JPS6410067B2 - - Google Patents

Description

[Detailed description of the invention]

The present invention relates to light (here, light in a broad sense, including ultraviolet rays, visible rays, infrared rays, X-rays, γ-rays, etc.)
The present invention relates to photoconductive members for electrophotography that are sensitive to electromagnetic waves such as. As a photoconductive material for forming a photoconductive layer in a solid-state imaging device, an electrophotographic image forming member in the image forming field, a document reading device, etc., it is highly sensitive,
Must have a high signal-to-noise ratio [photocurrent (Ip)/dark current (Id)], have absorption spectral characteristics that match the spectral characteristics of the irradiated electromagnetic waves, have fast photoresponsiveness, and have the desired dark resistance value. At times, solid-state imaging devices are required to have characteristics such as being non-polluting to the human body and being able to easily process afterimages within a predetermined time. Particularly in the case of an electrophotographic image forming member incorporated into an electrophotographic apparatus used in an office as a business machine, the pollution-free nature during use is an important point. Based on this point, amorphous silicon (hereinafter referred to as a-Si) is a photoconductive material that has recently attracted attention.
No. 2,855,718 describes its application as an image forming member for electrophotography, and JP-A-55-39404 describes its application to a photoelectric conversion/reading device. However, conventional photoconductive members having a photoconductive layer composed of a-Si have poor electrical, optical, and photoconductive properties such as dark resistance, photosensitivity, and photoresponsiveness, as well as moisture resistance. There are points that can be further improved in terms of usage environment characteristics and stability over time, and practical solid-state imaging devices, reading devices, and electrophotographic images can be used in a wide range of applications. The reality is that forming members and the like cannot be used effectively in consideration of productivity and mass production. For example, when applied to electrophotographic image forming members, it is often observed that residual potential remains during use, and such photoconductive members may become fatigued due to repeated use if used repeatedly for a long time. There have been many inconveniences such as the so-called ghost phenomenon in which an afterimage occurs due to the accumulation of images. Furthermore, for example, according to many experiments conducted by the present inventors, a-Si as a material constituting the photoconductive layer of an electrophotographic image forming member is superior to conventional Se, CdS, ZnO, PVCz, TNF, etc. Although it has many advantages compared to OPC (organic photoconductive material), a-Si has been given characteristics for use in conventional solar cells.
Even when the photoconductive layer of an electrophotographic image forming member having a single-layer photoconductive layer is subjected to charging treatment for electrostatic image formation, dark decay is extremely fast, compared to ordinary electrophotography. The above-mentioned tendency is remarkable in a humid atmosphere, and in some cases, it may not be possible to retain the electrostatic charge at all until the development time.There are some points that can be solved. is known to exist. Therefore, while efforts are being made to improve the properties of the a-Si material itself, efforts are being made to obtain the desired electrical, optical, and photoconductive properties as described above when designing photoconductive members for electrophotography. need to be done. The present invention has been made in view of the above points, and includes a
-As a result of intensive and comprehensive research on Si from the viewpoint of its applicability and applicability as a photoconductive member used in electrophotographic image forming members, we found that Si has a silicon atom as its base material and a hydrogen atom (H ) or a halogen atom (X), so-called hydrogenated amorphous silicon, halogenated amorphous silicon, or halogen-containing hydrogenated amorphous silicon [hereinafter referred to as a- A photoconductive member for electrophotography designed and produced with a layer structure in which a specific barrier layer is provided on a photoconductive layer composed of Si (H, In addition, we found that it is superior in most respects to conventional photoconductive members for electrophotography, and that it has particularly excellent properties as a photoconductive member for electrophotography. It is based on the following points. The present invention has stable electrical, optical, and photoconductive properties at all times, is suitable for all environments with almost no restrictions on usage environments, has excellent resistance to light fatigue, and does not cause deterioration even after repeated use. First, the main object is to provide a photoconductive member for electrophotography in which no or almost no residual potential is observed. Another object of the present invention is to provide a photoconductive member for electrophotography which has high photosensitivity, has a spectral sensitivity region that covers substantially the entire visible light region, and has fast photoresponsiveness. Another object of the present invention is to have charge retention ability during charging processing for electrostatic image formation to such an extent that ordinary electrophotography can be applied very effectively when applied as an image forming member for electrophotography. It is an object of the present invention to provide a photoconductive member for electrophotography which has sufficient electrophotographic properties and has excellent electrophotographic properties with almost no deterioration in the properties observed even in a humid atmosphere. Still another object of the present invention is to provide a photoconductive member for electrophotography that can easily produce high-quality images with high density, clear halftones, and high resolution. The photoconductive member for electrophotography of the present invention includes a support, a photoconductive layer made of an amorphous material containing silicon atoms as a matrix and containing either or both of hydrogen atoms and halogen atoms, and the photoconductive layer. The surface barrier layer is formed of an amorphous material having silicon atoms as a matrix and containing carbon atoms and hydrogen atoms. The photoconductive member for electrophotography of the present invention designed to have the above-described layer structure can solve all of the problems described above, and has extremely excellent electrical, optical, and photoconductive properties. and usage environment characteristics. When used as an electrophotographic image forming member, the photoconductive member for electrophotography of the present invention has excellent charge retention ability during charging processing, has no influence of residual potential on image formation, and can be used in a humid environment. Among them, those with stable electrical properties, high sensitivity, and high signal-to-noise ratio, excellent resistance to light fatigue and repeated use.Furthermore, in the case of electrophotographic image forming members, they have high density and half- A high-quality visible image with clear tones and high resolution can be obtained. Furthermore, in the electrophotographic photoconductive member of the present invention, a-Si (H, X) with high dark resistance has low photosensitivity, and conversely, a-Si (H, 10 ^5Ωcm
In either case, a photoconductive layer with a conventional layer structure could not be applied to an electrophotographic image forming member, but in the case of the present invention, the specified Due to its layered structure, even a-Si ( ^H , Highly sensitive a-
Si (H, Hereinafter, according to the drawings, a photoconductive member for electrophotography of the present invention (hereinafter simply referred to as "photoconductive member") will be described.
This will be explained in detail. FIG. 1 is a schematic configuration diagram schematically shown to explain a basic configuration example of a photoconductive member of the present invention. A photoconductive member 100 shown in FIG. 1 includes a photoconductive layer 102 on a support 101 for photoconductive members,
It has a layered structure consisting of a surface barrier layer 103 provided on the photoconductive layer 102 and in direct contact therewith. The support 101 may be electrically conductive or electrically insulating. Examples of the conductive support include NiCr, stainless steel, Al, Cr, Mo, Au,
Examples include metals such as Nb, Ta, V, Ti, Pt, and Pd, and alloys thereof. As the electrically insulating support, films or sheets of synthetic resins such as polyester, polyethylene, polycarbonate, cellulose acetate, polypropylene, polyvinyl chloride, polyvinylidene chloride, polystyrene, polyamide, glass, ceramic, paper, etc. are usually used. . Preferably, at least one surface of these electrically insulating supports is conductively treated, and another layer is preferably provided on the dielectrically treated surface side. For example, if it is glass, NiCr,
Al, Cr, Mo, Au, Ir, Nb, Ta, V, Ti, Pt,
Conductivity can be imparted by providing a thin film made of Pd, In ₂ O ₃ , SnO ₂ , ITO (In ₂ O ₃ +SnO ₂ ), etc., or if it is a synthetic resin film such as polyester film, NiCr, Al , Ag, Pb, Zn, Ni,
A thin film of metal such as Au, Cr, Mo, Ir, Nb, Ta, V, Ti, Pt, etc. is provided on the surface by vacuum evaporation, electron beam evaporation, sputtering, etc., or the surface is laminated with the metal, Conductivity is imparted to the surface. The shape of the support may be any shape, such as a cylinder, a belt, or a plate, and the shape is determined as desired. For example, the photoconductive member 100 in FIG. If used as an image forming member, it is desirable to have an endless belt shape or a cylindrical shape in the case of continuous high-speed copying. The thickness of the support is determined appropriately so that a desired photoconductive member is formed, but when flexibility is required as a photoconductive member, the support can sufficiently function as a support. It is made as thin as possible within this range. However, in such cases, from the viewpoint of manufacturing and handling of the support, mechanical strength, etc.,
It is considered to be 10μ or more. The surface barrier layer 103 has a function of preventing surface charges from being injected into the photoconductive layer 102 when its surface is subjected to charging treatment. The selection of the material constituting the surface barrier layer 103 and the determination of its layer thickness are determined by the irradiation when the photoconductive member 100 is used in such a way that the electromagnetic waves that the photoconductive layer 102 senses are irradiated from the surface barrier layer 103 side. This is done carefully so that a sufficient amount of the electromagnetic waves generated can reach the photoconductive layer 102 to efficiently cause photocarrier generation. The surface barrier layer 103 is made of a non-photoconductive amorphous material that has silicon atoms and carbon atoms as a matrix and contains hydrogen atoms. When the surface barrier layer 103 is made of the above-mentioned amorphous material, the layer forming method may be a glow discharge method, a sputtering method, an ion implantation method,
This is done by ion plating method, electron beam method, etc. These manufacturing methods are selected and adopted as appropriate depending on factors such as manufacturing conditions, amount of equipment capital investment, manufacturing scale, and desired characteristics of the photoconductive member to be manufactured. It is relatively easy to control the manufacturing conditions for manufacturing a photoconductive member having silicon atoms and carbon atoms,
The glow discharge method or the sputtering method is preferably employed because of the advantages that hydrogen atoms can be easily introduced into the surface barrier layer 103 to be created. Furthermore, in the present invention, the surface barrier layer 103 may be formed by using a glow discharge method and a sputtering method in the same apparatus system. In order to form the surface barrier layer 103 by the glow discharge method, the raw material gas for forming the amorphous material is
If necessary, it is mixed with a dilution gas at a predetermined mixing ratio and introduced into a deposition chamber for vacuum deposition in which the support 101 is installed, and the introduced gas is turned into gas plasma by generating a glow discharge. The support 1
The amorphous material described above may be deposited on 01. In the present invention, SiH ₄ and Si containing Si and H are effectively used as raw material gases for forming the surface barrier layer 103 made of a carbon-based amorphous material. Silicon hydride gas such as silanes such as ₂ H ₆ , Si ₃ H ₈ , Si ₄ H ₁₀ , etc., saturated hydrocarbons containing C and H as constituent atoms, e.g. 1 to 5 carbon atoms, carbon atoms Examples include ethylene hydrocarbons having 2 to 5 carbon atoms, acetylene hydrocarbons having 2 to 4 carbon atoms, and the like. Specifically, saturated hydrocarbons include methane (CH ₄ ), ethane (C ₂ H ₆ ), propane (C ₃ H ₈ ), n
-Butane (n _{- C4H10} ) _, pentane ( _C5H12 ), _ethylene hydrocarbons include ethylene ( _C2H4 ),
Propylene (C ₃ H ₆ ), butene-1 (C ₄ H ₈ ), butene-2 (C ₄ H ₈ ), isobutylene (C ₄ H ₈ ), pentene (C ₅ H ₁₀ ), acetylenic hydrocarbons ,
Examples include acetylene (C ₂ H ₂ ), methylacetylene (C ₃ H ₄ ), butyne (C ₄ H ₆ ), and the like. Examples of the source gas containing Si, C, and H as constituent atoms include alkyl silicides such as Si(CH ₃ ) ₄ and Si(C ₂ H ₅ ) ₄ . In addition to these raw material gases, H
Of course, H ₂ is also effectively used as the raw material gas for introduction. These surface barrier layer forming substances are used to form a barrier layer such that silicon atoms (Si), carbon atoms (C) and hydrogen atoms (H) are contained in a predetermined composition ratio in the surface barrier layer formed. They are selected and used as desired during layer formation. To form the surface barrier layer 103 made of a carbon-based amorphous material by the sputtering method, a single crystal or polycrystalline Si wafer, a C wafer, or a mixture of Si and C is used. This can be carried out by sputtering the wafers in various gas atmospheres, using them as targets. For example, if a Si wafer is used as a target, the raw material gas for introducing carbon atoms (C) and hydrogen atoms (H) is diluted with diluting gas as necessary and placed in a sputtering deposition chamber. The Si wafer may be sputtered by introducing these gases into a gas plasma to form a gas plasma of these gases. Alternatively, sputtering can be carried out in a gas atmosphere containing at least hydrogen atoms (H) by using separate targets for Si and C, or by using a mixed target of Si and C. It is accomplished by doing. As the raw material gas for introducing carbon atoms or hydrogen atoms, the raw material gases shown in the glow discharge example described above can also be used as effective gases in the case of the sputtering method. In the present invention, the diluent gas used when forming the surface barrier layer 103 by a glow discharge method or a sputtering method is a so-called rare gas, for example.
Preferred examples include He, Ne, Ar, and the like. The surface barrier layer 103 in the present invention is carefully formed to provide the desired properties. In other words, materials whose constituent atoms are Si, C, and H can have structural forms ranging from crystalline to amorphous depending on the conditions of their creation, and electrical properties ranging from conductive to semiconductive to insulating. and the properties between photoconductive and non-photoconductive properties,
Therefore, in the present invention, the preparation conditions are strictly selected so that a non-photoconductive amorphous material is formed. The function of the surface barrier layer 103 of the amorphous material constituting the surface barrier layer 103 of the present invention is to prevent surface charges from being injected into the photoconductive layer 102 when the surface thereof is subjected to charging treatment. Because it is a thing,
It is formed to exhibit electrically insulating behavior. An important factor in the layer forming conditions for forming the surface barrier layer 103 made of the amorphous material having the above characteristics is the temperature of the support during layer forming. That is, when forming the surface barrier layer 103 made of the amorphous material on the surface of the photoconductor 102, the temperature of the support during layer formation is an important factor that influences the structure and properties of the formed layer. In the present invention, the temperature of the support during layer formation is strictly controlled so that the amorphous material having the desired properties can be formed as desired. In order to effectively achieve the purpose of the present invention, the temperature of the support when forming the surface barrier layer 103 is appropriately selected in an optimal range in accordance with the method of forming the surface barrier layer 103. Formation of layer 103 is carried out at a temperature typically between 100<0>C and 300<0>C, preferably between 150<0>C and 250<0>C. The formation of the surface barrier layer 103 involves delicate control of the composition ratio of atoms constituting each layer and control of layer thickness, which can be continuously formed from the photoconductive layer 102 to the surface barrier layer 103 in the same system. The glow discharge method and sputtering method are advantageous because they are relatively easy compared to other methods.
When forming the surface barrier layer 103 using these layer forming methods, the discharge power and gas pressure during layer formation, as well as the support temperature described above,
This can be cited as an important factor that influences the characteristics of 03. The discharge power conditions for effectively creating the surface barrier layer 103 with good productivity, which have the characteristics to achieve the purpose of the present invention, are usually 1 to 1.
300W, preferably 2-150W. Furthermore, the gas pressure in the deposition chamber is usually 3×10 ^-3 to 5 Torr, preferably 8×
It is desirable that it be about 10 ^-3 to 0.5 Torr. Surface barrier layer 103 in the photoconductive member of the present invention
The amount of carbon atoms and hydrogen atoms contained in the surface barrier layer 103, as well as the conditions for forming the surface barrier layer 103, are important factors in forming a barrier layer that achieves the desired characteristics to achieve the object of the present invention. The surface barrier layer composed of a-(Si _b C _1-b ) _c H _1-c is
The carbon atom content is usually 30-90 atomic%, preferably 40-90 atomic%, optimally 50-80 atomic%
%, the content of hydrogen atoms is usually 1 to
40 atomic%, preferably 2 to 35 atomic%, optimally 5 to 30 atomic%, expressed as b, c, b
is typically 0.1 to 0.5, preferably 0.1 to 0.35, optimally
0.15-0.3, c is usually 0.60-0.99, preferably 0.65
~0.98, optimally 0.7-0.95. When using the electron beam method, the starting material for forming the barrier layer may be placed in a deposition boat, irradiated with an electron beam, heated and evaporated, and passed through various gas plasmas.
03 has the function of preventing surface charges from being injected into the photoconductive layer 102 when its surface is subjected to charging treatment, and is therefore formed to exhibit electrically insulating behavior. Ru. The numerical range of the layer thickness of the surface barrier layer 103 in the present invention is one of the important factors for effectively achieving the object of the present invention. If the surface barrier layer 103 is too thin, it will not be able to sufficiently prevent surface charges from being injected into the photoconductive layer 102, and if it is too thick, the surface barrier layer will be too thick. Photocarriers generated in the photoconductive layer when irradiated with electromagnetic waves that the photoconductive layer 102 is sensitive to from the layer 103 side are accumulated at the interface between the photoconductive layer and the surface barrier layer, so a special charging exposure process (e.g. NP process). In view of the above points, the thickness of the surface barrier layer 103 to effectively achieve the object of the present invention is usually 30 Å to 5 μm, preferably 50 Å to 2 μm. In the electrophotographic image forming member shown in FIG.
In order to effectively achieve the object of the present invention, the photoconductive layer 102 is made of a-Si having the semiconductor properties shown below.
It is composed of (H, X). p-type a-Si(H,X)...Contains only acceptor. Or one that contains both a donor and an acceptor and has a high concentration of acceptor (Na). A p ^- type a-Si (H, n-type a-Si(H,X)...Contains only a donor. Or one that contains both donor and acceptor and has a high donor concentration (Nd). An n ^- type a-Si (H, i-type a-Si(H,X)...NaNdO or NaNd. In the present invention, specific examples of the halogen atom (X) contained in the photoconductive layer 105 include fluorine, chlorine, bromine, and iodine, with fluorine and chlorine being particularly preferred. I can list them. In the present invention, the photoconductive layer 105 composed of a-Si (H, done by. For example, in order to form a photoconductive layer composed of a-Si (H, Introducing a raw material gas for introducing atoms into a deposition chamber whose interior can be reduced in pressure to generate a glow discharge within the deposition chamber,
A layer made of a-Si (H, In addition, when forming by sputtering method, for example, when sputtering a target formed of Si in an atmosphere of an inert gas such as Ar or He or a mixed gas based on these gases,
A gas for introducing hydrogen atoms and/or halogen atoms may be introduced into the deposition chamber for sputtering. As the Si generation raw material gas used in the present invention, silicon hydride (silanes) in a gaseous state or which can be gasified such as SiH ₄ , Si ₂ H ₆ , Si ₃ H ₈ , Si ₄ H ₁₀ is effective. Among them, SiH ₄ and Si ₂ H ₆ are particularly preferred in terms of ease of handling during layer formation work and good Si generation efficiency. Many halogen compounds are effective as the raw material gas for introducing halogen atoms used in the present invention, such as halogen gas, halides, interhalogen compounds, halogen-substituted silane derivatives, etc. Preferred examples include halogen compounds that can be gasified. Furthermore, silicon compounds containing silicon atoms and halogen atoms, which are in a gaseous state or can be gasified, are also effective in the present invention. Specifically, halogen compounds that can be suitably used in the present invention include fluorine, chlorine, bromine,
Iodine halogen gas, BrF, ClF, ClF ₃ ,
Examples include interhalogen compounds such as BrF ₅ , BrF ₃ , IF ₇ , IF ₅ , ICl, and IBr. Preferred examples of silicon compounds containing halogens, so-called halogen-substituted silane derivatives include silicon halides such as SiF ₄ , Si ₂ F ₆ , SiCl ₄ and SiBr ₄ . When forming the characteristic photoconductive member of the present invention by a glow discharge method using such a silicon compound containing halogen, silicon hydride gas is used as a raw material gas that can generate Si. At least, a photoconductive layer made of a-Si:X can be formed on a predetermined support. When manufacturing the photoconductive layer 102 containing halogen atoms according to the glow discharge method, basically silicon halide gas, which is a raw material gas for Si generation, and Ar,
Gases such as H ₂ and He are introduced into a deposition chamber in which a photoconductive layer is formed at a predetermined mixing ratio and gas flow rate, and a glow discharge is generated to form a plasma atmosphere of these gases. However, in order to introduce hydrogen atoms, a predetermined amount of silicon compound gas containing hydrogen atoms is also mixed with these gases. A layer may also be formed. Moreover, each gas may be used not only as a single species but also as a mixture of multiple species at a predetermined mixing ratio. To form a photoconductive layer made of a-Si (H, Sputtering is performed in a predetermined gas plasma atmosphere, and in the case of the ion plating method, polycrystalline silicon or single crystal silicon is housed in a deposition boat as an evaporation source, and this silicon evaporation source is heated using a resistance heating method or an electron beam. Law (EB Law)
This can be carried out by heating and evaporating the flying evaporated material by, for example, passing through a predetermined gas plasma atmosphere. At this time, in order to introduce halogen atoms into the layer formed by either the sputtering method or the ion plating method, a gas of the above-mentioned halogen compound or a silicon compound containing the above-mentioned halogen atoms is introduced into the deposition chamber. The gas may be introduced into the atmosphere to form a plasma atmosphere of the gas. In addition, when introducing hydrogen atoms, a raw material gas for introducing hydrogen atoms, such as H ₂ or the above-mentioned silanes, is introduced into the deposition chamber for sputtering to create a plasma atmosphere of the gas. All you have to do is form it. In the present invention, the above-mentioned halogen compounds or halogen-containing silicon compounds are effectively used as the raw material gas for halogen introduction, but in addition, HF, HCl, HBr, HI
Hydrogen halides such as SiH ₂ F ₂ , SiH ₂ Cl ₂ ,
Halogen-substituted silicon hydrides such as SiHCl ₃ , SiH ₂ Br ₂ , SiHBr ₃ and other halides containing gaseous or gasifiable hydrogen atoms as one of their constituents are also effective starting materials for forming the photoconductive layer. I can list many. These halides containing hydrogen atoms are used in the present invention because hydrogen atoms, which are extremely effective in controlling electrical or photoelectric properties, are also introduced into the layer at the same time as halogen atoms are introduced into the photoconductive layer. is used as a suitable raw material for halogen introduction. In order to structurally introduce hydrogen atoms into the photoconductive layer, in addition to the above, H ₂ or SiH ₄ , Si ₂ H ₆ , Si ₃ H ₈ ,
This can also be done by causing a discharge by causing a silicon hydride gas such as Si ₄ H ₁₀ to coexist with a silicon compound for producing a-Si in a deposition chamber. For example, in the case of the reaction sputtering method,
Using a Si target, a plasma atmosphere is formed by introducing a gas for introducing halogen atoms and H ₂ gas, including inert gases such as He and Ar as necessary, into the deposition chamber, and the Si target is sputtered. A photoconductive layer made of a-Si(H,X) is formed on the substrate by tuttering. Furthermore, B ₂ H ₆ , which also serves as impurity doping,
Gases such as PH ₃ and PF ₃ can also be introduced. In the present invention, the amount of H or X contained in the photoconductive layer of the photoconductive member to be formed or (H+X)
The amount of is usually 1 to 40 atomic%, preferably 5 atomic%.
It is desirable that it be ~30 atomic%. The amount of H and/or All you have to do is control the force. In order to make the photoconductive layer n-type, p-type, or i-type, an n-type impurity, a p-type impurity, or both impurities are formed during layer formation by a glow discharge method, a reactive sputtering method, or the like. This is accomplished by doping the layer in a controlled amount. In order to make the photoconductive layer i-type or p-type, impurities doped into the photoconductive layer include elements of group A of the periodic table, such as B, Al, Ga,
Preferred examples include In and Tl. In the case of an n-type tendency, suitable elements include elements of group A of the periodic table, such as N, P, As, Sb, and Bi. The amount of impurities doped into the photoconductive layer is appropriately determined depending on the desired electrical and optical properties, but it is determined according to the desired electrical and optical properties.
In the case of impurities, it is sufficient to dope within the range of up to 3×10 ^-3 atomic%, and in the case of impurities in group A of the periodic table, doping may be carried out in the range of 5×10 ^-3 atomic% or less. It is desirable. The layer thickness of the photoconductive layer is appropriately determined as desired so that photocarriers are efficiently generated in the photoconductive layer and efficiently transported in a predetermined direction, and is usually 3 to 100 μm, preferably 5 μm. ~50μ. In the present invention, by providing the surface barrier layer 103, the photoconductive layer 102 can be used even if it has a relatively low resistance. The dark resistance of the photoconductive layer 102 is preferably 5×10 ⁹ Ωcm or more, most preferably
It is desirable that the photoconductive layer 102 be formed to have a resistance of 10 ¹⁰ Ωcm or more. In particular, this numerical condition for the dark resistance value is required when the produced photoconductive member is used as an electrophotographic image forming member, a high-speed reading device or imaging device used in a low illuminance region, or a photoelectric conversion device. This is an important element in some cases. The layer thickness of the photoconductive layer 102 of the photoconductive member for electrophotography in the present invention is appropriately determined according to the purpose of the application, such as a reading device, an imaging device, or an image forming member for electrophotography. be done. In the present invention, the layer thickness of the photoconductive layer 102 is set such that the surface layer thickness is such that the function of the photoconductive layer 102 and the function of the surface barrier layer are each effectively utilized and the object of the present invention is effectively achieved. It is determined as desired in relation to the layer thickness with the barrier layer 103, and in normal cases, the layer thickness is several hundred to several thousand times or more than the layer thickness of the surface barrier layer 103. is preferred. Example 1 Using the apparatus shown in FIG. 2 installed in a completely shielded clean room, a photoconductive member having the layered structure shown in FIG. 1 was produced by the following operations. A molybdenum (substrate) 205 having a surface cleaned and having a thickness of 0.5 mm and 10 cm square was firmly fixed to a fixing member 203 at a predetermined position in the deposition chamber 201 . Substrate 20
5 is heated with an accuracy of ±0.5° C. by the heater 204 inside the fixed member 203. Temperature was allowed to be measured directly on the backside of the substrate by a thermocouple (alumel-chromel). Next, after confirming that all valves in the system are closed, the main valve 232 is fully opened to create a vacuum of about 5×10 ^-7 Torr (at this time, all valves in the system are closed). Auxiliary valve 231 and outflow valve 2
25, 226, 227, 228, 229, 230
are opened and the flow meters 240, 241, 242,
After the inside of 243, 244, 245 is sufficiently deaerated, the outflow valve 225, 226, 227, 22
8,229,230 and auxiliary valve 231 were closed. Here, the heater 204 was turned on and the substrate temperature was set at 250°C. _Thereafter , the valve 213 of the cylinder 207 of SiH ₄ gas (purity 99.999%, hereinafter referred to as SiH ₄ /H 2 ) diluted to 10 vol% with H ₂ , and the B ₂ H ₆ gas (hereinafter referred to as SiH 4 /H ₂ ) diluted to 500 vppm with H 2 Open the valve 214 of the cylinder 208 (denoted as B ₂ H ₆ /H ₂ ), and check the outlet pressure gauge 2.
The pressure of 34,235 was adjusted to 1 Kg/cm ² and the inflow valves 219, 220 were gradually opened to allow SiH ₄ gas and B ₂ H ₆ gas to flow into the flow meters 240, 241. Subsequently, the outflow valves 225 and 226 were gradually opened, and then the auxiliary valve 231 was gradually opened. At this time, SiH ₄ /H ₂ gas flow rate and B ₂ H ₆ /H ₂
219, 22 so that the gas flow ratio is 500:1
0 and adjusted the opening of the auxiliary valve 231 to maintain the inside of the chamber 201 at 1×10 ^-2 Torr. Room 201
After the internal pressure has stabilized, the main valve 232 is gradually closed, and the indication on the Pirani gauge 246 is 0.2 Torr.
I adjusted the aperture so that After confirming that the gas inflow is stable and the internal pressure is stable, turn on the high frequency power supply 247.
The switch was turned on and high-frequency power was applied to the induction coil 206 to generate glow discharge in the chamber 201 with an input power of 10W. A photoconductive layer was formed by sustaining glow discharge for about 10 hours in this manner. After layer formation, valves 213, 214
was closed once. Thereafter, the auxiliary valve 231, then the outflow valves 225, 226, and the inflow valves 219, 220 were fully opened, and the insides of the flow meters 240, 241 were also sufficiently degassed to a vacuum state. After closing the auxiliary valve 231 and the outflow valves 219, 220, 225, 226, SiH ₄ gas diluted to 10 vol% with H ₂ (purity
99.999% (hereinafter referred to as SiH ₄ /H ₂ ) cylinder 20
Bulb 213 of 7, diluted to 10 vol% with _H2
Cylinder 21 of C ₂ H ₄ gas (hereinafter referred to as C ₂ H ₄ /H ₂ )
0 valve 216 is opened and the outlet pressure gauge 234,
Adjust the pressure of 237 to 1Kg/cm ² and open the inflow valve 21.
9,222 gradually open and flow meter 240,
SiH ₄ gas and C ₂ H ₄ gas were respectively introduced into 243. Subsequently, the outflow valves 225 and 228 were gradually opened, and then the auxiliary valve 231 was gradually opened. At this time, the inflow valve 21 is adjusted so that the SiH ₄ /H ₂ gas flow rate and C ₂ H ₄ /H ₂ gas flow rate ratio is 1:9.
9,222 was adjusted. Next, Pirani Gauge 24
The opening of the auxiliary valve 231 was adjusted while observing the reading 6, and the auxiliary valve 231 was opened until the inside of the chamber 201 became 1×10 ⁻² Torr. After the internal pressure of the chamber 201 stabilizes, the main valve 232 is gradually closed.
The opening was adjusted so that the reading on the Pirani gauge 246 was 0.5 Torr. After confirming that the gas inflow is stable and the internal pressure is stable, the high frequency power supply 247 is turned on, and the induction coil 206 is
High frequency power of 13.56 MHz was applied to generate glow discharge in the chamber 301, resulting in an input power of 10 W.
In order to deposit a-( _{SixC1 -x} ) _y :H1 _-y on the substrate under the above conditions, the conditions were maintained for 1 minute to form a surface barrier layer. After that, the high frequency power supply 247 is turned off, and the outflow valves 225 and 228 and the inflow valve 2 are turned off.
19 and 222 and fully open the main valve 232 to reduce the inside of the chamber 201 to 10 ^-5 Torr or less,
The main valve 232 was closed, and the inside of the chamber 201 was brought to atmospheric pressure by the leak valve 233, and the substrate was taken out. The total thickness of the layer thus formed on the substrate was approximately 15μ. The photoconductive member thus obtained was installed in an experimental charging exposure experiment apparatus. Corona charging is performed at 6KV, and exposure is performed by scanning with a 780nm semiconductor laser given an image signal, and the scene is
It was 5 μJ. Immediately thereafter, a good toner image was obtained on the photoconductive member surface by cascading a chargeable developer (including toner and carrier) onto the photoconductive member surface. The toner image on the photoconductive member is
Transferred onto transfer paper with 5.0KV corona charging,
A clear, high-density image with excellent resolution and good gradation reproducibility was obtained. Further, even after image formation was repeated 50,000 times, no deterioration in the image characteristics was observed. Example 2 In forming the surface barrier layer, SiH ₄ /H ₂ gas and
Photoconductive members were prepared under the same conditions and procedures as in Example 1, except that the C content in the layer was varied by changing the flow rate ratio of C ₂ H ₄ /H ₂ gas. In the case of preparation and the formation of the surface barrier layer, light was applied under the same conditions and procedures as in Example 1, except that the layer thickness of the surface barrier layer was varied by changing the glow discharge time. Regarding the case of creating a conductive member, each sample was prepared in Example 1.
When an image was formed by installing it in a charging exposure device exactly the same as that described above and the image quality was judged, the results shown in Table 1 below were obtained.

[Table] Example 3 After forming a photoconductive layer on a molydene substrate according to the same conditions and procedures as in Example 1, 10 vol% of _H2 was added.
Open the valve 217 of the cylinder 211 of Si(CH ₃ ) ₄ gas (purity 99.999%, hereinafter referred to as Si(CH ₃ ) ₄ /H ₂ ) diluted to 1 kg/cm 2 and adjust the pressure on the outlet pressure gauge to 1 Kg/cm ^{2 .} Then, the inflow valve 223 was gradually opened to allow Si(CH ₃ ) ₄ /H ₂ gas to flow into the flow meter 244. Subsequently, the outflow valve 229 was gradually opened.
Next, the opening of the auxiliary valve 231 was adjusted while observing the reading on the Pirani gauge 246, and the auxiliary valve 231 was opened until the inside of the chamber 201 became 1×10 ⁻² Torr. After the internal pressure of the chamber 201 becomes stable, the main valve 232 is gradually closed, and the Pirani gauge 246 is closed.
The aperture was adjusted so that the indication was 0.5 Torr.
After confirming that the gas inflow is stable and the internal pressure is stable, the switch of the high frequency power supply 242 is turned ON, and 13.56 MHz high frequency power is applied to the induction coil 206 to generate a glow discharge in the chamber 201. , with an input power of 10W. After maintaining the same conditions for 1 minute to form a surface barrier layer, the high frequency power source 247
Turn off the glow discharge, wait for the substrate temperature to reach 100℃, and then close the outflow valve 22.
9 and the inflow valve 223, and close the main valve 2.
32 is fully opened to reduce the temperature inside the chamber 201 to 10 ^-5 Torr or less, then the main valve 232 is closed and the chamber 201 is
The inside of the chamber was brought to atmospheric pressure using a leak valve 233, and the substrate was taken out. In this case, the total thickness of the layer formed was approximately 9μ. The image forming member obtained in this way was installed in a charging exposure experiment equipment and exposed to 6.0KV.
Corona charging was performed for 0.2 seconds, and a light image was immediately irradiated. The optical image is created using a tungsten lamp light source.
A light intensity of 1.0 lux sec was irradiated through a transmission type test chart. Immediately thereafter, a good toner image was obtained on the surface of the component by cascading a charged developer (including toner and carrier) onto the surface of the component. When the toner image on the member was transferred onto transfer paper using -5.0 kV corona charging, a clear, high-density image with excellent resolution and good gradation reproducibility was obtained. Further, even when the corona charge polarity was changed to 1 and the developer polarity was changed to 2, a clear and good image was obtained in the same manner as in Example 1. Example 4 When forming a photoconductive layer on a molybdenum substrate, the input voltage of the heater 204 was increased, and the input voltage was varied while detecting the substrate temperature until it stabilized at a constant value of 250°C. Thereafter, the auxiliary valve 231, then the outflow valve 225, and the inflow valve 219 were fully opened, and the inside of the flow meter 240 was also sufficiently degassed and vacuumed. After closing the auxiliary valve 231, valves 225, 219, SiH ₄ gas diluted to 10 vol% with H ₃ (purity
99.999% (hereinafter referred to as SiH ₄ /H ₂ ) cylinder 20
The valve 213 of No. 7 was opened, the pressure of the outlet pressure gauge 234 was adjusted to 1 Kg/cm ² , and the inflow valve 219 was gradually opened to allow SiH ₄ /H ₂ gas to flow into the flow meter 240. Subsequently, the outflow valve 225 was gradually opened, and then the auxiliary valve 231 was gradually opened. Next, while watching the reading on the Pirani gauge 246, adjust the opening of the auxiliary valve 231, and
Auxiliary valve 23 until the inside of 1 becomes 1×10 ^-2 Torr.
I opened 1. After the internal pressure of the chamber 201 becomes stable, the main valve 232 is gradually closed and the Pirani gauge 2 is closed.
The aperture was adjusted so that the indication of No. 46 was 0.5 Torr. After confirming that the gas inflow is stable and the internal pressure is stable, the switch of the high frequency power supply 247 is turned on, and 13.56 MHz high frequency power is applied to the induction coil 206 to generate a glow discharge in the chamber 201, generating a 10 W The input power was set to . After the glow discharge was maintained for 3 hours to form a photoconductive layer, the heating heater 204 was turned off, the high frequency power supply 247 was turned off, and after waiting for the substrate temperature to reach 100°C, the same process as in Example 1 was performed. The a-
(Si _x C _1-x ) _y : A surface barrier layer made of H _1-y was provided.
In this case, the total thickness of the layer formed was approximately 9μ.
When the thus obtained image forming member was imaged on transfer paper according to the same procedure as in Example 1,
The image formed by corona discharge was superior to the image formed by corona discharge and was extremely clear. From this result, it was confirmed that the image forming member obtained in this example had charge polarity dependence. Example 5 The deposition chamber was evacuated to 5×10 ^-7 Torr under the same conditions and procedures as in Example 1, and SiH ₄ /H ₂ gas was introduced into the chamber 201 in the same manner as in Example 1.
Then _PH3 gas diluted to 25 volppm with _H2 (hereinafter
The reading of the flow meter 241 is adjusted by adjusting the inflow valve 221 and the outflow valve 227 at a gas pressure of 1 Kg/cm ² (reading of the outlet pressure gauge 236) from the cylinder 209 of PH ₃ /H ₂ through the inflow valve 221. The opening of the outflow valve 227 was determined to be 1/50 of the flow rate of SiH ₄ /H ₂ gas, and the flow rate was stabilized. Subsequently, the high frequency power supply 247 was turned on to generate glow discharge. The input voltage at that time was 10W. After sustaining the glow discharge for 4 hours to form a photoconductive layer, the heating heater 2
04 is turned off, the high frequency power supply 247 is also turned off, and after waiting for the substrate temperature to reach 100°C, a-(Si _x C _{1 -x} ) _y : A surface barrier layer made of H _1-y was provided. In this case, the total thickness of the layer formed was approximately 11μ. An image was formed on a transfer paper using the thus obtained image forming member under the same conditions and procedures as in Example 1. The image quality was excellent and extremely clear. From this result, it was confirmed that the image forming member obtained in this example had charge polarity dependence. Example 6 Under the same conditions and procedures as in Example 1, the inside of the deposition chamber 201 was evacuated to 5×10 ^-7 Torr and SiH ₄ /
H ₂ gas was introduced into chamber 201 . Then with H ₂
B ₂ H ₆ gas diluted to 50 volppm (hereinafter B ₂ H ₆
(50)/H ₂ ) from the cylinder 208 through the inflow valve 220 at a gas pressure of 1 Kg/cm ² (reading of the outlet pressure gauge 235). The opening of the outflow valve 226 was set so that the flow rate was 1/10 of the flow rate of SiH ₄ /H ₂ gas, and the flow rate was stabilized. Subsequently, the high frequency power supply 247 was turned on to generate glow discharge. The input power at that time was set to 10W. After continuing the glow discharge for another 4 hours to form a photoconductive layer, the heating heater 204 is turned off, and the high frequency power source 247 is also turned off.
After waiting for the substrate temperature to reach 100°C, a
−(Si _x C _1-x ) _y : A surface barrier layer made of H _1-y was provided. In this case, the total thickness of the layer formed was approximately 10μ. The image forming member thus obtained was prepared in Example 1.
When an image was formed on a transfer paper under the same conditions and procedures as above, the image quality was superior and extremely clear when the image was formed using corona discharge than when the image was formed using corona discharge. From this result, it was confirmed that the image forming member obtained in this example had charge polarity dependence. However, its charge polarity dependence was opposite to that of the image forming members obtained in Examples 4 and 5. Example 7 SiH ₄ gas diluted to 10 vol% with H ₂ (hereinafter referred to as
Using a cylinder 212 of undiluted Si ₂ H ₆ gas in place of the cylinder 207 of SiH ₄ /H ₂ ), B ₂ H ₆ gas (B ₂ H ₆ (50) diluted with H ₂ to 50 volppm) is used. /H ₂ ) cylinder 208 with H ₂
B ₂ H ₆ gas diluted to 500 volppm (B ₂ H ₆ /H ₂ )
After forming a photoconductive layer and a surface barrier layer on a molybdenum substrate under the same conditions and procedures as in Example 1, except that the cylinder was changed to a cylinder of When an image formation test was performed by leaving the toner in an experimental apparatus, an extremely high quality, high contrast toner image was obtained on transfer paper using a combination of -5.5 kV corona discharge and a charged developer. Example 8 A photoconductive layer and a surface barrier layer were formed in the same manner as in Example 1 on a substrate in which a tin oxide transparent electrode was provided on an optically polished glass plate using a conventional method. however,
Regarding the shape of the photoconductive layer, the preparation time was shortened so that the layer thickness was approximately 2 μm. When the photoconductive member prepared in this way was used as the light-receiving surface of a visible image pickup tube, the target applied voltage was 60V.
When irradiated with white light 11L _x , the signal current is 630mA,
Dark current 1.0mA or less, afterimage characteristics after 3 fields
Good characteristics of 10% were obtained.

[Brief explanation of the drawing]

FIG. 1 is a schematic explanatory diagram for explaining the layer structure of a preferred embodiment of the photoconductive member for electrophotography of the present invention, and FIG. FIG. 2 is a schematic explanatory diagram for explaining the apparatus of FIG. 100... Photoconductive member for electrophotography, 101...
Support, 102...Photoconductive layer, 103...Surface barrier layer, 104...Free surface.

Claims (1)

[Scope of Claims] 1. Consisting of a support and an amorphous material having silicon atoms as a matrix and containing either one or both of hydrogen atoms and halogen atoms, the content of either one of the hydrogen atoms and the halogen atoms is or a photoconductive layer having a total content of 1 to 40 atomic%, and a surface barrier layer provided thereon and made of an amorphous material containing silicon atoms and carbon atoms and hydrogen atoms. A photoconductive member for electrophotography, characterized in that: 2. The photoconductive member for electrophotography according to claim 1, wherein the photoconductive layer contains a p-type or n-type impurity.