JP2022054180A - Photodetector - Google Patents

Abstract

To provide a graphene photodetector capable of detecting light with only one voltage applied to one back gate.SOLUTION: A graphene photodetector 2 has an optical sensor 4 having graphene including a photosensitive area 10 with a plurality of regions whose fill factor, which indicates the percentage of portions other than pores, differs from each other, and a gate electrode 5 opposite the graphene, and a gate voltage application circuit that applies a gate voltage 17 between the photosensitive area and the gate electrode. The gate voltage is set such that the sensitivity of the optical sensor is set to a specific value.SELECTED DRAWING: Figure 1

Description

The present invention relates to a photodetector.

A photodetector (hereinafter referred to as a graphene photodetector) that detects a voltage or the like generated in graphene by light irradiation is attracting attention. Graphene is a material in which carbon atoms are arranged in a two-dimensional honeycomb shape, and has characteristic physical properties.

Graphene, for example, has a small heat capacity and a large thermoelectric effect. Therefore, when graphene is irradiated with infrared rays or terahertz light, the temperature of graphene rises significantly, and as a result, a large thermoelectromotive force is generated. The graphene photodetector is a photodetector that utilizes these features (see, for example, Patent Document 1 and Non-Patent Document 1).

A graphene photodetector (hereinafter referred to as a two-backgate photodetector) having a graphene and two backgates facing the graphene has demonstrated photodetection by graphene (see, for example, Non-Patent Document 1). When different voltages are applied to the two backgates, an asymmetric carrier distribution is formed in the graphene. Since the Seebeck coefficient depends on the carrier density, when graphene having an asymmetric carrier distribution is irradiated with infrared light or the like and the temperature rises, thermoelectromotive force is generated. 2 The backgate photodetector detects this thermoelectromotive force. Note that the asymmetric carrier distribution means that the types and / or densities of multiple carriers are not uniform.

The asymmetric carrier distribution can also be realized by adhering different different substances to adjacent regions of graphene (see, for example, Patent Document 1). However, it is not easy to manufacture a graphene photodetector in which different substances different from each other are attached to graphene. 2 The backgate photodetector does not have such a problem.

Regarding the physical characteristics of graphene, a technique for providing a bandgap in graphene, which is a zero-gap semiconductor, by providing holes in graphene has been reported (see, for example, Patent Document 1). As for a detector that detects terahertz light, a device having improved sensitivity by using three-dimensional porous graphene as a light receiving layer has been reported (see, for example, Patent Document 2).

Re-table 2013/018153 Gazette Japanese Unexamined Patent Publication No. 2018-37617

Kei Kinoshita et al., Applied Physics Letters 113, 103102 (2018)

A 2-backgate photodetector is a device that can be manufactured without the complicated process of adhering different substances to graphene. However, the two-backgate photodetector has a problem that the structure is complicated.

The two backgate photodetectors also have the problem that the peripheral circuits are complicated because different voltages are applied to the two backgates. These problems relate to the basic operation of a two-backgate photodetector, which applies different voltages to the two backgates.

Therefore, it is an object of the present invention to solve such a problem.

In one embodiment, the photodetector comprises a graphene including a light receiving region in which a first region provided with a hole is arranged on one end side and a second region different from the first region is arranged on the other end side. A gate voltage is applied between an optical sensor having a gate electrode facing the light receiving region and outputting an electric signal in response to light radiated to the light receiving region, and the light receiving region and the gate electrode. The ratio of the area other than the hole in the first region to the area of the first region is the area of the region other than the hole in the second region and the second region. The gate voltage is set so that the ratio of the intensity of the electric signal to the intensity of the light becomes a specific value.

On one side, according to the invention, a graphene photodetector (ie, a photodetector that photoelectrically converts light with graphene) capable of detecting light by applying one voltage to one backgate. Can be provided.

FIG. 1 is a diagram showing an example of the photodetector 2 of the first embodiment. FIG. 2 is a perspective view showing an example of the optical sensor 4. FIG. 3 is a plan view showing an example of the light receiving region 10. FIG. 4 is a diagram showing an energy band structure of graphene without doping of impurities or adhesion of foreign substances. FIG. 5 is a diagram illustrating a conductive type of the light receiving region 10 in the first embodiment. FIG. 6 is a diagram showing an example of the relationship between the sensitivity R1 of the photodetector 2 and the gate voltage Vg when the light receiving region 10 is irradiated with light of a specific wavelength (for example, 8 μm). FIG. 7 is a diagram illustrating the densities of electrons 34 induced in the first region 16a and the second region 16b. FIG. 8 is a diagram showing an example of the manufacturing method of the optical sensor 4 of the first embodiment. FIG. 9 is a diagram showing an example of the manufacturing method of the optical sensor 4 of the first embodiment. FIG. 10 is a diagram showing an example of the structure of a photodetector 102 having a photosensor 104 provided with two gate electrodes. FIG. 11 is a diagram illustrating a modification 216a of the first region 16a. FIG. 12 is a diagram showing an example of the photodetector 202 of the second embodiment. FIG. 13 is a diagram illustrating a conductive type of the light receiving region 10 in the second embodiment. FIG. 14 is a diagram showing an example of the relationship between the sensitivity R2 of the photodetector 202 and the gate voltage Vg when the light receiving region 10 is irradiated with light having a specific wavelength.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the technical scope of the present invention is not limited to these embodiments, but extends to the matters described in the claims and their equivalents. Even if the drawings are different, the parts having the same structure and the like are designated by the same reference numerals, and the description thereof will be omitted.

(Embodiment 1)
(1) Structure FIG. 1 is a diagram showing an example of the photodetector 2 of the first embodiment. As shown in FIG. 1, the photodetector 2 of the first embodiment includes an optical sensor 4, a gate voltage application circuit 6, and an electric signal detection circuit 8.

―Optical sensor 4―
FIG. 2 is a perspective view showing an example of the optical sensor 4. FIG. 2 shows the vicinity of graphene 12 (see FIG. 1) in the optical sensor 4.

The optical sensor 4 covers a region 10 (hereinafter referred to as a light receiving region) irradiated with light, a first connection region 15a in contact with one end E1 (see FIG. 1) of the light receiving region 10, and the other end E2 of the light receiving region 10. It has a graphene 12 that includes a second connecting region 15b in contact with it. The optical sensor 4 is a device that outputs an electric signal in response to the light emitted to the light receiving region 10.

The optical sensor 4 further has a first electrode 11a connected to the first connection region 15a and a second electrode 11b connected to the second connection region 15b. The optical sensor 4 further has a gate electrode 5 facing the light receiving region 10. The gate electrode 5 is, for example, a conductive silicon substrate 7 (that is, n ⁺ silicon substrate or p ⁺ silicon substrate).

The optical sensor 4 further has a SiO ₂ film 9 disposed on the silicon substrate 7 and supporting the graphene 12. The optical sensor 4 further has a substrate electrode 13 (see FIG. 1) connected to the silicon substrate 7.

FIG. 3 is a plan view showing an example of the light receiving region 10. A first region 16a provided with a hole 14 is arranged on one end E1 side of the light receiving region 10. On the other end E2 side of the light receiving region 10, a second region 16b different from the first region 16a is arranged. The fill factor of the first region 16a is smaller than the fill factor of the second region 16b.

The fill factor of a certain region A (for example, the first region 16a) is the ratio (= S1 / S2) of the area S1 of the region other than the hole in the region A and the area S2 of the region A. Therefore, the fill factor of the first region 16a is the ratio (= S1 / S2) of the area S1 of the region 3 (hereinafter referred to as a filling region) filled with carbon atoms in the first region 16a to the area S2 of the first region 16a. ). The area S2 of the first region 16a is the entire area inside the outer circumference of the first region 16a. In the example shown in FIG. 3, the fill factor of the first region 16a is approximately 0.5.

The same applies to the fill factor of the second region 16b. In the example shown in FIG. 3, since the second region 16b is not provided with a hole, the fill factor of the second region 16b is 1.

―Gate voltage application circuit 6―
The gate voltage application circuit 6 (see FIG. 1) is a circuit that applies a gate voltage Vg between the light receiving region 10 and the gate electrode 5. The gate voltage Vg of the photodetector 2 is a constant voltage V1 (for example, 3V). The details of the voltage V1 will be described in "(2) Operation".

In the example shown in FIG. 1, the gate voltage application circuit 6 has a constant voltage source 17 connected to a substrate electrode 13 and a second electrode 11b to output a voltage V1. The gate voltage Vg (that is, the voltage V1) is applied between the light receiving region 10 and the gate electrode 5 via the substrate electrode 13 and the second electrode 11b.

The conductive type of the light receiving region 10 is a p type (or n type) when no voltage is applied between the light receiving region 10 and the gate electrode 5. By applying the voltage V1 between the light receiving region 10 and the gate electrode 5, the conductive type of the first region 16a is inverted, and the conductive type of the second region 16b is maintained.

-Electrical signal detection circuit 8-
The electric signal detection circuit 8 (see FIG. 1) is a circuit that detects an electric signal output by the optical sensor 4 in response to light (for example, visible light, infrared rays, or terahertz light) radiated to the light receiving region 10.

The electric signal detection circuit 8 of the first embodiment is a current detection circuit 19 that detects a current I flowing in the light receiving region 10 while applying voltage Vbias to both ends E1 and E2 of the light receiving region 10. The current detection circuit 19 has, for example, a constant voltage source 18 for applying a voltage Vbias to the light receiving region 10, and an ammeter 20 connected to the constant voltage source 18. One end of the current detection circuit 19 is connected to the first electrode 11a and the other end is connected to the second electrode 11b.

The voltage Vbias is the potential of one of the first and second regions 16a and 16b, in which the conductive type is n type while the voltage V1 is applied between the light receiving region 10 and the gate electrode 5. It is a voltage higher than the other potential of the first to second regions 16a and 16b. The conductive type of the first to second regions 16a and 16b will be described in "(2) Operation". The voltage Vbias is a reverse bias voltage applied to the pn junction (see “(2) Operation”) formed in the light receiving region 10.

The electrical signal output by the optical sensor 4 goes to the current I (that is, the reverse-biased light receiving region 10) detected by the current detection circuit 19 while the voltage V1 is applied between the light receiving region 10 and the gate electrode 5. The current flowing in the light receiving region 10 due to the light irradiation of the above.

(2) Operation FIG. 4 is a diagram showing an energy band structure of graphene without doping of impurities or adhesion of foreign substances. The k _x -axis 22 indicates the wave number k _x in the x-axis direction. The _y -axis 24 indicates the wave number ky in the _y -axis direction. The energy axis 26 shows the energy E of the electron.

As shown in FIG. 4, the valence band 28 and the conduction band 30 of graphene are in contact with each other at the K point 32. For this reason, graphene is sometimes referred to as a zero-gap semiconductor. The K point 32 in graphene is the Dirac point (that is, the point where the band is degenerate).

FIG. 5 is a diagram illustrating a conductive type of the light receiving region 10 in the first embodiment. FIG. 5 shows an example of the energy band of the light receiving region 10. In the example shown in FIG. 5, the conductive type of the light receiving region 10 is a p type when no voltage is applied between the light receiving region 10 and the gate electrode 5. In order not to complicate the explanation, the thermal energy of the electron is ignored in the explanation of FIG. 5 (the same applies to FIG. 13 described later).

In the following description, "between the light receiving region 10 and the gate electrode 5" is abbreviated as "to the gate electrode 5." Therefore, for example, "when no voltage is applied between the light receiving region 10 and the gate electrode 5" is abbreviated as "when no voltage is applied to the gate electrode 5". Similarly, "between the light receiving region 10 and the gate electrode 5" is abbreviated as "to the gate electrode 5."

FIG. 5A shows an example of the energy band of the light receiving region 10 when no voltage is applied to the gate electrode 5. When no voltage is applied to the gate electrode 5, the valence band 28 of the light receiving region 10 (see FIG. 5A) is filled with electrons up to energy E ₀ and the top of the valence band from energy E ₀ (see FIG. 5A). That is, points up to point K) are filled with holes. That is, when no voltage is applied to the gate electrode 5, the conductive type of the light receiving region 10 is p type.

FIG. 5B shows the energy band of the first region 16a when the voltage V1 (that is, the gate voltage Vg of the first embodiment) is applied to the gate electrode 5. FIG. 5C shows the energy band of the second region 16b when the voltage V1 is applied to the gate electrode 5.

In the example shown in FIGS. 5 (b) to 5 (c), the voltage V1 is a voltage that lowers the potential of the light receiving region 10 to be lower than the potential of the gate electrode 5. Therefore, when the voltage V1 is applied to the gate electrode 5, electrons are induced in the first region 16a and the second region 16b.

At this time, electrons having a higher density than the electron density of the second region 16b are induced in the filling region 3 (see FIG. 3) of the first region 16a having a low fill factor (see “-asymmetric carrier induction” below). ). As a result, the valence band 28 of the first region 16a is filled with the induced electrons, and the electrons entered in the valence band 28 fill the bottom of the conduction band 30 of the first region 16a (see FIG. 5B). ). Therefore, the conductive type of the first region 16a is inverted by applying the voltage V1 to the gate electrode 5 and becomes the n type.

On the other hand, even if the voltage V1 is applied to the gate electrode 5, sufficient electrons are not induced in the second region 16b to fill the conduction band 30, and the conductive type of the second region 16b is maintained in the p type (p-type). See FIG. 5 (c)). Therefore, a pn junction occurs in the light receiving region 10 by applying the voltage V1 to the gate electrode 5. The pn junction generated in the light receiving region 10 can be detected by, for example, a scanning probe microscope.

In addition, in the second region 16b, the maximum value of the electron energy in the valence band 28 is changed from E ₀ to E ₂ (see FIG. 5 (c)) by applying the voltage V1 to the gate electrode 5. Rise. Therefore, the hole density in the second region 16b is lowered by applying the voltage V1 to the gate electrode 5.

-Generation of photocurrent-
When a voltage Vbias (that is, a reverse bias voltage) is applied to the light receiving region 10, the depletion layer of the pn junction generated in the light receiving region 10 expands. When the expanded depletion layer is irradiated with light, electron-hole pairs are generated. The generated electron-hole pair is separated into electrons and holes by the electric field in the depletion layer. The separated electrons and holes become a flow of electrons and a flow of holes due to the electric field in the depletion layer. This bundle of electron flow and hole flow is a current (hereinafter referred to as photocurrent) that flows in the light receiving region 10 due to light irradiation.

The photocurrent flowing in the light receiving region 10 is output from the light receiving region 10 via the first electrode 11a and the second electrode 11b, and is detected by the ammeter 20 (see FIG. 1) of the current detection circuit 19. The electric signal output by the optical sensor 4 is a light current flowing through the light receiving region 10 due to light irradiation while the voltage V1 is applied between the light receiving region 10 and the gate electrode 5 and the voltage Vbias is applied to the light receiving region 10. Is.

-sensitivity-
FIG. 6 is a diagram showing an example of the relationship between the sensitivity R1 of the photodetector 2 and the gate voltage Vg when the light receiving region 10 is irradiated with light of a specific wavelength (for example, 8 μm). The horizontal axis is the gate voltage Vg. The vertical axis is the sensitivity R1 of the photodetector 2. The sensitivity of the photodetector 2 is the intensity A of the electric signal (photocurrent in the first embodiment) output by the optical sensor 4 in response to the light emitted to the light receiving region 10 and the light emitted to the light receiving region 10. It is the ratio (= A / B) of the intensity (so-called optical power) B of. As shown in FIG. 6, the sensitivity R1 can be either positive or negative.

The positive or negative of the sensitivity R1 of the photodetector 2 is determined by the positive or negative of the current flowing through the electric signal detection circuit 8. For example, if the current is negative, the sensitivity is also negative. Since the positive or negative of the current is determined by the definition of the positive direction (of the current), the positive or negative of the sensitivity of the photodetector 2 is convenient. The same applies to the sensitivity of the photodetector 202 of the second embodiment.

In the region I where the gate voltage Vg (here, the potential of the gate electrode 5 with respect to the light receiving region 10) is small, the conductive type of the first region 16a and the second region 16b of the light receiving region 10 is not inverted, so that the light receiving region 10 is pn. No joint is formed. Therefore, the sensitivity of the photodetector 2 is substantially zero. On the other hand, in the region III where the gate voltage Vg is too large, the conductive type of both the first region 16a and the second region 16b is inverted, so that the pn junction is not formed in the light receiving region 10. Therefore, even in region III, the sensitivity of the photodetector 2 is substantially zero.

In the region II where the gate voltage Vg is not too small and not too large, the conductive type of only the first region 16a is inverted, so that a pn junction is formed in the light receiving region 10. Then, the sensitivity of the photodetector 2 increases, and a large peak 36 appears on the curve 35 showing the relationship between the gate voltage Vg and the sensitivity R1.

The peak value P1 of the sensitivity R1 (that is, the sensitivity having the maximum absolute value among the sensitivities R1) depends not only on the gate voltage Vg but also on the voltage Vbias applied to the light receiving region 10. When the voltage V bias is 1 V, the peak value P1 of the sensitivity R1 is, for example, 1 mA / W.

The gate voltage Vg of the first embodiment is a voltage V1 set so that the sensitivity R1 (see FIG. 6) of the photodetector 2 becomes a specific value (hereinafter referred to as a target sensitivity). The voltage V1 may be a variable voltage. That is, the constant voltage source 17 of the gate voltage application circuit 6 may be a variable voltage source.

When the peak value P1 of the sensitivity R1 is a positive value, the target sensitivity is preferably 0.5 times or more the peak value P1 of the sensitivity R1. More preferably, the target sensitivity is 0.7 times or more the peak value P1 of the sensitivity R1. Most preferably, the target sensitivity is 0.9 times or more the peak value P1 of the sensitivity R1 (for example, the peak value P1). The upper limit of the target sensitivity is the peak value P1 of the sensitivity R1.

On the other hand, when the peak value P1 of the sensitivity R1 is a negative value, the target sensitivity is preferably 0.5 times or less the peak value P1 of the sensitivity R1. More preferably, the target sensitivity is 0.7 times or less of the peak value P1 of the sensitivity R1. Most preferably, the target sensitivity is 0.9 times or less the peak value P1 of the sensitivity R1 (for example, the peak value P1). The lower limit of the target sensitivity is the peak value P1 of the sensitivity R1.

Specifically, the absolute value of the target sensitivity is preferably 0.5 mA / W or more. More preferably, the absolute value of the target sensitivity is 0.7 mA / W or more. Most preferably, the absolute value of the target sensitivity is 0.9 mA / W or more.

As described in the second embodiment, when the gate voltage Vg is applied to the gate electrode 5, the Seebeck coefficient of the first region 16a and the Seebeck coefficient of the second region 16b of the light receiving region 10 deviate from each other. Therefore, the electric signal output from the optical sensor 4 includes a current generated by the thermoelectric effect (that is, the thermoelectric effect due to the heat generated by light absorption).

However, in the photodetector 2 of the first embodiment, since the reverse bias voltage Vbias is applied to the light receiving region 10 and the depletion layer expands, the photocurrent due to the photovoltaic effect (that is, the photocurrent generated by the internal electric current of the pn junction). However, it is often more dominant than the current due to the photovoltaic effect.

The pyroelectric effect will be described in the second embodiment.

-Asymmetric carrier induction-
FIG. 7 is a diagram illustrating the densities of electrons 34 induced in the first region 16a and the second region 16b. Again, the conductive type of the light receiving region 10 is a p type when no voltage is applied between the light receiving region 10 and the gate electrode 5.

As is clear from Gauss's law regarding the electrostatic field, the number N ₁ of electrons induced in the first region 16a by a certain gate voltage Vg is expressed by the equation (1).

Here, ε is the dielectric constant of the SiO ₂ film 9. e is an elementary charge. _En is a component of the electric field vector from the first region 16a toward the gate electrode 5 that is perpendicular to the first region 16a. When the width of the hole 14 is sufficiently smaller than the distance _d between the first region 16a and the gate electrode 5 (that is, the thickness of the SiO ₂ film 9), En is a filled region 3 (that is, a region filled with carbon atoms). : See FIG. 2) and just below both the hole 14 is approximately Vg / d.

Therefore, the macroscopic electron density ED _mac induced in the first region 16a by applying the gate voltage Vg is represented by the equation (2).

The macroscopic electron density is the area of the microscopic region (that is, the entire inside of the outer periphery of a certain region) divided by the total number of electrons induced in the macroscopic region. Therefore, the macroscopic electron density ED _mac induced in the first region 16a by applying the gate voltage Vg is induced in the first region 16a by applying the gate voltage Vg in the entire area _Smac inside the outer periphery of the first region 16a. It is a value obtained by dividing the total number of electrons to be generated N ₁ (= N ₁ / S _mac ).

On the other hand, the electron density ED _mic (hereinafter referred to as microscopic electron density) induced in the packed region 3 (see FIG. 2) filled with carbon atoms is N ₁ / S _mic . Here, _Smic is the area of the filling region. _Smic is the area of a region (here, the first region 16a) other than the hole 14.

Therefore, the microscopic electron density ED _mic of the first region 16a is represented by the equation (3).

Here, F is a fill factor (= _Smic / _Smac ) of the macroscopic region (here, the first region 16a). The electron density induced in graphene 12 in the first region 16a is not the macroscopic electron density ED _mac but the microscopic electron density ED _mic .

Similarly, the density of electrons induced in graphene 12 in the second region 16b is not a macroscopic electron density but a microscopic electron density. Equations (1) to (3) also hold for the electron density and the like in the second region 16b.

Since the same gate voltage Vg is applied to the first region 16a and the second region 16b, as is clear from the equation (2), the macroscopic electron density ED _mac of the first region 16a and the macroscopic view of the second region 16b. Electron density ED _mac is equal. On the other hand, as shown in FIG. 3, the fill factor F of the first region 16a is smaller than the fill factor F of the second region 16b.

Therefore, the microscopic electron density ED _mic of the first region 16a is larger than the microscopic electron density ED _mic of the second region 16b. Therefore, the density of electrons induced in graphene 12 in the first region 16a is higher than the density of electrons induced in graphene 12 in the second region 16b. That is, the application of one gate voltage Vg to one gate electrode 5 induces an asymmetric carrier distribution (see FIG. 5) in the light receiving region 10.

In the above description, the width of the hole 14 is sufficiently smaller than the thickness of the SiO ₂ film 9. However, even if such ideal conditions are not satisfied, the density of electrons (or holes) induced in the first region 16a is the density of electrons (or holes) induced in the second region 16b. Will be higher.

(3) Manufacturing Method FIGS. 8 to 9 are views showing an example of a manufacturing method of the optical sensor 4 of the first embodiment.

First, the SiO ₂ film 9 is formed on the conductive silicon substrate 7 (see FIG. 8A). The thickness of the SiO ₂ film 9 is, for example, 50 nm to 200 nm (preferably 90 nm).

On the SiO ₂ film 9, a band-shaped graphene 12 in which a part of carbon atoms is replaced with a hetero atom (for example, nitrogen or boron) is arranged (see FIG. 8 (b)). When a part of the carbon atom is replaced with a hetero atom, the conductive type of graphene 12 becomes n-type or p-type. For example, the conductive type of graphene 12 in which a part of carbon atoms is replaced with nitrogen atoms is n type. The conductive type of graphene 12 in which a part of carbon atom is replaced with a boron atom is p type.

The length of graphene 12 is, for example, 5 μm to 20 μm (eg, 9 μm). The width of graphene 12 is, for example, 2 μm to 10 μm (eg, 5 μm).

A photoresist film 38 having a plurality of openings 37 provided on one end side of the graphene 12 is formed on the SiO ₂ film 9 and the graphene 12 (see FIG. 8C). Graphene 12 is etched through the photoresist film 38. The graphene 12 is etched, for example, by dry etching using oxygen as a reaction gas.

By this etching, a plurality of holes 14 are formed on one end side of the graphene 12 (see FIG. 9A). The region where the plurality of holes 14 are formed becomes the first region 16a of the light receiving region 10. The region in contact with the first region 16a is the second region 16b of the light receiving region 10. In FIG. 9A, the first region 16a is longer than the second region 16b, but the lengths of the first region 16a and the second region 16b may be substantially the same. Alternatively, the first region 16a may be shorter than the second region 16b.

The width of the holes 14 is, for example, 10 nm to 1000 nm. The fill factor of the first region 16a is, for example, 0.7 to 0.95 (preferably 0.9). The fill factor of the second region 16b is, for example, 1.0.

After forming the plurality of holes 14, a contact hole 40 penetrating the SiO ₂ film 9 is formed (see FIG. 9B).

After that, the first electrode 11a is formed at one end of the graphene 12, and the second electrode 11b is formed at the other end. Further, a substrate electrode 13 is formed in contact with the silicon substrate 7 exposed in the contact hole 40 and extending on the SiO ₂ film 9 (see FIG. 9 (c)).

(4) Two-backgate photodetector FIG. 10 is a diagram showing an example of the structure of a photodetector 102 having an optical sensor 104 (that is, a two-backgate photodetector) provided with two gate electrodes. The photodetector 102 is similar to the photodetector 2 of the first embodiment described with reference to FIG. 1 and the like. Therefore, the description of the parts common to the photodetector 2 will be omitted.

The photodetector 102 includes an optical sensor 104, a first bias circuit 106a, a second bias circuit 106b, and an electrical signal detection circuit 8. The electric signal detection circuit 8 is a circuit described with reference to FIG. 1 and the like.

-Optical sensor 104-
The graphene 112 of the optical sensor 104 is not provided with a hole. Therefore, the fill factor of the first region 116a of the light receiving region 110 is 1. The fill factor of the second region 116b of the light receiving region 110 is also 1.

The optical sensor 104 has a first gate electrode 105a facing the first region 116a and a second gate electrode 105b facing the second region 116b. The optical sensor 104 further has an insulating film 109 (eg, a SiO ₂ film) disposed between the first gate electrode 105a and the second gate electrode 105b and the graphene 112. The first gate electrode 105a and the second gate electrode 105b are arranged on the SiO ₂ film 9 covering the silicon substrate 7.

-First bias circuit 106a and second bias circuit 106b-
The first bias circuit 106a applies a first gate voltage Vg1 between the first region 116a of the light receiving region 110 and the first gate electrode 105a. The second bias circuit 106b applies a second gate voltage Vg2 different from the first gate voltage Vg1 between the second region 116b of the light receiving region 110 and the second gate electrode 105b.

When no voltage is applied between the first region 116a and the first gate electrode 105a and between the second region 116b and the second gate electrode 105b, the conductive type of the light receiving region 110 is p-type (or n-type). be.

The first gate voltage Vg1 and the second gate voltage Vg2 are different voltages from each other. Therefore, the microscopic carrier density (eg, electron density) induced in the first region 116a by the first gate voltage Vg1 and the microscopic carrier density induced in the second region 116b by the second gate voltage Vg2 are Different from each other. Therefore, it is easy to form a pn junction in the light receiving region 110.

Therefore, the photodetector 102 of FIG. 10 can also detect the light emitted to the graphene 112. However, since the optical sensor 104 includes two gate electrodes (that is, a first gate electrode 105a and a second gate electrode 105b), the structure of the optical sensor 104 is complicated. Further, since different voltages Vg1 and Vg2 are applied to the two gate electrodes 105a and 105b, the peripheral circuit 42 becomes complicated.

The photodetector 2 described with reference to FIG. 1 does not have these problems.

(5) Modification Example FIG. 11 is a diagram illustrating a modification 216a of the first region 16a. The hole 14 of the first region 16a shown in FIG. 3 is a band-shaped hole with both ends rounded. On the other hand, the hole 114 of the first region 216a shown in FIG. 11 is a circular hole. According to the modified example, the variation of the first region 16a increases.

In the above example, the hole 14 is not provided in the second region 16b. However, the hole 14 may be provided not only in the first region 16a but also in the second region 16b.

Further, in the above example, the conductive type of the light receiving region 10 is a p type when no voltage is applied between the light receiving region 10 and the gate electrode 5. However, the conductive type of the light receiving region 10 may be an n type when no voltage is applied between the light receiving region 10 and the gate electrode 5. In this case, the gate voltage V1 is a voltage that makes the potential of the light receiving region 10 higher than the potential of the gate electrode 5.

In the above example, the light receiving region 10 has two regions having different fill factors (that is, the first region 16a and the second region 16b). However, the light receiving region 10 may have three or more regions having different fill factors from each other. For example, the light receiving region 10 may have a region between the first region 16a and the second region 16b having a fill factor larger than that of the first region 16a and smaller than that of the second region 16b. According to this structure, a pin junction can be formed in the light receiving region 10.

In the above example, a part of the carbon atom contained in graphene 12 is replaced by a heteroatom (see "(3) Production method"). However, it is possible to make the conductive type of the light receiving region 10 n-type or p-type without using the substitution of carbon atoms. For example, by adhering any one of an organic substance such as F4-TCNQ (tetrafluoro-tetracyanoquin-odimethane), a metal particle such as Au _, and an _Al2O3 film to the light receiving region 10, the conductive type of graphene 12 can be controlled. It is possible. Alternatively, it is possible to control the conductive type of graphene 12 by introducing a defect into graphene 12. Substitution of carbon atoms and attachment of organic substances may not be intentional.

Further, in the above example, the gate electrode 5 is a conductive silicon substrate 7. However, the gate electrode 5 may be a metal film.

The insulating film arranged between the graphene 12 and the gate electrode 5 may be an insulating film other than the SiO ₂ film (for example, a SiN film).

In the first embodiment, by applying one voltage V1 between the light receiving region 10 including the regions having different fill factors and the gate electrode 5, an asymmetric carrier distribution is induced in the light receiving region 10 to form a pn junction. do. Therefore, according to the first embodiment, it is possible to realize a graphene photodetector capable of photodetection only by applying one voltage V1 to one gate electrode 5.

(Embodiment 2)
The second embodiment is similar to the first embodiment. Therefore, the description of the same configuration and the like as in the first embodiment will be omitted or simplified.

(1) Structure FIG. 12 is a diagram showing an example of the photodetector 202 of the second embodiment. As shown in FIG. 12, the photodetector 202 includes a photosensor 4, a gate voltage application circuit 6, and an electrical signal detection circuit 208.

The optical sensor 4 is the sensor described in the first embodiment (see FIG. 1). Similarly, the gate voltage application circuit 6 is the circuit described in the first embodiment. On the other hand, the electric signal detection circuit 208 is a circuit different from the electric signal detection circuit 8 of the first embodiment.

The electric signal detection circuit 208 detects the potential difference V _PTE generated between the first connection region 15a in contact with the first region 16a of the light receiving region 10 and the second connection region 15b in contact with the second region 16b of the light receiving region 10. The voltage detection circuit 219.

In the example shown in FIG. 12, the voltage detection circuit 219 is a circuit having a voltmeter 220 connected to the first connection region 15a and the second connection region 15b. The electrical signal output by the optical sensor 4 of the second embodiment is a potential difference V _PTE (that is, a received light irradiated with light) detected by the voltage detection circuit 219 while the voltage V2 is applied to the gate electrode 5 of the optical sensor 4. The potential difference generated at both ends of the region 10). The voltage V2 is a gate voltage Vg output by the gate voltage application circuit 6. The details of the voltage V2 will be described in "(2) Operation".

(2) Operation FIG. 13 is a diagram illustrating a conductive type of the light receiving region 10 in the second embodiment. FIG. 13 shows an example of the energy band of the light receiving region 10. In the example shown in FIG. 13, the conductive type of the light receiving region 10 is a p type when no voltage is applied to the gate electrode 5.

FIG. 13A shows the energy band of the light receiving region 10 when no voltage is applied to the gate electrode 5. As shown in FIG. 13A, when no voltage is applied to the gate electrode 5, the valence band of the light receiving region 10 is filled with electrons up to energy E ₀ , and the top of the valence band from energy E ₀ . It is filled with holes up to (that is, point K).

FIG. 13B shows the energy band of graphene 12 in the first region 16a when the voltage V2 (that is, the gate voltage Vg of the second embodiment) is applied to the gate electrode 5. FIG. 13 (c) shows the energy band of graphene 12 in the second region 16b when the voltage V2 is applied to the gate electrode 5.

When the voltage V2 is applied to the gate electrode 5, electrons are induced in the first region 16a and the second region 16b. At this time, the density of electrons induced in graphene 12 in the first region 16a having a small fill factor is higher than the density of electrons induced in graphene in the second region 16b (see the first embodiment). Therefore, the maximum value E1'of the electron energy in the valence band in the first region 16a is higher than the maximum value E2'of the electron energy in the valence band in the second region 16b. That is, the hole density in the first region 16a is lower than the hole density in the second region 16b.

Therefore, while the voltage V2 is applied to the gate electrode 5, the density of the majority carriers (here, holes) in the first region 16a is lower than the density of the majority carriers in the second region 16b.

The Seebeck coefficient, which indicates the magnitude of the thermoelectric effect, depends on the density of the majority carriers. Therefore, when the gate voltage V2 is applied to the gate electrode 5, the Seebeck coefficient of the first region 16a and the Seebeck coefficient of the second region 16b deviate from each other. Therefore, when the temperature of the light receiving region 10 rises due to light irradiation, a potential difference V _PTE is generated between the first connection region 15a and the second connection region 15b (see "-Generation of potential difference V _PTE due to thermoelectric effect-"). .. The potential difference V _PTE is detected by the voltmeter 220 of the electric signal detection circuit 208.

-Generation of potential difference voltage V _PTE due to thermoelectric effect-
The light emitted to the light receiving region 10 is absorbed by the graphene 12 in the light receiving region 10 and raises the temperature of the light receiving region 10.

On the other hand, the light emitted from above the optical sensor 4 toward the first connection region 15a is blocked by the first electrode 11a and does not reach the first connection region 15a. Similarly, the light emitted from above the optical sensor 4 toward the second connection region 15b does not reach the second connection region 15b. Therefore, irradiation of the first and second connection regions 15a and 15b does not raise the temperature of the first and second connection regions 15a and 15b.

Therefore, when light is irradiated from the front surface side of the silicon substrate 7 toward the entire graphene 12 instead of from the back surface side, the temperature rises in the center of the light receiving region 10 and the first and second connections are made at both ends of the light receiving region 10. The temperature rise is suppressed by the regions 15a and 15b. As a result, a temperature gradient is generated in the first region 16a and the second region 16b. Even when light is irradiated only to the central portion of the light receiving region 10, a temperature gradient TG naturally occurs in the first region 16a and the second region 16b.

When the light receiving region 10 in which the Seebeck coefficient of the first region 16a and the Seebeck coefficient of the second region 16b deviate from each other due to the application of the voltage V2 is irradiated with light and a temperature gradient TG is generated, the first connection region 15a and the second are generated by the thermoelectric effect. A potential difference V _PTE occurs between the connection regions 15b. In other words, when light is irradiated to the light receiving region 10 in which regions having different Seebeck coefficients are generated by applying the voltage V2 to the gate electrode 5, a potential difference V _PTE is generated by the pyroelectric effect.

-sensitivity-
As is clear from the above description, the sensitivity of the photodetector 202 can be controlled by the gate voltage Vg. The gate voltage Vg of the second embodiment is also set so that the sensitivity of the photodetector 202 becomes a specific value (that is, the target sensitivity), similarly to the gate voltage Vg of the first embodiment.

When the target sensitivity is a positive value, the target sensitivity of the second embodiment is preferably 0.5 V / W or more. More preferably, the target sensitivity is 0.7 V / W or more. Most preferably, the target sensitivity is 0.9 V / W or more. The upper limit of the target sensitivity is the maximum value of the sensitivity of the photodetector 202 (for example, the peak value P2 in FIG. 14 described later).

When the target sensitivity is a negative value, the target sensitivity of the second embodiment is preferably −0.5 V / W or less. More preferably, the target sensitivity is −0.7 V / W or less. Most preferably, the target sensitivity is −0.9 V / W or less. The lower limit of the target sensitivity is the minimum value of the sensitivity of the photodetector 202.

(3) Modification example (3-1) Modification example 1
In the example described with reference to FIG. 13, when no voltage is applied to the gate electrode 5, the conductive type of the light receiving region 10 is p type. However, the conductive type of the light receiving region 10 may be an n type when no voltage is applied to the gate electrode 5. In this case, the carriers induced in the light receiving region 10 by applying the voltage V2 to the gate electrode 5 are holes.

Alternatively, the conductive type of the light receiving region 10 may be i type when no voltage is applied to the gate electrode 5. In this case, the carrier induced in the light receiving region 10 by applying the voltage V2 to the gate electrode 5 may be either an electron or a hole. According to the variant example 1, the variation of the photodetector 202 increases.

(3-2) Modification 2
In the above example, while the voltage V2 is applied to the gate electrode 5, the conductive type of the first region 16a and the second region 16b are both n-type or p-type. However, while the voltage V2 is applied to the gate electrode 5, one of the conductive types of the first region 16a and the second region 16b may be n-type and the other may be p-type.

Since the Seebeck coefficient depends not only on the carrier density of the thermoelectric exchange material but also on the conductive type, it is possible to detect the light radiated to the light receiving region 10 by the modification 2.

As is well known, the sensitivity of the temperature sensor to which the n-type thermoelectric exchange material and the p-type thermoelectric exchange material are connected is higher than the sensitivity of the temperature sensor to which the thermoelectric exchange material of the same conductive type is connected. Therefore, according to the second modification, the sensitivity of the photodetector 202 can be improved.

Since the pn junction is formed in the light receiving region 10 of the modification 2, the electric signal output from the optical sensor 4 includes a voltage generated by the photovoltaic effect. However, in the second modification, since the reverse bias voltage is not applied to the light receiving region 10, in many cases, the voltage due to the photovoltaic effect is dominant over the voltage due to the photovoltaic effect.

FIG. 14 is a diagram showing an example of the relationship between the sensitivity R2 of the photodetector 202 and the gate voltage Vg when the light receiving region 10 is irradiated with light having a specific wavelength (hereinafter referred to as irradiation light). The wavelength of the irradiation light is, for example, 8 μm. The intensity of the irradiation light is, for example, 1 W / cm ² .

The horizontal axis is the gate voltage Vg. The gate voltage Vg in FIG. 14 is the difference (= Φ1-Φ2) between the potential Φ1 of the gate electrode 5 and the potential Φ2 of the graphene 12. The vertical axis is the sensitivity R2 of the photodetector 202. The sensitivity of the photodetector 202 is the intensity a of the electric signal (voltage in the second embodiment) output by the optical sensor 4 in response to the light emitted to the light receiving region 10 and the light emitted to the light receiving region 10. The ratio of the intensity b (= a / b).

In the region 240 where the gate voltage Vg is small, the conductive types of the first region 16a and the second region 16b are not inverted (see FIG. 13). Therefore, in the region 240 where the gate voltage Vg is small, a pn junction is not formed in the light receiving region 10. Therefore, in the region 240, the absolute value of the sensitivity R2 of the photodetector 202 is not so large.

In a region where the gate voltage Vg is too large (not shown), the conductive type of both the first region 16a and the second region 16b is inverted, so that a pn junction is not formed in the light receiving region 10. Even in this region, the absolute value of the sensitivity R2 of the photodetector 202 is not so large.

In the region 242 where the gate voltage Vg is not too small and not too large, only the conductive type of the first region 16a is inverted to form a pn junction. When the pn junction is formed, the absolute value of the sensitivity R2 increases significantly. Therefore, a large peak 236 appears on the curve 235 showing the relationship between the gate voltage Vg and the sensitivity R2. The peak value P2 of the sensitivity R2 (that is, the sensitivity having the maximum absolute value among the sensitivities R2) is, for example, 1 V / W.

Since the voltage V2 applied to the gate electrode 5 is selected from the gate voltage Vg in the region 242, according to the modification 2, the sensitivity of the photodetector 202 can be improved.

In the second embodiment, by applying one voltage V2 between the light receiving region 10 including the regions having different fill factors and the gate electrode 5, an asymmetric carrier distribution is induced in the light receiving region 10 and the Seebeck coefficient is different. A region is formed in the light receiving region 10. Therefore, according to the second embodiment, as in the first embodiment, it is possible to realize a graphene photodetector capable of photodetection only by applying one voltage V2 to one gate electrode 5.

Although the embodiments of the present invention have been described above, the first and second embodiments are exemplary and not restrictive. For example, in the above example, the fill factor of the first region 16a is smaller than the fill factor of the second region 16b. However, the fill factor of the first region 16a may be larger than the fill factor of the second region 16b.

Further, in the above example, the electrodes provided on the graphene 12 (that is, the first electrode 11a and the second electrode 11b) are band-shaped electrodes. However, the shape of the electrode provided on the graphene 12 is not limited to the band shape. The shape of the electrode provided on the graphene 12 may be, for example, a comb-shaped electrode.

The following additional notes will be further disclosed with respect to the above embodiments 1 and 2.

(Appendix 1)
It has a graphene containing a light receiving region in which a first region provided with a hole is arranged on one end side and a second region different from the first region is arranged on the other end side, and a gate electrode facing the light receiving region. Then, an optical sensor that outputs an electric signal in response to the light radiated to the light receiving area, and
A gate voltage application circuit for applying a gate voltage is provided between the light receiving region and the gate electrode.
The ratio of the area of the first region other than the hole to the area of the first region is smaller than the ratio of the area of the region other than the hole of the second region to the area of the second region.
The gate voltage is a photodetector in which the ratio of the intensity of the electric signal to the intensity of the light is set to a specific value.

(Appendix 2)
The conductive type of the light receiving region is n type or p type when no voltage is applied between the light receiving region and the gate electrode.
The description in Appendix 1 characterized in that, by applying the gate voltage between the light receiving region and the gate electrode, the conductive type in the first region is inverted and the conductive type in the second region is maintained. Photodetector.

(Appendix 3)
Further, the potential of one of the first region and the second region where the conductive type is n type while the gate voltage is applied between the light receiving region and the gate electrode is set as described above. It has a current detection circuit that detects a current flowing in the light receiving region while applying a voltage higher than the potential of the other of the first region and the second region to both ends of the light receiving region.
The photodetector according to Appendix 2, wherein the electric signal is the current detected by the current detection circuit while the gate voltage is applied between the light receiving region and the gate electrode. ..

(Appendix 4)
The photodetector according to Appendix 3, wherein the absolute value of the specific value is 0.5 mA / W or more.

(Appendix 5)
Further, it has a voltage detection circuit for detecting a potential difference generated between a first connection region contained in the graphene and in contact with the first region and a second connection region included in the graphene and in contact with the second region.
The light according to Appendix 1 or 2, wherein the electric signal is the potential difference detected by the voltage detection circuit while the gate voltage is applied between the light receiving region and the gate electrode. Detection device.

(Appendix 6)
The photodetector according to Appendix 5, wherein the absolute value of the specific value is 0.5 V / W or more.

2,202: Photodetector 4: Photosensor 5: Gate electrode 6: Gate voltage application circuit 8,208: Electrical signal detection circuit 10: Light receiving area 12: Graphene 14: Hole 15a: First connection area 15b: Second connection Region 16a: First region 16b: Second region

Claims (4)

It has a graphene containing a light receiving region in which a first region provided with a hole is arranged on one end side and a second region different from the first region is arranged on the other end side, and a gate electrode facing the light receiving region. Then, an optical sensor that outputs an electric signal in response to the light radiated to the light receiving area, and
A gate voltage application circuit for applying a gate voltage is provided between the light receiving region and the gate electrode.
The ratio of the area of the first region other than the hole to the area of the first region is smaller than the ratio of the area of the region other than the hole of the second region to the area of the second region.
The gate voltage is a photodetector in which the ratio of the intensity of the electric signal to the intensity of the light is set to a specific value. The conductive type of the light receiving region is n type or p type when no voltage is applied between the light receiving region and the gate electrode.
The first aspect of the present invention is characterized in that, by applying the gate voltage between the light receiving region and the gate electrode, the conductive type in the first region is inverted and the conductive type in the second region is maintained. Photodetector. Further, the potential of one of the first region and the second region where the conductive type is n type while the gate voltage is applied between the light receiving region and the gate electrode is set as described above. It has a current detection circuit that detects a current flowing in the light receiving region while applying a voltage higher than the potential of the other of the first region and the second region to both ends of the light receiving region.
The photodetection according to claim 2, wherein the electric signal is the current detected by the current detection circuit while the gate voltage is applied between the light receiving region and the gate electrode. Device. Further, it has a voltage detection circuit for detecting a potential difference generated between a first connection region contained in the graphene and in contact with the first region and a second connection region included in the graphene and in contact with the second region.
The electric signal according to claim 1 or 2, wherein the electric signal is the potential difference detected by the voltage detection circuit while the gate voltage is applied between the light receiving region and the gate electrode. Photodetector.

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