman, Anis

Granted Patent

US 7,412,121 B2
Time in Patent Office

Days
Field of Search
US Class Current

327/89
CPC Class Codes

G02B 6/12011   characterised by the arraye...

G02B 6/1221   made from organic materials

H01S 3/0637   Integrated lateral waveguid...

H01S 3/1608   erbium

H01S 3/17   amorphous, e.g. glass

Nanophotonic integrated circuit and fabrication thereof

First Claim

1 Assignment

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Abstract

35 Citations

23 Claims

Specification

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Nanophotonic integrated circuit and fabrication thereof

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

35 Citations

23 Claims

Specification

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Solutions

Use Cases

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