BACKGROUND OF THE INVENTION

An avalanche photodiode (APD) used as a photodiode having multiplying effect is well-known.

The avalanche photodiode comprises a photo-electric conversion region which imparts a photo-electric effect after exposure to an incident light and a multiplying region which imparts an avalanche effect by applying a reverse bias voltage thereto. A desired distribution of impurities in the avalanche photodiode is dependent upon using electronsor positive holes as carriers for the multiplying step.

In order to impart the desired functions of the avalanche photodiode, it is necessary to form the photo-electric conversion region from a substance that produces a photo-electric effect upon exposure to incident light and the energy gap thereof should be smaller than the photon energy (hν).

On the other hand, the multiplying characteristic of the carrier region is dependent upon a ratio of the impact ionization coeffecient of electrons to that of positive holes in the multiplying region.

It is known that the avalanche photodiode uses a substance for providing α/β>>1 or α/β<<1 (α and β are respectively the impact ionization coefficient of the electrons and that of the positive holes) and uses a carrier for providing a higher absolute value for the impact ionization coefficient.

However, the conventional avalanche photodiode is made of a single crystalline substance and it is essential that the avalanche photodiode have the photo-electric effect as one of its functions. As a result of this, it is necessary to select a substance having an energy gap smaller than the photon energy (hν). Accordingly, it has not been possible to effectively use a substance for providing α/β>>1 or α/β<<1--the impact ionization coefficient ratio in the carrier multiplying region.

That is, it has not been possible to provide an avalanche photodiode having high quantum efficiency and low noise, to provide a satisfactory charging effect after exposure to the incident light; and to provide α/β>>1 or α/β<<1--the impact ionization coefficient ratio.

SUMMARY OF THE INVENTION

It is an object of the present invention to improve the quantum efficiency of an avalanche photodiode upon exposure to incident light.

It is another object of the present invention to increase the ratio of the impact ionization coefficient of electrons to that of positive holes in the multiplying step of an avalanche photodiode.

It is the other object of the present invention to provide an avalanche photodiode having high efficiency and low noise.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a sectional view of one embodiment of an avalanche photodiode according to the present invention;

FIG. 2 is a sectional view of the other embodiment of an avalanche photodiode according to the present invention; and

FIG. 3 is a graph showing a distribution of the compositions of the Ge_x Si_1-x layer of FIG. 2.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention overcomes the disadvantages of the conventional avalanche photodiode.

The avalanche photodiode of the present invention comprises: a photo-electric conversion region made of a semiconductor having an energy band gap that is smaller than the photon energy; and a carrier multiplying region made of a semiconductor that differs from the semiconductor of the photo-electric region and has α/β>>1 or α/β<<1 as an impact ionization coefficient ratio, whereby an avalanche photodiode having a high quantum efficiency and a low noise index in the multiplying step is obtained.

Referring to the figures in the drawing, the present invention will be illustrated.

In FIG. 1, the reference letter (A) designates a N type high impurity content semiconductor layer and (B) designates a P type impurity semiconductor layer having α/β>>1 of an impact ionization coefficient ratio. The semiconductor layer (B) forms the carrier multiplying region and the semiconductor layers (A) and (B) are connected by P-N junction (1).

The semiconductor layers (A) and (B) are usually formed by using the same crystalline substrate, however, it is not always necessary to use the same crystalline substrate.

The reference (C) designates a semiconductor layer having an energy gap that is smaller than the photon energy upon exposure to the incident light and having a higher specific resistance than layer (B). The semiconductor layer (C) forms a photo-electric conversion region made of a P type impurity semiconductor substance that differs from the semiconductor layers (A), (B). The reference (2) designates a heterojunction for connecting the layer (B) and the layer (C). The reference (D) designates a P type high impurity content semiconductor layer connected to the semiconductor layer (C). The layer (D) can be made of the same semiconductor substance as that of the layer (C). The reference numerals (3) and (4) designate electrodes and the arrow line designates the incident light.

In accordance with the above-mentioned structure, an avalanche photodiode is obtained which has a high quantum efficiency and low noise; imparts a satisfactory photo-electric effect in the photo-electric conversion region (C); and has a high impact ionization coefficient ratio in the carrier multiplying region (B).

The substances used in the semiconductor layers (A), (B), (C) and (D) are dependent upon the characteristics of the incident light, e.g., wavelength.

Certain examples of semiconductor substances used for the semiconductor layers are illustrated below.

EXAMPLE 1

Semiconductor layer (A): N type high impurity content Si layer;

Semiconductor layer (B): P type Si layer;

Semiconductor layer (C): P type Ge layer;

Semiconductor layer (D): P type high impurity content Ge layer.

The avalanche photodiode made of substances the above exhibited a high quantum efficiency to incident light having a wavelength of 1.2 to 1.6 μm, as the energy gap of Ge was 0.66 (eV) (300° K.). The impact ionization coefficient ratio of Si in the carrier multiplying region was 10≦α/β≦200.

EXAMPLE 2

Semiconductor layer (A): N type high impurity content GaAs layer

Semiconductor layer (B): P type GaAs layer (carrier multiplying region)

Semiconductor layer (C): P type GaAs_1-x Sb_x layer (photo-electric conversion region)

Semiconductor layer (D): P type high impurity content GaAs_1-x Sb_x layer

The avalanche photodiode made of the above substances had an energy gap which depend upon the ratio of As to Sb. For example, the energy gap of GaAs₀.95 Sb₀.05 (where x=0.05) was 1.3 (eV) and a high quantum efficiency was obtained for incident light having a wavelength of less than 0.95 μm.

The impact ionization coefficient ratio α/β of GaAs in the carrier multiplying region was α/β≃4.

EXAMPLE 3

Semiconductor layer (A): N type high impurity content Si layer;

Semiconductor layer (B): P type Si layer (carrier multiplying region)

Semiconductor layer (C): P type Ge_x Si_1-x layer (photo-electric conversion region)

Semiconductor layer (D): P type high impurity content Ge_x Si_1-x layer.

In the avalanche photodiode, the energy gap of the photo-electric conversion region (C) is in the range of 0.66 to 1.11 (eV) depending upon the ratio of Ge to Si; and high sensitivity is given to the wavelength that corresponds to the energy gap.

The ratio of α/β in the carrier multiplying region was 10≦α/β≦200.

In the above examples, the P type high impurity content semiconductor layer (D) is made of a substance that corresponds to the substance of the P type photo-electric conversion region (C). Thus, it is possible to use different substances for both layers.

When a substance with a small absorption coefficient to the incident light wavelength is selected as the P type high impurity content substance, absorption of the light in the semiconductor layer (D) is reduced.

In the embodiment of the avalanche photodiode shown in FIG. 2, the carrier multiplying region (B) and the photo-electric conversion region (C) are not clearly defined. As shown in the graph of FIG. 3, the compositions in the Ge_x Si_1-x layer (E) are gradually varied in the direction of thickness. Accordingly the value of x is gradually varied to Ge 100% at the end of the photo-electric conversion region and Si 100% at the end of the carrier multiplying region.

The semiconductor layer (A) is a N type high impurity content Si layer and the semiconductor layer (D) is a P type high impurity content Ge layer.

In the above-mentioned embodiments, the incident light strikes the P type high impurity content semiconductor layer (D).

It is also effective to have the incident light enter from the side of the N type high impurity content semiconductor layer. In this case, the same effect can be attained by selecting a substance having a sufficient low light absorption coefficient to the incident light wavelength and having the ratio of α/β>>1, for the carrier multiplying region (B).

In the above-mentioned embodiments, electrons are used as the carriers for the multiplying effect. Thus, it is also possible to use positive holes as carriers. In the latter case, it is preferable to select a substance having an impact ionization coefficient ratio of α/β<<1. Such substances are easily obtainable. Thus, the present invention can be easily manufactured by following the above-described steps. Moreover, the present invention can be applied to other semiconductor devices utilizing the avalanche effect.

As described above, the avalanche photodiode of the present invention utilizes different semiconductor crystalline substances in the photo-electric conversion region and in the carrier multiplying region so as to impart satisfactory functions in these regions whereby the quantum efficiency in the photo-electric conversion region is improved and the noise in the carrier multiplying region is reduced.