METHOD AND APPARATUS FOR A LOW PARASITIC CAPACITANCE BUTT-JOINED PASSIVE WAVEGUIDE CONNECTED TO AN ACTIVE STRUCTURE
Undoped layers are introduced in the passive waveguide section of a butt-joined passive waveguide connected to an active structure. This reduces the parasitic capacitance of the structure.
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This is a Divisional of copending application Ser. No. 10/944,326, filed on Sep. 17, 2004, the entire disclosure of which is incorporated herein by reference.
BACKGROUNDTypical methods to fabricate a butt-joined passive waveguide structure involves etching past the active region of the active device to grow the desired waveguide.
However, when attempting to make a low parasitic electro-absorption (EA) modulator with passive waveguide there is an optimization problem because the parasitic capacitance value is determined by the thickness of passive Q-waveguide core 190. As noted above, the thickness of passive Q-waveguide core 190 is constrained by mode matching issues. These issues typically arise when a passive waveguide needs to be butt joined to an active device requiring low parasitic capacitance such as is typically required in making optical integrated structures.
SUMMARY OF INVENTIONIn accordance with the invention, passive Q waveguides are butt-joined to active EA modulators with low parasitic capacitance. While passive-Q waveguide core thickness is still important for minimizing mode mismatch losses, an extra degree of freedom is introduced by sandwiching a passive Q-waveguide between two undoped layers of InP to allow passive Q-waveguide core thickness independent reduction of parasitic capacitance.
SiO2/Si3N4 mask 295 is then defined over part of p-InP layer 230.
The use of undoped InP layer 280 and undoped InP layer 285 increases the depletion region thickness and the application of a reverse bias, typically about −0.5 to −3 volts, results in reduced parasitic capacitance. Depending on the size of parasitic capacitance that is acceptable for a given application, the thickness of undoped InP layers 280 and 285 may be suitably adjusted. Parasitic capacitance can typically drop to about 35 percent if undoped InP cladding layers 280 and 285 are the same thickness as SCH layers 245, 255 and active region 250 together, for example.
The thickness and composition of passive Q-waveguide core 290 may be optimized to achieve a good mode match with active EA modulator structure 299 resulting in the parasite capacitance due to passive section 298 being reduced in some embodiments in accordance with the invention from about 50 percent to about 10 percent. Note that while this embodiment is discussed with respect to an active EA modulator structure, in accordance with the invention, the active region described may also be the active region of a laser or a receiver, for example. Mode matching typically requires that, first, the axis of symmetry of passive Q-waveguide core 290 and the axis of symmetry for active region 250 are the same distance from substrate 210 and, second, that the optical modes in passive Q-waveguide core 290 and active region 250 be as matched to each other in spatial extent as possible. The second requirement is typically expressed by requiring the overlap integral between the two mode field distributions to be as close to unity as possible.
The cross-sectional dimensions of an active device such as EA modulator structure 299 are typically determined by the performance required. The choice for the cross-sectional dimensions determines the size of the optical mode. The cross-sectional dimensions and the composition of the passive section, such as passive Q-waveguide core 290, are adjusted to maximize the overlap integral. For buried heterostructures, the lateral dimensions of passive section 298 and active EA modulator structure 299, for example, are defined by a single mesa etch resulting in one width for both passive section 298 and active EA modulator structure 299. The height for passive section 298 needs to be selected so that the resulting mode is at the same height as the mode in active EA modulator structure 299. Because the mode size in general depends on the refractive index as well as the thickness of passive Q-waveguide core 290, a quaternary composition for passive Q-waveguide core 290 may be selected whose band-gap energy is larger than the energy corresponding to the propagating wavelength, for example, 1550 nm. In this case, quaternary composition refers to InxGa1-xAsyP1-y where the x and y values determine the band-gap energy of the particular quaternary composition. The thickness and composition of passive Q-waveguide core 290 assures that the mode sizes match across the interface between the passive waveguide section 298 and the active EA modulator structure 299. The selected composition typically depends on a number of factors. For the purposes of aligning the axes of symmetry of passive Q-waveguide core 290 and of active region 250, the quaternary composition of passive Q-waveguide core 290 is typically selected closer to 1400 nm so that the mode size is slightly larger than the thickness of active region 250. In an embodiment in accordance with the invention, the quaternary composition of passive Q-waveguide core 290 is selected to correspond to 1300 nm. To reduce optical absorption losses, the wavelength corresponding to the band-gap energy of passive Q-waveguide core 290 is typically selected via the quaternary composition to typically be at least 100 nm less than the propagating wavelength, for example, 1550 nm. If the quaternary composition is chosen to have a band-gap energy closer to about 1100 nm, the passive Q-waveguide comprised of passive Q-waveguide core and cladding layers 280 and 285 would be dilute, requiring a thicker passive Q-waveguide core 290 to achieve the correct mode size. This results in a larger thickness difference between passive Q-waveguide core 290 and active region 250. If this approach creates problems in mesa etching and burying epitaxial growth steps the quaternary composition of passive Q-waveguide core 290 may be suitably modified so that the overlap integral is maximized.
The invention is applicable to any situation where a small parasitic capacitance is needed from a butt-joined passive waveguide. Hence, the invention is generally applicable to the building of optical integrated structures. Additionally, the invention is applicable to other III-V semiconductor systems where similar problems of reduced parasitic capacitance arise such as embodiments of 40 Gb receivers, modulators or lasers.
While the invention has been described in conjunction with specific embodiments, it is evident to those skilled in the art that many alternatives, modifications, and variations will be apparent in light of the foregoing description. Accordingly, the invention is intended to embrace all other such alternatives, modifications, and variations that fall within the spirit and scope of the appended claims.
Claims
1. An active-passive butt-joint structure for reduced parasitic capacitance comprising:
- a III-V substrate;
- an active structure disposed over said substrate comprised of an active region sandwiched between two separate confinement heterostructure layers; and
- a passive butt-joint structure comprised of a passive Q-waveguide core sandwiched between two undoped III-V layers, said passive butt-joint structure disposed over said substrate and aligned adjacent to said active structure such that said active region is adjacent to said passive Q-waveguide core.
2. The structure of claim 1 wherein said undoped III-V layers are comprised of InP.
3. The structure of claim 1 wherein said substrate is comprised of N-InP.
4. The structure of claim 1 wherein a first thickness of each said two undoped III-V layers is adjusted to control parasitic capacitance.
5. The structure of claim 1 wherein said active structure comprises an EA-modulator.
6. The structure of claim 1 wherein a second thickness of said passive Q-waveguide core is selected to achieve a good mode match to said active region.
7. The structure of claim 1 wherein a composition of said passive Q-waveguide core is selected to achieve a good mode match to said active region.
8. The structure of claim 1 wherein said active structure comprises a laser.
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Type: Application
Filed: Mar 11, 2008
Publication Date: Jul 3, 2008
Applicant: AVAGO TECHNOLOGIES FIBER IP (SINGAPORE) PTE. LTD. (Singapore)
Inventors: Tirumala R. Ranganath (Palo Alto, CA), Jintian Zhu (Palo Alto, CA)
Application Number: 12/046,410
International Classification: H01S 3/00 (20060101); G02F 1/01 (20060101);