1. Field of the Invention
The present invention relates to an electro-absorption semiconductor optical modulator.
2. Related Background Art
Publication 1 (Japanese Patent Application Laid Open No. 2003-255286) discloses an electro-absorption modulator. This electro-absorption modulator has an interlayer provided between a well layer and a barrier layer, and the interlayer is located on the n-side of the barrier layer, and tensile strain is applied to the well layer. The bandgap Eb (eV) of the barrier layer, the bandgap Ew (eV) of the well layer and the bandgap Em (eV) of the interlayer layer satisfy the following relationship: Ew<E m<Eb. The electro-absorption modulator of a tensile-strained quantum well structure with an interlayer has an extinction ratio equivalent to that of the same as an electro-absorption modulator (comparative example) of a tensile-strained quantum well structure without an interlayer, and has a chirp characteristics lower than that of the comparative example. The electro-absorption modulator in publication 1 reduces the chirping without the deterioration of its extinction ratio. This reduction of the chirping is provided by small positive alpha parameters and negative alpha parameters. Publication 1 discloses that, if an electro-absorption modulator has a tensile-strained quantum well structure, its chirp characteristics is lowered without the deterioration of the extinction ratio thereof.
Publication 1 discloses that the application of voltage changes the alpha parameter to a small positive value, and the application of a larger voltage changes the alpha parameter to a large negative value.
Publication 1 discloses that the tensile-strained quantum well structure is a promising structure for low chirping characteristics, and many researcher have thought that low chirping characteristics are easily realized in tensile-strained quantum well structures as compared with compressive-strained quantum well structures. That is, they have thought that alpha parameters in compressive-strained quantum well structures are not changed to small positive and negative large values even if the applied voltage is widely changed.
In order to reduce alpha parameters, the following methods are used: (1) well layers are made shallow with reference to barrier layers; (2) well layers are made thick in thickness; (3) an absorption edge is made close to the wavelength of an input optical signal. In method (1), the extinction ratio is lowered; in method (2), a burden is posed on crystal growth; in method (3), loss to signals of level “1” is increased.
The present invention is made in the circumstances described above, and is obtained through a trial and error process.
It is an object to provide an electro-absorption semiconductor optical modulator that reduces the chirping and avoids the degradation of extinction ratio.
According to one aspect of the present invention, an electro-absorption semiconductor optical modulator comprises an n-type cladding layer of III-V compound semiconductor, a p-type cladding layer of III-V compound semiconductor, and an active region. The active region is provided between the n-type cladding layer and the p-type cladding layer, and has a quantum well structure. The quantum well structure includes plural semiconductor units, each of which has a well layer, a barrier layer and an interlayer. The interlayer is made of material of a bandgap between a bandgap of the well layer and a bandgap of the barrier layer, and the well layer is compressively strained. In each semiconductor unit, the well layer, interlayer and barrier layer are sequentially arranged in a direction from the p-type cladding layer to the n-type cladding layer.
In the electro-absorption semiconductor optical modulator according to the present invention, it is preferable that the quantum well structure be strain-compensated. In the electro-absorption semiconductor optical modulator according to the above case, it is preferable that the interlayer be strain free.
In the electro-absorption semiconductor optical modulator according to the present invention, in a energy band diagram of the quantum well structure, the band edge of light hole of the well layer is located between the band edge of heavy hole of the well layer and the band edge of hole of the interlayer. Further, in the electro-absorption semiconductor optical modulator according to the present invention, the well layer is made of GaInAsP, the barrier layer is made of GaInAsP, and the interlayer is made of GaInAsP.
In the electro-absorption semiconductor optical modulator according to the present invention, the electro-absorption semiconductor optical modulator is integrated with a semiconductor laser; and the electro-absorption semiconductor optical modulator modulates light from the semiconductor laser. Further, in the electro-absorption semiconductor optical modulator according to the present invention, compressive strain is applied to a well layer of the semiconductor laser. Furthermore, in the electro-absorption semiconductor optical modulator according to the present invention, the semiconductor laser has a quantum well structure. The quantum well structure of the semiconductor laser includes plural semiconductor units. Each semiconductor unit of the semiconductor laser has a well layer, a barrier layer and an interlayer. The interlayer is made of material of a bandgap between a bandgap of the well layer and a bandgap of the barrier layer in the semiconductor laser. The well layer is compressively strained in the semiconductor laser, and the well layer, interlayer and barrier layer are sequentially arranged in each semiconductor unit of the semiconductor laser in a direction from the p-type cladding layer to the n-type cladding layer. Additionally, in the electro-absorption semiconductor optical modulator according to the present invention, in the semiconductor laser, the well layer is made of GaInAsP, the barrier layer is made of GaInAsP, and the interlayer is made of GaInAsP.
In the electro-absorption semiconductor optical modulator according to the present invention, the semiconductor laser has a quantum well structure, and the quantum well structure of the semiconductor laser is optically coupled to the quantum well structure of the electro-absorption semiconductor optical modulator semiconductor laser in a butt joint. In the electro-absorption semiconductor optical modulator according to the present invention, the quantum well structure of the semiconductor laser includes well layers and barrier layers alternately arranged. Furthermore, in the electro-absorption semiconductor optical modulator according to the present invention, in the semiconductor laser, each well layer is made of GaInAsP, and each barrier layer is made of GaInAsP.
In the electro-absorption semiconductor optical modulator according to the present invention, the interlayer is located on an n-side of the well layer in each semiconductor unit, and the n-side of the well layer is directed to the n-type cladding layer. Further, in the electro-absorption semiconductor optical modulator according to the present invention, the interlayer in one of the semiconductor units is located between the well layer in the one of the semiconductor units and the barrier layer in another of the semiconductor units. The one of the semiconductor units and the other of the semiconductor units are adjacent to each other, and the one of the semiconductor units is provided between the p-type cladding layer and the other of the semiconductor units.
In the electro-absorption semiconductor optical modulator according to the present invention, the barrier layer is located on a p-side of the well layer in each semiconductor unit. The p-side of the well layer is directed to the p-type cladding layer, and the well layer is located between the barrier layer and the interlayer in each semiconductor unit. Further, in the electro-absorption semiconductor optical modulator according to the present invention, the barrier layer in one of the semiconductor units is located between the well layer in the one of the semiconductor units and the interlayer in another of the semiconductor units, the one of the semiconductor units and the other of the semiconductor units are adjacent to each other, and the one of the semiconductor units is provided between the n-type cladding layer and the other of the semiconductor units.
In the electro-absorption semiconductor optical modulator according to the present invention, a wave function of electron in a conduction band in the well layer is deformed to spread in the well layer and interlayer in response to a reverse voltage applied to the active region. Further, in the electro-absorption semiconductor optical modulator according to the present invention, a wave function of heavy hole in a valence band in the well layer is deformed to localize in the well layer in response to the reverse voltage.
In the electro-absorption semiconductor optical modulator according to the present invention, the plural semiconductor units are arranged in a direction from the p-type cladding layer to the n-type cladding layer. Further, in the electro-absorption semiconductor optical modulator according to the present invention, the barrier layer has tensile strain and the interlayer is strain free.
The above objects and other objects, features, and advantages of the present invention will be understood easily from the following detailed description of the preferred embodiments of the present invention with reference to the accompanying drawings.
Referring to the accompanying drawings, embodiments of the present invention will be explained. When possible, parts identical to each other will be referred to with symbols identical to each other.
Part (a) of
In the electro-absorption semiconductor optical modulator 11, negative voltage is applied to anode electrode and positive voltage is applied to cathode electrode. Thus, the pn junction in the electro-absorption semiconductor optical modulator 11 is reversely biased. Part (b) of
The well layer 23a, interlayer 23b and barrier layer 23c are arranged as above in the electro-absorption semiconductor optical modulator 11, that is, the interlayer 23b is provided on the n-side, which is directed to the n-type cladding layer, of the well layer 23a. Thus, the confinement of the wave function of electron in the conduction band into the well layer 23a is weakened in applying a reverse bias, and the peak of the wave function φE is shifted toward the interlayer 23b. Hence, the wave function φE is broadened in the well layer 23a and the interlayer 23b to reduce the peak value of the wave function φE. In contrast, since the interlayer 23b is not provided on the other side, which is directed to the p-type cladding layer, of the well layer 23a, the wave function φHH is shifted by moving the heavy holes in response to a reverse bias in a direction opposite to the moving direction of electron in the conduction band. Accordingly, the wave function φHH is localized and the peak value of the wave function φHH is not decreased. Consequently, the overlap of the wave functions φE and φHH is decreased as a whole to reduce the absorption of the incident light in a short wavelength region. Therefore, the alpha parameter is made negative, and the chirping characteristics become excellent. If the well layer 23a is compressively strained, the alpha parameter is shifted to a negative value.
Referring again to
In the electro-absorption semiconductor optical modulator 11 shown in
It is preferable that the quantum well structure 21 be strain-compensated. In the electro-absorption semiconductor optical modulator 11 that is strain-compensated, the well layers have compressive strains and this strain-compensation permits the crystal quality of the active region to become excellent. The quantum well structure 21 shown in Part (a) of
It is preferable that the interlayer 23b be strain-free. Accordingly, the strain relation of the quantum well structure does not become complicated, and rather simple. The band structure 21 shown in Part (a) of
In one example of the electro-absorption semiconductor optical modulator 11, the well layer 23a is made of GaInAsP, the barrier layer is made of GaInAsP, and the interlayer is made of GaInAsP. According to the above example of the electro-absorption semiconductor optical modulator 11, it is easy to obtain both the relation of strains and the relation of bandgaps by changing the compositions of the well layer, interlayer and barrier layer.
Part (a) of
Parts (a) to (d) of
Parts (a) to (d) of
In the semiconductor laser 51, a semiconductor mesa 75 includes the n-type cladding layer 13, p-type cladding layer 55 and the active region 57. A third optical guide layer 67 is provided between the n-type cladding layer 13 and the active region 57, and fourth optical guide layer 69 is provided between the p-type cladding layer 55 and the active region 57. The semiconductor mesa 75 is buried by a burying region 33, electrical current flowing from the anode electrode to the cathode electrode is effectively confined into the active region 57. The semiconductor mesa 75 and the burying region 33 are provided on the primary surface 35a of the semiconductor substrate 35. The cladding layer 37 is provided on the semiconductor mesa 75 and the burying region 33. A contact layer 71 is provided on the cladding layer 37. The contact layer 71 is made of the same material of the contact layer 39, and is isolated from the contact layer 39. A third electrode 73 is provided on the contact layer 71, and the second electrode 43 on the back side 35b of the semiconductor substrate 35 is shared with the electro-absorption semiconductor optical modulator 11.
In the semiconductor laser 51, the semiconductor substrate 35 has n-type conductivity as in the electro-absorption semiconductor optical modulator 11, and the contact layer 71 has p-type conductivity. But, the present invention is not limited thereto, p-type semiconductor substrates can be used in place of the semiconductor substrate 35 of n-type conductivity, and n-type cladding and contact layers can be used in place of the cladding and contact layers of p-type conductivity.
One example of the electro-absorption semiconductor optical modulator 11 is as follows:
semiconductor substrate 35: n-type InP;
n-type cladding region 13: n-type InP;
p-type cladding region 15: p-type InP;
active region 17 (multiple quantum well structure)
well layer 23a: InGaAsP (its bandgap wavelength is adjusted such that photo luminescence wavelength is 1.52 micrometers)
One example of the semiconductor laser 51 is as follows:
n-type cladding region 13: n-type InP;
p-type cladding region 55: p-type InP;
active region 57 (multiple quantum well structure)
well layer 63a: InGaAsP (bandgap wavelength is adjusted such that photo luminescence wavelength is 1.56 micrometers)
The quantum well structure 21 of the semiconductor mesa 25 and the quantum well structure 61 of the semiconductor mesa 75 can be fabricated by selective growth using a dielectric mask. Alternatively, the semiconductor mesa 25 and the semiconductor mesa 75 are fabricated by butt-joint method.
It is preferable that the well layers 63a in the semiconductor laser 51 be compressively strained. In this the electro-absorption semiconductor optical modulator, the well layers 63a of the semiconductor laser 51 can be made by selectively growth method in the same steps as the growth of the well layers 13a. It is preferable that the quantum well structure 61 be strain-compensated, and the strain-compensation is made crystal quality of semiconductor layers for the semiconductor laser excellent. When the well layers 63a of the semiconductor laser 51 are made by selectively growth method in the same steps as the growth of the well layers 13a, the barrier layers 63b of the semiconductor laser 51 are made by selectively growth method in the same steps as the growth of the barrier layers 13c. The quantum well structure 61 also includes the interlayer.
When the semiconductor mesa 25 and semiconductor mesa 75 are fabricated by butt-joint method, the strain of the well layers 63a in the semiconductor laser 51 is not restricted by the strain of the well layers 23a in the electro-absorption semiconductor optical modulator 11.
With reference to
As shown in Part (c) of
As shown in Part (a) of
As shown in Part (b) of
After removing the dielectric mask 88, as shown in Part (c) of
As shown in Part (a) of
As shown in Part (c) of
The fabrication of the quantum well structures for the electro-absorption semiconductor optical modulator 11 and semiconductor laser 51 is not limited to the butt-joint method as described above, and selective growth method can be used as well. In this selective growth method, an active layer for the electro-absorption semiconductor optical modulator 11 is formed at the same time as the active layer for the semiconductor laser 51. The selective growth method can be performed using a mask for selective growth by MOVPE method. The primary surface of the substrate has the first area for forming the active layer of the DFB semiconductor laser (DFB laser portion) and the second area for forming the active layer of the optical modulator (modulator portion). The mask for selective growth has a first opening (slit) located on the first area, and the second area is not covered with the mask. If required, the mask for selective growth has a second opening (slit) located on the second area, and the second opening is wider than the first opening. In the modulator portion which is not covered with the mask, inherent semiconductor as designed is deposited. Since the mask on the DFB laser portion has the slit and this slit increases growth rate, a semiconductor layer which is formed using the mask is thicker than a semiconductor layer in the modulator portion and has a composition different from the semiconductor layer in the modulator portion. These differences are adjusted by the size of the slit (mask ratio). When the mask ratio is high, the growth rate is increased and the well layer becomes thick in thickness. The increase of the well layer in thickness shifts a peak of the photo luminescence spectrum in the multiple quantum well (MQW) structure to a longer wavelength region. The ratio of Indium to Gallium in the composition of GaInAsP becomes greater, and the wavelength of the MQW structure is also shifted to a longer wavelength region. The well layers in the semiconductor laser are compressively strained. It is preferable that a selectively-growing mask having a width be used so that the peak wavelength of the photoluminescence spectrum from the MQW structure of the semiconductor laser is longer than the peak wavelength of the photoluminescence spectrum from the MQW structure of the modulator portion by 40 nanometers. Thereafter, a semiconductor laser integrated with a modulator as in the above embodiment is fabricated.
In this method, the multiple quantum well structure in the semiconductor laser includes the interlayer directly located on the n-side of the well layer. In this MQW, since the barrier layer is directly located on the p-side of the well layer and it is important that electrons of a effective mass smaller than that of holes is confined to the well layers, the performance of the modulator can be improved by use of the simple fabrication process as above without the degradation of the performance of the carrier confinement.
Having described and illustrated the principle of the invention in a preferred embodiment thereof, it is appreciated by those having skill in the art that the invention can be modified in arrangement and detail without departing from such principles. We therefore claim all modifications and variations coming within the spirit and scope of the following claims.
Number | Date | Country | Kind |
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P2006-294668 | Oct 2006 | JP | national |