The present invention relates to a photoelectric conversion element material that is used for light sensors and the like and particularly to a photoelectric conversion element material provided with a light-receiving layer including a predetermined metal chalcogenide on a base material. In addition, the present invention relates to an ink where semiconductor nanoparticles are dispersed, the semiconductor nanoparticles being suitable for forming light-receiving layers in photoelectric conversion element materials.
As a configuration material of photoelectric conversion elements or light-emitting elements that are mounted in a variety of optical semiconductor devices such as solar cells, light sensors and light-emitting devices (LEDs), the use of semiconductor nanoparticles that are referred to as quantum dots (QDs) is expected. Semiconductors develop a quantum confinement effect when being composed of nano-scale fine particles and have a band gap based on the particle diameters. Therefore, the adjustment of the band gap by controlling the composition and particle diameters of semiconductor nanoparticles makes it possible to arbitrarily set light-emitting wavelengths or absorption wavelengths.
Semiconductor nanoparticles are capable of contributing to the size reduction and thickness reduction of semiconductor devices including a photoelectric conversion element as a light-receiving element. For example, in photoelectric conversion portions of CMOS image sensors that have been conventionally mounted in video cameras, mobile phone cameras and the like, silicon photodiodes have been in use. In this CMOS image sensor, it is required to form a silicon thin film having a certain degree of thickness (2 to 3 μm) for light absorption that is necessary for sensor driving. However, semiconductor nanoparticles have a high quantum efficiency and also have a characteristic of a high absorption coefficient. This makes it possible to make the thicknesses of light-receiving elements in CMOS image sensors thinner (less than 1 μm) than those with existing techniques.
In addition, the characteristics of semiconductor nanoparticles the light-emitting and absorption wavelengths of which can be adjusted can be a starting point of the development of photoelectric conversion elements intended for light in a wavelength range which has been difficult to handle with conventional semiconductor materials. Particularly, in recent years, there has been a demand for the development of a photoelectric conversion element having responsiveness to light in the near infrared region. Examples of the photoelectric conversion element in which near infrared light is used include light-receiving elements that are applied to LIDAR (light detection and ranging) or short-wave infrared (SWIR) image sensors. LIDAR refers to a remote sensing system in automobile self-driving, drones, ships and the like. LIDAR is a measurement system in which a subject is irradiated with laser light, a reflected light is sensed with a light-receiving element and the distance or angle of the subject is detected. LIDAR is deemed to be an important device in the recent development of self-driving techniques. In addition, SWIR image sensors are also devices the demand for which in the future is expected to increase in the fields of food inspection, the agricultural field, drones and the like.
Photoelectric conversion elements such as LIDAR or SWIR image sensors exemplified above are required to have favorable response characteristics to light in the near infrared region. Regarding this, it was difficult for conventional semiconductor materials to meet this requirement. Silicon that is used in the above-described CMOS image sensors has a difficulty in responding to near infrared light owing to its band gap value. Therefore, the effectiveness of semiconductor nanoparticles is also expected from the viewpoint of such a response to near infrared light.
Japanese Patent Application Laid-Open No. 2020-40847
Japanese Patent Application Laid-Open No. 2020-15802
At the moment, there are not so many reported cases regarding semiconductor nanoparticles having responsiveness to light in the near infrared region. While it is possible to adjust the band gap of semiconductor nanoparticles by controlling the particle diameters, the adjustable range is based on the band gap of a semiconductor that configures the nanoparticles. Based on the photon energy formula (E=hc/λ (h: Planck constant, c: speed of light, λ: wavelength)), the band gap of semiconductor nanoparticles needs to be approximately 1.77 eV or less in order to acquire responsiveness in the near-infrared region (the wavelength region is set to 700 nm to 2500 nm). However, there are not so many semiconductor materials with such a narrow band gap.
As semiconductors that configure semiconductor nanoparticles, metal chalcogenides, which are binary or tertiary compounds of one or two metals belonging to transition metals (Pb, Cd or the like) and a chalcogen element except oxygen (S, Se, Te or the like) are known. As a metal chalcogenide that has responsiveness to near infrared light and has been successfully put into practical use when made into semiconductor nanoparticles, PbS is known. However, PbS includes Pb, which makes it hard to say that PbS is a suitable semiconductor material owing to the recent environmental issues and the like. Therefore, studies of the configurations and compositions of semiconductor materials that satisfy this requirement become necessary.
In addition, even when metal chalcogenides having a response characteristic to near infrared light have been found and it has become possible to manufacture semiconductor nanoparticles of the metal chalcogenide, additional studies regarding element materials having a high photoresponse characteristic in consideration of practicality are also required. As an aspect for applying semiconductor nanoparticles to photoelectric conversion elements and the like, semiconductor thin films, which serve as light-receiving layers, have been formed by dispersing semiconductor nanoparticles in an appropriate dispersion medium to produce an ink (dispersion) and applying this ink to a base material. In order to improve the response characteristic of photoelectric conversion elements to near infrared light, the characteristics of semiconductor nanoparticles are important, but the characteristics of the semiconductor nanoparticles when made into thin films as described above become more important.
The present invention has been made based on the above-described background, and an objective of the present invention is to propose semiconductor nanoparticles including a metal chalcogenide having a light absorption property in the near infrared region and to provide a photoelectric conversion element material that includes a semiconductor thin film formed of these semiconductor nanoparticles and is provided with a light-receiving layer having excellent photoresponsivity. In addition, an ink including the above-described semiconductor nanoparticles and a method for producing a semiconductor thin film having a suitable configuration using this ink will also be clarified.
In order to solve the above-described problems, first, the present inventors studied the composition of a metal chalcogenide having a suitable band gap and being capable of exhibiting responsiveness in the near infrared region when made into semiconductor nanoparticles. In addition, the present inventors paid attention to AgBiS2 and Ag2S, which are Ag-based chalcogenides. These Ag-based chalcogenides have a band gap of 1 eV or less in a bulk state and are thus considered to be capable of exhibiting responsiveness to near infrared light when made into semiconductor nanoparticles.
Therefore, the present inventors confirmed the near infrared light absorption properties of semiconductor nanoparticles including AgBiS2 and Ag2S and also confirmed that semiconductor nanoparticles can be made into inks in a suitable state and, furthermore, can be formed into semiconductor thin films, which serve as light-receiving layers. In addition, based on these studies, the present inventors performed the configurations and studies of thin films having improved responsiveness to near infrared light regarding AgBiS2 thin films and Ag2S thin films formed of semiconductor nanoparticles and got an idea of the present invention.
The present invention that solves the above-described problems is a photoelectric conversion element material provided with a base material and a light-receiving layer including a semiconductor film formed on the base material, in which the semiconductor film includes Ag2−xBixSx+1 (x is an integer of 0 or 1) and the crystallite diameter of the semiconductor film is 10 nm or more and 25 nm or less.
Hereinafter, the configuration of the photoelectric conversion element material provided with a light-receiving layer including a metal chalcogenide thin film of the present invention and a method for producing the material will be described. As described above, the photoelectric conversion element material of the present invention includes a base material and a light-receiving layer on the base material as a basic configuration.
The base material is a member for supporting the light-receiving layer including a semiconductor film of a metal chalcogenide. The base material may be any material as long as the material is capable of achieving this objective. Examples of material for the base material include glass, quartz, silicon, ceramic, and metal. In addition, the shape and dimension of the base material are not particularly limited.
The semiconductor film that configures the light-receiving layer in the photoelectric conversion element material of the present invention is a thin film including Ag2−xBixSx+1 (x is 0 or 1), which is a Ag-based metal chalcogenide, that is, AgBiS2 or Ag2S. The band gaps of these metal chalcogenides are less than 1 eV, that is, 0.8 eV (AgBiS2) and 0.9 eV (Ag2S) in a bulk state, and thus the nanoparticles of these metal chalcogenides are considered to have responsiveness in the near infrared region.
The light-receiving layer including the semiconductor film is a thin film that is formed by depositing the nanoparticles of AgBiS2 or Ag2S. In the present invention, for improving the photoresponsivity, the crystallite diameter of the semiconductor nanoparticles of AgBiS2 or Ag2S in the thin film is regulated. The crystallite diameter is the largest region that can be regarded as a single crystal in the semiconductor nanoparticles. The semiconductor nanoparticles in the thin film of the present invention are polycrystalline substances or single-crystal substances, and the crystallite diameter is smaller than or equal to the particle diameters of the semiconductor nanoparticles. In the present invention, the crystallite diameter of AgBiS2 or Ag2 S is set to 10 nm or more and 40 nm or less. The reason for the photoresponsivity being related to the crystallite diameter in the light-receiving layer including a semiconductor of the present invention is not clear, but the present inventors assume that enhancement of crystallinity optimizes the crystal structure of AgBiS2 or Ag2S. In a state where the crystallite diameter of AgBiS2 or Ag2 S is less than 10 nm, the crystallinity is low, there is no difference from a state before the formation of the thin film (a state of the semiconductor nanoparticles in an ink), and there is no effect of improving the photoresponsivity. On the other hand, in a state where the crystallite diameter of AgBiS2 or Ag2S exceeds 40 nm, it is considered that the coarsening of AgBiS2 particles or Ag2 S particles or the decomposition of a compound occurs partially, and, in this case as well, the photoresponsivity deteriorates. The crystallite diameter of AgBiS2 and Ag2S is more preferably nm or more and 25 nm or less.
The crystallite diameter is the minimum unit capable of contributing to diffraction when a substance is irradiated with X-rays and thus can be measured by X-ray diffraction (XRD). Regarding the present invention, when the crystallite diameter of the light-receiving layer is measured by XRD, in AgBiS2, diffraction peaks are shown at 2θ=near 27° and near 31° owing to CuKα rays. In addition, in Ag2S, diffraction peaks are shown at 2θ=near 26° and near 38° owing to CuKα rays. In the present invention, it is preferable to measure the crystallite diameters of AgBiS2 and Ag2S based on the diffraction peaks at 2θ=near 31° and 2θ=near 38°, respectively. As described below, in the present invention, the crystallite diameter can be adjusted by performing a thermal treatment on the thin film of AgBiS2 or Ag2S at a predetermined temperature. In AgBiS2 or Ag2S, what can be clearly confirmed at any thermal treatment temperature is the peak at 2θ=near 38°. The crystallite diameter can be calculated based on the Scherrer equation by calculating the full-width at half maximum of the diffraction peak.
In addition, the surface roughness of the light-receiving layer in the photoelectric conversion element material of the present invention is preferably 2 nm or more and 15 nm or less. An increase in surface roughness is considered to affect the distance between particles. In photoelectric conversion elements, the distance between particles acts on the efficiency of the transfer of electrons between the particles, and thus the surface roughness is preferably set within the above-described range. In addition, the thickness of the light-receiving layer including the semiconductor thin film is preferably set to 10 nm or more.
The photoelectric conversion element material of the present invention has an absorption property and responsiveness with respect to light in the near infrared region. It is preferable that the photoelectric conversion element material has responsiveness with respect to light in the near-infrared region where the wavelengths are 700 nm or more and 1200 nm or less. This characteristic is attributed to the band gap of AgBiS2 or Ag2S, which is the semiconductor that forms the light-receiving layer.
Therefore, the photoelectric conversion element material of the present invention is applied to semiconductor devices that handle light having wavelengths in the near infrared region, and the applications are not particularly limited. For example, the photoelectric conversion element material can be used as a semiconductor material in a broad range of applications such as light-receiving elements, optical sensors and light detectors. In particular, the photoelectric conversion element material has excellent light sensitivity in the near infrared region and is thus suitable for light-receiving elements such as LIDAR and SWIR image sensors.
In the producing of the photoelectric conversion element material of the present invention, it is necessary to form a semiconductor thin film (AgBiS2 thin film or Ag2S thin film), which serves as the light-receiving layer, on the above-described base material. In the present invention, the AgBiS2 thin film or Ag2 S thin film is formed by applying an ink in which the semiconductor nanoparticles of AgBiS2 or Ag2 S are dispersed. In addition, in order to set the crystallite diameter of the above-described semiconductor within a preferable range, a treatment of firing a semiconductor layer after the application and enhancing the crystallinity is performed. Hereinafter, these characteristic portions will be described.
In the present invention, an ink containing semiconductor nanoparticles dispersed in a dispersion medium is applied. The semiconductor nanoparticles include Ag2−xBixSx+1 (x is 0 or 1). These semiconductor nanoparticles that disperse in the ink have particle diameters of 3 nm or more and 20 nm or less and have a crystallite diameter of 3 nm or more and 20 nm or less. The reason for regulating the particle diameters of the semiconductor nanoparticles as described above is to have a band gap in the near-infrared region while holding the quantum confinement effect of quantum dots. In addition, the crystallite diameter is the maximum value of regions that are regarded as single crystals in the semiconductor nanoparticles and is thus deemed to be preferably as large as possible within the above-described particle diameter range.
The semiconductor nanoparticles are dispersed in the dispersion medium in a state protected by a protective agent. The protective agent is an additive for suppressing the agglomeration and coarsening of the semiconductor nanoparticles and stabilizing the dispersion state. The agglomeration and coarsening of the semiconductor nanoparticles affects the response characteristic when the semiconductor nanoparticles are applied to the base material and made into the light-receiving layer and thus needs to be avoided at all costs. The protective agent is an organic compound that bonds to the semiconductor nanoparticles and suppresses the agglomeration of the nanoparticles caused by the repulsive force between the protective agents.
The protective agent in the ink of the present invention is composed of at least any one of a long-chain alkylamine, a long-chain carboxylic acid and a thiol. Specifically, the long-chain alkylamine refers to a linear or branched alkylamine having 6 or more carbon atoms. Specific examples of a preferable alkylamine include octylamine (having 8 carbon atoms), decylamine (having carbon atoms), dodecylamine (having 12 carbon atoms), tetradecylamine (having 14 carbon atoms), and oleylamine (having 18 carbon atoms). In addition, the carboxylic acid is a linear or branched carboxylic acid having 6 or more carbon atoms. Specific examples of a preferable carboxylic acid include octanoic acid (having 8 carbon atoms), lauric acid (having 12 carbon atoms), myristic acid (having 14 carbon atoms), and oleic acid (having 18 carbon atoms). In addition, the thiol is a linear or branched thiol having 6 or more carbon atoms. Specific examples of a preferable thiol include octanethiol (having 8 carbon atoms), dodecanethiol (having 12 carbon atoms), and octadecanethiol (having 18 carbon atoms). A protective agent produced by combining one or more long-chain alkylamines, long-chain carboxylic acids or thiols as described above can be applied.
As the dispersion medium of the semiconductor nanoparticle ink, an organic solvent with a low polarity is used. Specifically, each of toluene, hexane, chloroform, dichloromethane, cyclohexane, octanol and the like or a solvent mixture of the organic solvents is preferable.
The semiconductor nanoparticle ink of the present invention can be produced by synthesizing the nanoparticles of AgBiS2 and Ag2S in advance and dispersing these in the dispersion medium. Regarding the AgBiS2 nanoparticles, sulfur or a sulfur compound is added to a solution mixture obtained by mixing a Ag salt (for example, silver acetate, silver oxalate, silver nitrate, silver carbonate, silver diethyldithiocarbamate or the like) and a Bi salt (bismuth acetate, bismuth nitrate or the like) with the protective agent and reacted, whereby AgBiS2 nanoparticles to which the protective agent bonds are synthesized. In addition, the Ag2S nanoparticles can be synthesized by mixing and reacting a sulfur compound (thiourea or sulfur), together with the protective agent, with the same Ag salt as described above. Both nanoparticles can be made into an ink by separating the nanoparticles from a reaction liquid after the synthesis, appropriately washing the nanoparticles and then adding the nanoparticles to the dispersion medium.
The light-receiving layer including the semiconductor film in the present invention can be formed by applying the above-described ink containing the semiconductor nanoparticles dispersed therein to the base material and firing the ink. A method for applying the ink is preferably a spin coating method in order to uniformly deposit the semiconductor nanoparticles on the base material. It is preferable to repeat this application of the ink twice or more times. Regarding the conditions of the application, it is preferable to perform the application at a rotation speed of 500 to 5000 rpm for a rotation time of 10 to 300 seconds.
In addition, in the present invention, a firing treatment is performed after the application of the semiconductor nanoparticle ink, whereby a semiconductor nanoparticles light-receiving layer having suitable photoresponsivity is produced. In this firing step, the crystallinity of the semiconductor nanoparticles (AgBiS2 nanoparticles and Ag2S nanoparticles) on the base material is enhanced by heating, and the crystallite diameter is made to be within the above-described preferable range. The firing temperature at this time is set to 200° C. or higher and 350° C. or lower. At lower than 200° C., the crystallite diameter does not fall into the predetermined range, and the effect of improving responsiveness is weak. In addition, since the protective agent adsorbed to the particle surfaces does not sufficiently volatilize, charges around the particles become biased, and a state where the quantum confinement effect has been impaired is formed. When the firing temperature is set to 200° C. or higher, the crystallinity improves, and an effect of improving the responsiveness is expected. At this time, while there is a possibility that the protective agent may slightly remain on the particle surfaces, the protective agent is removed in a quantity large enough to prevent the quantum confinement effect from being impaired. However, when the upper limit of the firing temperature exceeds 350° C., the crystallite diameter becomes large owing to excessive crystallization. In addition, there is a concern of the precipitation of Ag caused by the decomposition of the compound or the breakage of the semiconductor film caused by the generation of a compound diverging from a desired chemical composition or the like. This firing treatment is preferably performed in an inert gas (nitrogen, argon or the like), and the treatment time is preferably set to 0.5 hours or longer.
The firing temperature of the semiconductor nanoparticles after the application of the ink is more preferably from 200° C. to 250° C. Even with the firing treatment at 250° C. or higher, an effect of improving a photoresponse is expected from the viewpoint of crystallinity. However, for AgBiS2 in particular, the firing treatment at 250° C. or higher is a treatment that is performed beyond the three-phase eutectic point, and once dissolves the semiconductor particles, and thus the stability of the film may be affected.
When the above-described firing step has been completed, a light-receiving layer including a semiconductor thin film having a predetermined crystallite diameter is formed. In addition, when wires enabling the electrical connection with the light-receiving layer are formed as appropriate, it is possible to produce a photoelectric conversion element.
As described above, the present invention relates to a photoelectric conversion element material including a light-receiving layer composed of Ag2−xBixSx+1 (x is an integer of 0 or 1), which is a metal chalcogenide. This light-receiving layer is composed of the semiconductor nanoparticles of the above-described metal chalcogenide and has photoresponsivity in the near infrared region. In particular, when the crystallite diameter of the light-receiving layer including a semiconductor is set within a predetermined range, the responsiveness to light in the near infrared region improves.
First Embodiment: Hereinafter, an embodiment of the present invention will be described. In the present embodiment, a photoelectric conversion element material provided with a light-receiving layer including AgBiS2 as a semiconductor material was produced. Semiconductor nanoparticles of AgBiS2 were synthesized to produce an ink, this ink was applied to and fired on a base material to form a light-receiving layer, thereby producing a photoelectric conversion element material. Subsequently, the morphology of a thin film, which served as the light-receiving layer, was observed and the photoresponse characteristic of a photoelectric conversion element was evaluated.
133.5 mg of silver acetate (Ag(OAc)), 386 mg of bismuth acetate (Bi(OAc)3) and 5.5 mL of oleic acid were mixed together, the inside of a mixing container was substituted with a N2 gas, and then the liquid mixture was stirred at 100° C. for one hour. A solution containing 33 mg of sulfur dissolved in 5 mL of oleylamine was added to this liquid mixture and reacted. During the reaction, the liquid mixture was left to stand and cooled. Subsequently, AgBiS2 nanoparticles were separated and extracted with acetone, and the extraction liquid was centrifuged to collect the AgBiS2 nanoparticles. Furthermore, the collected nanoparticles were mixed with toluene, again, extracted and centrifuged with acetone, thereby collecting the AgBiS2 nanoparticles. These were added to toluene, which was a dispersion medium, to produce an ink (nanoparticle concentration: 0.04 M). This ink was black.
[Measurement of Particle Diameters and Crystallite diameter of AgBiS2 Nanoparticles]
The particle diameters and crystallite diameter of the AgBiS2 nanoparticles in the ink produced above were studied. In this study, the AgBiS2 nanoparticles were observed with a transmission electron microscope (TEM) to measure the particle diameters (average particle diameter). In addition, the AgBiS2 nanoparticles were supported by a SiO2 powder from the ink and measured in a dry state. An XRD analyzer was Ultima IV produced by Rigaku Corporation, CuKα rays were used as characteristic X rays, and 0.1°/m in. was set as an analysis condition.
Next, the differential scanning calorimetry (DSC) of the AgBiS2 nanoparticles was performed. The result is shown in
In order to confirm the optical semiconductor characteristic of the AgBiS2 nanoparticles produced in the present embodiment, the light absorption characteristic was evaluated. The light absorption characteristic of a solution obtained by diluting the above ink 100 times was analyzed with a UV-Vis-NIR Spectrophotometer (UV-3600i Plus produced by Shimadzu Corporation).
The absorption spectrum of the AgBiS2 ink is shown in
After a variety of characteristics of the above AgBiS2 nanoparticles and ink were confirmed, this ink was applied to a base material to form a light-receiving layer, thereby producing a photoelectric conversion element material. As the base material, a silicon wafer (dimensions: 25×25, thickness: 0.6 mm) was prepared, and the above ink was applied to this base material. The application of the ink was performed by the spin coating method, the ink was dropped and applied onto the base material at a rotation speed of 2000 rpm (30 seconds) to form a semiconductor layer. In the present embodiment, this application step was repeated three times, and the amount of the ink applied per step was set to 0.1 mL (the mass of the nanoparticles: 2.8 mg).
After the application of the AgBiS2 ink, the semiconductor layer was made into a light-receiving layer by a firing treatment. The firing treatment was performed in a nitrogen atmosphere at seven patterns of the treatment temperature set to 150° C., 200° C., 250° C., 300° C., 350° C., 400° C. and 500° C. The treatment time was set to 0.5 hours.
For seven photoelectric conversion elements produced by the above-described seven patterns of firing, XRD analyses were performed on semiconductor thin films that configured the light-receiving layers, and the crystallite diameters were calculated. In the XRD analyses, the thin films on the silicon wafers were measured as they were. The XRD analyses were performed with the same device under the same conditions as those in the analysis of the nanoparticles. In addition, the images of the surface morphologies of the light-receiving layers were captured and the surface roughness was measured with an atomic force microscope (AFM: NANOCUTE produced by Hitachi High-Tech Science Corporation).
From Table 1, it can be seen that, as the temperature of the firing treatment increases, the crystallite diameter of the thin film becomes larger.
Particularly, at 200° C. or higher, improvement in the crystallinity is shown. However, when the firing temperature reaches 500° C., from the fact that the peak at near 31° vanishes in smoke and a Ag-derived peak near pure 38.3° becomes clear, it can be seen that the decomposition of AgBiS2 occurs at this firing temperature.
In addition, when the relationship between the firing temperature and the surface roughness of the thin film is observed, the surface roughness does not change at firing temperatures of up to 200° C., the surface roughness increases at 250° C. to 300° C., and the surface roughness once returns to the original at 300° C. to 350° C.
This is considered to be related to the fact that, during the firing at a temperature exceeding the three-phase eutectic point of AgBiS2, which was confirmed in the DSC analysis of the AgBiS2 nanoparticles (near 250° C. to 260° C.), the AgBiS2 nanoparticles once dissolve. Therefore, it is deemed that there is no complete proportional relationship between the firing temperature and the surface roughness. However, when the firing temperature exceeds 400° C., the surface roughness increases at once, and the AgBiS2 particles coarsen. This point matches the fact that, in the XRD diffraction profiles, the diffraction peaks at near 27° rapidly increase at 400° C. In addition, during the firing at 500° C., even when the surface roughness decreases owing to the decomposition of AgBiS2, the AgBiS2 particles become islands.
After the configurations of the light-receiving layers were confirmed as described above, as a preliminary evaluation of the optical semiconductor characteristics of the photoelectric conversion element materials produced in the present embodiment, the photoluminescence (PL) was measured. Here, the measurement was performed using the photoelectric conversion element materials produced by the firing treatments performed at 150° C., 200° C. and 300° C. The PL measurement was conducted using LabRam Aramis produced by Horiba, Ltd. as the measurement device within a range of 500 to 1000 nm as a measurement condition.
The PL measurement result of each photoelectric conversion element material is shown in
For the photoelectric conversion element materials produced in the present embodiment, the photoresponse characteristics were evaluated. In this evaluation test, the photoelectric conversion element materials produced by the firing treatments at 150° C., 200° C. and 300° C. were used, and an electrode was formed on the light-receiving layer surface of each material by patterning a Ti film (film thickness: 5 nm) and a Au film (film thickness: 40 nm) in this order in a comb shape by a thermal deposition method, thereby producing a sample. In addition, a bias voltage of 0.5 V was loaded with a multimeter connected to the electrode, and a photocurrent owing to pulse irradiation of a near infrared light source was measured. The wavelengths of near infrared rays were set to 740 nm, 850 nm and 940 nm, and the pulse irradiation with the near infrared rays was performed in a manner of 20-second ON/40-second OFF.
These photocurrent measurement results are shown in
Furthermore, in order to confirm the influence of the firing temperature of higher than 350° C., PL measurement and photoresponsivity evaluation were performed on the light-receiving layer produced by the firing treatment at 500° C. These results are shown in
Here, in the present embodiment, comparison with photoelectric conversion elements including a PbS thin film, which has been conventionally known as a metal chalcogenide thin film having responsiveness in the near infrared region, as a light-receiving layer was performed. An ink in which commercially available PbS particles (Sigma-Aldrich) had been dispersed was produced, and this was applied to the same base material as in the present embodiment. In addition, the evaluation test of photoresponsivity was performed in the same manner as described above.
The results are shown in
Next, as the photoresponse characteristic evaluation of the photoelectric conversion element, evaluation was performed when the bias during photocurrent measurement was set to a high bias. In this evaluation, a commercially available Ag nanopaste was applied to the light-receiving layer surface by screen printing, and a wire having a thickness of approximately 1 μm was formed in a comb shape, thereby producing a sample. In addition, a bias voltage of 2.0 V was loaded with a multimeter connected to an electrode, and a photocurrent owing to pulse irradiation of the near infrared light source was measured. The wavelengths of near infrared rays were set to 850 nm and 940 nm, and the pulse irradiation with the near infrared rays was performed in a manner of 10-second ON/10-second OFF.
The results of these photoresponsivity evaluation tests are shown in
Second Embodiment: In the present embodiment, a photoelectric conversion element material provided with a light-receiving layer including Ag2S as a semiconductor thin film was produced. After semiconductor nanoparticles of Ag2S were synthesized and an ink was produced in the same manner as in First Embodiment, the ink was applied to and fired on a base material to manufacture a photoelectric conversion element material.
134 mg of silver acetate, 30.5 mg of thiourea, 11.8 mL of oleylamine and 0.2 mL of dodecanethiol were mixed together, and a liquid mixture was stirred and reacted at 200° C. for 10 minutes. After the reaction, the liquid mixture was left to stand and cooled. Subsequently, Ag2S nanoparticles were separated and extracted with methanol, and the extraction liquid was centrifuged to collect the Ag2S nanoparticles. Furthermore, the collected nanoparticles were mixed with toluene, again, extracted and centrifuged with methanol, thereby collecting the Ag2S nanoparticles. These were added to toluene, which was a dispersion medium, to produce an ink (nanoparticle concentration: 0.04 M). This ink was light brownish transparent.
The particle diameters and crystallite diameters of the Ag2S nanoparticles in the ink produced above were studied. Particle diameter (average particle diameter) measurement and XRD analysis were performed with TEM under the same conditions as in First Embodiment.
The measurement result of the light absorption characteristic of the Ag2 S ink by the same method as in First Embodiment is shown in
After the above-described studies were performed, the Ag2S ink was applied to a base material to form a light-receiving layer, thereby producing a photoelectric conversion element material. The Ag2S ink was applied to a silicon wafer, which was the base material, in the same manner as in First Embodiment. A method for applying the ink was the same as that in First Embodiment. After the application of the Ag2S ink, a firing treatment was performed in the same manner as in First Embodiment, thereby forming a light-receiving layer. The firing treatment was performed in a nitrogen atmosphere at treatment temperatures set to 150° C., 200° C., 250° C., 300° C., 350° C., 400° C. and 500° C.
For seven photoelectric conversion element materials of the present embodiment, XRD analyses were performed on semiconductor thin films that configured the light-receiving layers, and the crystallite diameters were calculated. In addition, the images of the surface morphologies of the light-receiving layers were captured and the surface roughness was measured with an atomic force microscope.
The behaviors of the particles by the firing treatment of the light-receiving layer including the Ag2S thin film of the present embodiment are basically the same as those in the light-receiving layer including the AgBiS2 thin film of First Embodiment. That is, as the temperature of the firing treatment increases, the crystallite diameter of the thin film becomes larger; however, when the firing temperature becomes a high temperature, the decomposition of Ag2S occurs. In the present embodiment, the peak of Ag2S at near 38° when fired at 150° C. was too small to calculate the crystallite diameter. In addition, in the relationship between the firing temperature and the surface roughness of the thin film as well, the surface roughness does not change at firing temperatures of relatively low temperatures, but it is observed that the surface roughness increases during the firing at 250° C. or higher and it is presumed that the crystal structure changes in this firing as well. During the firing at 500° C., Ag2S decomposes, and Ag2S particles become islands.
Furthermore, the PL measurement results of the photoelectric conversion element materials provided with the light-receiving layer including Ag2S produced in the present embodiment are shown in
In addition, for the photoelectric conversion element materials provided with the light-receiving layer including Ag2S produced in the present embodiment, the photoresponse characteristics were evaluated. Here, photocurrents were measured from photoelectric conversion elements produced by the firing treatments at 150° C., 200° C. and 300° C. with the same samples under the same measurement conditions as in the photocurrent measurement under a low bias condition (0.5 V) in First Embodiment.
The photocurrent measurement results of the photoelectric conversion elements provided with the light-receiving layer including Ag2S are shown in
Furthermore, in the present embodiment as well, PL measurement and photoresponsivity evaluation were performed on the light-receiving layers including Ag2S produced by the firing treatment at 500° C. These results are shown in
In addition, comparison between the light-receiving layers including Ag2S of the present embodiment and the light-receiving layer including PbS, which is the related art, is shown in
As described above, the photoelectric conversion element material of the present invention is provided with a semiconductor film including Ag2−xBixSx+1 (x is an integer of 0 or 1), which is a metal chalcogenide, as a light-receiving layer. This light-receiving layer exhibits excellent responsiveness to light in the near infrared region by being imparted with appropriate crystallinity. The present invention is particularly useful as a photoelectric conversion thin film for a light-receiving element for a variety of optical semiconductor devices and is expected to contribute to the size reduction or performance improvement of LIDAR or image sensors as a light-receiving element therefor.
Number | Date | Country | Kind |
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2021-001129 | Jan 2021 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2021/048457 | 12/27/2021 | WO |