Claims
- 1. Drive circuitry to provide a DC bias voltage and a high frequency modulation current to an electroabsorption modulator (EAM) which includes a first semiconductor type contact and a second semiconductor type contact, the drive circuitry comprising:
a first modulation lead configured to be coupled to the first semiconductor type contact of the EAM; and a second modulation lead configured to be coupled to an AC ground; a coupling capacitor including;
an EAM-side capacitor electrode electrically coupled to the second semiconductor type contact of the EAM; a non-EAM-side capacitor electrode electrically coupled to the AC ground; and a dielectric layer disposed between the EAM-side capacitor electrode and the non-EAM-side capacitor electrode; and a first DC lead electrically coupled to the EAM-side capacitor electrode and configured to be coupled to a first DC potential.
- 2. The drive circuitry of claim 1, further comprising:
a termination circuit including;
a first termination electrode electrically coupled to the first semiconductor type contact of the EAM; a second termination electrode configured to be coupled to a second DC potential; and a resistive layer disposed between the first termination electrode and the second termination electrode.
- 3. The drive circuitry of claim 1, wherein the AC ground includes a common potential.
- 4. The drive circuitry of claim 1, wherein:
the first semiconductor type contact of the EAM is an n contact; and the second semiconductor type contact of the EAM is a p contact.
- 5. The drive circuitry of claim 1, wherein:
the first semiconductor type contact of the EAM is a p contact; and the second semiconductor type contact of the EAM is an n contact.
- 6. A monolithic electroabsorption modulator (EAM) and coupling capacitor comprising:
a substrate with a top surface; a non-EAM-side capacitor electrode coupled to the top surface of the substrate; a capacitor dielectric layer coupled to the non-EAM-side capacitor electrode; an EAM-side capacitor electrode coupled to the capacitor dielectric layer; an EAM base layer formed of a first type semiconductor material and electrically coupled to the EAM-side capacitor electrode; an EAM waveguide formed on the EAM base layer and including an electroabsorption portion; an EAM second type semiconductor layer formed on the EAM waveguide; and an EAM electrode electrically coupled to the EAM second type semiconductor layer.
- 7. The monolithic EAM and coupling capacitor of claim 6, wherein:
the first type semiconductor material of the EAM base layer is an n-type semiconductor material; and the EAM second type semiconductor layer is an EAM p-type semiconductor layer.
- 8. The monolithic EAM and coupling capacitor of claim 6, wherein:
the first type semiconductor material of the EAM base layer is a p-type semiconductor material; and the EAM second type semiconductor layer is an EAM n-type semiconductor layer.
- 9. The monolithic EAM and coupling capacitor of claim 6, wherein:
the first type semiconductor material of the EAM base layer includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; the EAM waveguide includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; and the EAM second type semiconductor layer includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb.
- 10. The monolithic EAM and coupling capacitor of claim 6, wherein the electroabsorption portion of the EAM waveguide includes a plurality of electroabsorption sub-layers forming a quantum well structure.
- 11. The monolithic EAM and coupling capacitor of claim 6, wherein the electroabsorption portion of the EAM waveguide includes a bulk material.
- 12. The monolithic EAM and coupling capacitor of claim 6, wherein the capacitor dielectric layer includes at least one of: SiOx; SiNx; BaTiO3; SrTiO3; TiO2; Nb2O5; CoO; BaZrO3; PbZrO3; BaSnO3; PbSnO3; borosilicate glass frit; X7R; Z5U; Y5V; non-conductive epoxy; and non-conductive thermoplastic.
- 13. The monolithic EAM and coupling capacitor of claim 6, wherein:
the EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder; and the non-EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder.
- 14. The monolithic EAM and coupling capacitor of claim 6, wherein the substrate is formed of an intrinsic semi-insulating material.
- 15. The monolithic EAM and coupling capacitor of claim 6, further comprising:
a first termination contact formed on the top surface of the substrate; a resistive layer electrically coupled to the first termination contact; and a second termination contact electrically coupled to the resistive layer and the EAM electrode.
- 16. The monolithic EAM and coupling capacitor of claim 15, wherein the resistive layer is a surface resistor formed by a thick film process.
- 17. A monolithic electroabsorption modulator (EAM) and coupling capacitor comprising:
a substrate formed of a first type semiconductor material with a top surface and a bottom surface; an EAM-side capacitor electrode coupled to the bottom surface of the substrate; a capacitor dielectric layer coupled to the EAM-side capacitor electrode; a non-EAM-side capacitor electrode coupled to the capacitor dielectric layer; an EAM waveguide formed on the top surface of the substrate and including an electroabsorption portion; and an EAM second type semiconductor layer formed on the EAM waveguide.
- 18. The monolithic EAM and coupling capacitor of claim 17, wherein:
the first type semiconductor material of the substrate is an n-type semiconductor material; and the EAM second type semiconductor layer is an EAM p-type semiconductor layer.
- 19. The monolithic EAM and coupling capacitor of claim 17, wherein:
the first type semiconductor material of the substrate is a p-type semiconductor material; and the EAM second type semiconductor layer is an EAM n-type semiconductor layer.
- 20. The monolithic EAM and coupling capacitor of claim 17, wherein:
the first type semiconductor material of the substrate includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; the EAM waveguide includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; and the EAM second type semiconductor layer includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb.
- 21. The monolithic EAM and coupling capacitor of claim 17, wherein the electroabsorption portion of the EAM waveguide includes a plurality of electroabsorption sub-layers forming a quantum well structure.
- 22. The monolithic EAM and coupling capacitor of claim 17, wherein the electroabsorption portion of the EAM waveguide includes a bulk material.
- 23. The monolithic EAM and coupling capacitor of claim 17, wherein the capacitor dielectric layer includes at least one of: SiOx; SiNx; BaTiO3; SrTiO3; TiO2; Nb2O5; CoO; BaZrO3; PbZrO3; BaSnO3; PbSnO3; borosilicate glass frit; X7R; Z5U; Y5V; non-conductive epoxy; and non-conductive thermoplastic.
- 24. The monolithic EAM and coupling capacitor of claim 17, wherein:
the EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder; and the non-EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder.
- 25. The monolithic EAM and coupling capacitor of claim 17, further comprising:
a first termination contact formed on the top surface of the substrate; a resistive layer electrically coupled to the first termination contact; and a second termination contact electrically coupled to the resistive layer and the EAM electrode.
- 26. The monolithic EAM and coupling capacitor of claim 25, wherein the resistive layer is a surface resistor formed by a thick film process.
- 27. A method of manufacturing a monolithic electroabsorption modulator (EAM) and coupling capacitor, comprising the steps of:
a) providing a substrate formed of a first type semiconductor material with a top surface and a bottom surface; b) forming an EAM waveguide layer on the top surface of the substrate, the EAM waveguide layer including an electroabsorption portion; c) forming an EAM second type semiconductor layer on the EAM waveguide layer; d) etching the EAM second type semiconductor layer and the EAM waveguide layer to form an EAM second type semiconductor region and an EAM waveguide; e) forming an EAM-side capacitor electrode on the substrate; f) forming a capacitor dielectric layer electrically coupled to the EAM-side capacitor electrode; and g) forming a non-EAM-side capacitor electrode on the capacitor dielectric layer.
- 28. The method of claim 27, wherein:
step (e) includes the step of forming the EAM-side capacitor electrode on the bottom surface of the substrate; and step (f) includes the step of forming the capacitor dielectric layer on the EAM-side capacitor electrode.
- 29. The method of claim 27, wherein:
step (e) includes the step of forming the EAM-side capacitor electrode on a portion of the top surface of the substrate; and step (f) includes the step of forming the capacitor dielectric layer on the EAM-side capacitor electrode.
- 30. The method of claim 27, wherein:
step (e) includes the step of forming the EAM-side capacitor electrode on a portion of the top surface of the substrate; and step (f) includes the step of forming the capacitor dielectric layer on the bottom surface of the substrate.
- 31. The method of claim 27, wherein step (d) further includes the step of forming an insulating layer on portions of the substrate exposed by etching the EAM waveguide layer.
- 32. The method of claim 27, wherein:
step (b) includes the step of growing the EAM waveguide layer using an epitaxial technique.
- 33. The method of claim 32, wherein the epitaxial technique is at least one of: liquid phase epitaxy; metal organic chemical vapor deposition; molecular beam epitaxy; and chemical beam epitaxy.
- 34. The method of claim 27, wherein:
step (b) includes the step of forming a plurality of EAM waveguide sub-layers to form a quantum well structure.
- 35. The method of claim 27, wherein:
step (d) includes the step of etching the EAM second type semiconductor layer and the EAM waveguide layer using a dry anisotropic etch technique.
- 36. The method of claim 27, wherein:
step (f) includes the step of forming the capacitor dielectric layer using thin film deposition.
- 37. A monolithic electroabsorption modulator (EAM) and coupling capacitor comprising:
a substrate including a first type semiconductor material portion, the first type semiconductor material portion having a top surface; an EAM electrode electrically coupled to the first type semiconductor material portion of the substrate; an EAM waveguide formed on the top surface of the first type semiconductor material portion of the substrate and including an electroabsorption portion; an EAM second type semiconductor layer formed on the EAM waveguide; an EAM-side capacitor electrode electrically coupled to the EAM second type semiconductor layer; a capacitor dielectric layer formed on the EAM-side capacitor electrode; and a non-EAM-side capacitor electrode formed on the capacitor dielectric layer.
- 38. The monolithic EAM and coupling capacitor of claim 37, wherein:
the first type semiconductor material portion of the substrate is an n-type semiconductor material; and the EAM second type semiconductor layer is an EAM p-type semiconductor layer.
- 39. The monolithic EAM and coupling capacitor of claim 37, wherein:
the first type semiconductor material portion of the substrate is a p-type semiconductor material; and the EAM second type semiconductor layer is an EAM n-type semiconductor layer.
- 40. The monolithic EAM and coupling capacitor of claim 37, wherein:
the first type semiconductor material portion of the EAM base layer includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; the EAM waveguide includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb; and the EAM second type semiconductor layer includes at least one of: GaAs; InP; InGaAsP; AlGaAs; and InSb.
- 41. The monolithic EAM and coupling capacitor of claim 37, wherein the electroabsorption portion of the EAM waveguide includes a plurality of electroabsorption sub-layers forming a quantum well structure.
- 42. The monolithic EAM and coupling capacitor of claim 37, wherein the electroabsorption portion of the EAM waveguide includes a bulk material.
- 43. The monolithic EAM and coupling capacitor of claim 37, wherein the capacitor dielectric layer includes at least one of: SiOx; SiNx; BaTiO3; SrTiO3; TiO2; Nb2O5; CoO; BaZrO3; PbZrO3; BaSnO3; PbSnO3; borosilicate glass frit; X7R; Z5U; Y5V; non-conductive epoxy; and non-conductive thermoplastic.
- 44. The monolithic EAM and coupling capacitor of claim 37, wherein:
the EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder; and the non-EAM-side capacitor electrode includes at least one of: aluminum, gold, silver, copper, nickel, titanium, tungsten, platinum, germanium, polyaniline, polysilicon, indium, conductive epoxy, and solder.
- 45. The monolithic EAM and coupling capacitor of claim 37, further comprising:
a first termination contact formed on the top surface of the substrate; a resistive layer electrically coupled to the first termination contact; and a second termination contact electrically coupled to the resistive layer and the EAM electrode.
- 46. The monolithic EAM and coupling capacitor of claim 45, wherein the resistive layer is formed by a thick film process.
- 47. A method of manufacturing a monolithic electroabsorption modulator (EAM) and coupling capacitor, comprising the steps of:
a) providing a substrate including a first type semiconductor material portion, the first type semiconductor material portion having a top surface; b) forming an EAM waveguide layer on the top surface of the first type semiconductor material portion of the substrate, the EAM waveguide layer including an electroabsorption portion; c) forming an EAM second type semiconductor layer on the EAM waveguide layer; d) etching the EAM second type semiconductor layer and the EAM waveguide layer to form an EAM second type semiconductor region and an EAM waveguide; e) forming an EAM electrode on the first type semiconductor material portion of the substrate; f) forming an EAM-side capacitor electrode on the EAM second type semiconductor region; g) forming a capacitor dielectric layer on the EAM-side capacitor electrode; and h) forming a non-EAM-side capacitor electrode on the capacitor dielectric layer.
- 48. The method of claim 47, wherein step (d) further includes the step of forming an insulating layer on portions of the substrate exposed by etching the EAM waveguide layer.
- 49. The method of claim 47, wherein:
step (b) includes the step of growing the EAM waveguide layer using an epitaxial technique.
- 50. The method of claim 49, wherein the epitaxial technique is at least one of: liquid phase epitaxy; metal organic chemical vapor deposition; molecular beam epitaxy; and chemical beam epitaxy.
- 51. The method of claim 47, wherein:
step (b) includes the step of forming a plurality of EAM waveguide sub-layers to form a quantum well structure.
- 52. The method of claim 47, wherein:
step (d) includes the step of etching the EAM second type semiconductor layer and the EAM waveguide layer using a dry anisotropic etch technique.
- 53. The method of claim 47, wherein:
step (g) includes the step of forming the capacitor dielectric layer using thin film deposition.
- 54. The method of claim 47, wherein step (g) includes the steps of:
g1) applying a layer of a viscous non-conductive liquid; and g2) curing the viscous non-conductive liquid to form the capacitor dielectric layer.
- 55. The method of claim 47, further comprising the steps of:
i) forming a first termination contact on the top surface of the first type semiconductor material portion of the substrate; j) forming a resistive layer on the first termination contact; and k) forming a second termination contact on the resistive layer.
- 56. The method of claim 55, wherein:
step (j) includes the step of forming the resistive layer using thin film deposition.
- 57. A method of manufacturing a monolithic co-sided electroabsorption modulator (EAM) and coupling capacitor, comprising the steps of:
a) providing a non-conducting substrate with a top surface; b) forming a co-sided EAM on the top surface of the non-conducting substrate, formation of the co-sided EAM including the steps of;
b1) forming an EAM first type base layer with a top surface on the top surface of the non-conducting substrate; b2) forming an EAM waveguide layer on the EAM first type base layer, the EAM waveguide layer including an electroabsorption portion; b3) forming an EAM second type semiconductor layer on the EAM waveguide layer; and b4) etching the EAM second type semiconductor layer and the EAM waveguide layer to form an EAM second type semiconductor region and EAM waveguide and expose at least one side portion of the top surface of the EAM first type base layer; b5) forming an EAM insulating layer on the at least one side portion of the top surface of the EAM first type base layer; b6) etching the EAM insulating layer to expose at least one contact region of the at least one side portion of the top surface of the EAM first type base layer; and c) forming at least one capacitor on the top surface of the non-conducting substrate, formation of each capacitor including the steps of;
c1) forming a non-EAM-side capacitor electrode on the top surface of the non-conducting substrate; c2) forming a capacitor dielectric layer on the non-EAM-side capacitor electrode; and c3) forming an EAM-side capacitor electrode on the capacitor dielectric layer.
- 58. The method of claim 57, wherein:
step (b2) includes the step of growing the EAM waveguide layer using an epitaxial technique.
- 59. The method of claim 58, wherein the epitaxial technique is at least one of: liquid phase epitaxy; metal organic chemical vapor deposition; molecular beam epitaxy; and chemical beam epitaxy.
- 60. The method of claim 57, wherein:
step (b2) includes the step of forming a plurality of EAM waveguide sub-layers to form a quantum well structure.
- 61. The method of claim 57, wherein:
step (b4) includes the step of etching the EAM second type semiconductor layer and the EAM waveguide layer using a dry anisotropic etch technique.
- 62. The method of claim 57, wherein:
step (c2) includes the step of forming the capacitor dielectric layer using thin film deposition.
- 63. The method of claim 57, further comprising the steps of:
d) forming a termination on the top surface of the non-conducting substrate;
d1) forming a first termination contact on the top surface of the non-conducting substrate; d2) forming a resistive layer coupled to the first termination contact; and d3) forming a second termination contact coupled the resistive layer.
- 64. The method of claim 63, wherein:
step (d2) includes the step of forming the resistive layer on the top surface of the non-conducting substrate using thin film deposition; and step (d3) includes the step of forming the second termination contact on the top surface of the non-conducting substrate.
- 65. The method of claim 63, wherein:
step (d2) includes the step of forming the resistive layer on the first termination contact using thin film deposition.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the benefit of U.S. Provisional Application No. 60/348,179, filed Oct. 23, 2001, the contents of which are incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60348179 |
Oct 2001 |
US |