Abstract: An active-energy-ray-curable composition, a cured material of the active-energy-ray-curable composition satisfying a critical load of 5.0 g or more but 25.0 g or less, the critical load being obtained by a continuous loading test method using a variable normal load friction and wear measurement device, the cured material having an average thickness of 10 ?m and being formed by coating the active-energy-ray-curable composition on a substrate and by irradiating and curing the active-energy-ray-curable composition with active energy rays having illuminance of 1.5 W/cm2 and an amount of irradiation of 200 mJ/cm2.

Abstract: An active-energy-ray-curable composition including active-energy-ray-polymerizable compounds, wherein the active-energy-ray-polymerizable compounds include a monofunctional monomer, a bifunctional monomer, and a trifunctional monomer, and wherein the monofunctional monomer, the bifunctional monomer, and the trifunctional monomer satisfy conditions (1) and (2) below: (1) [number of functional groups derived from the monofunctional monomer]>[number of functional groups derived from the bifunctional monomer]>[number of functional groups derived from the trifunctional monomer]; and (2) a standard deviation of functional group ratios is from 0.003 through 0.030, the functional group ratios being expressed by [number of functional groups derived from N-functional monomer]/([number of functional groups derived from the monofunctional monomer]+[number of functional groups derived from the bifunctional monomer]+[number of functional groups derived from the trifunctional monomer]), the N being mono, bi, or tri.

Abstract: Active-energy-ray-curable composition including: monofunctional monomers; and polymerization initiator, cured material of the composition satisfying 0.30?D?0.85, where D is difference between peak-area-ratios A and B in infrared-ATR and obtained by: the composition is coated on polycarbonate substrate to form coated film having average thickness of 10 ?m; the film is irradiated with active energy rays having light quantity of 500 mJ/cm2 at UV intensity of 1.

Abstract: An active-energy-ray-curable composition, a cured material of the active-energy-ray-curable composition satisfying a critical load of 5.0 g or more but 25.0 g or less, the critical load being obtained by a continuous loading test method using a variable normal load friction and wear measurement device, the cured material having an average thickness of 10 ?m and being formed by coating the active-energy-ray-curable composition on a substrate and by irradiating and curing the active-energy-ray-curable composition with active energy rays having illuminance of 1.5 W/cm2 and an amount of irradiation of 200 mJ/cm2.

Abstract: Active-energy-ray-curable composition including: monofunctional monomers; and polymerization initiator, cured material of the composition satisfying 0.30?D?0.85, where D is difference between peak-area-ratios A and B in infrared-ATR and obtained by: the composition is coated on polycarbonate substrate to form coated film having average thickness of 10 ?m; the film is irradiated with active energy rays having light quantity of 500 mJ/cm2 at UV intensity of 1.

Abstract: An active-energy-ray-curable composition including active-energy-ray-polymerizable compounds, wherein the active-energy-ray-polymerizable compounds include a monofunctional monomer, a bifunctional monomer, and a trifunctional monomer, and wherein the monofunctional monomer, the bifunctional monomer, and the trifunctional monomer satisfy conditions (1) and (2) below: (1) [number of functional groups derived from the monofunctional monomer]>[number of functional groups derived from the bifunctional monomer]>[number of functional groups derived from the trifunctional monomer]; and (2) a standard deviation of functional group ratios is from 0.003 through 0.030, the functional group ratios being expressed by [number of functional groups derived from N-functional monomer]/([number of functional groups derived from the monofunctional monomer]+[number of functional groups derived from the bifunctional monomer]+[number of functional groups derived from the trifunctional monomer]), the N being mono, bi, or tri.

Abstract: An active-energy-ray-curable composition, cured material of which satisfies W1?75.0 g and 165.0 g?W2?300.0 g when the material is analyzed by variable-normal-load-friction-and-wear-measurement system, W1 being expressed by W1=4*TW1 and W2 being expressed by W2=4*TW2, TW1 and TW2 being obtained by method in which: the material is formed by coating the composition on substrate to have thickness of 10 ?m, and curing the composition, and in the system, load is applied to the material with indenter while the load is changed from 0 g through 200 g for 50 seconds to obtain graph having time in horizontal axis and friction resistance force in vertical axis, and in the graph, a time at which scratch first occurs in the material is defined as T1 and time closest to T1 among times at which change in the friction resistance force is discontinuous is defined as TW1; and TW2 is defined as time at which the substrate is exposed.

Abstract: An image forming apparatus including an image bearing member having a photosensitive layer and the surface including concave portions having a concave diameter of from 5 to 200 ?m, an irradiation device that irradiates the surface of the image bearing member with light to form a latent electrostatic image thereon, a development device that develops the latent electrostatic image with a development agent containing toner to obtain a visualized image, a transfer device that transfers the visualized image to a transfer medium, a first cleaning brush to which a bias is applied with a polarity reverse to that of the toner remaining on the surface of the image bearing member after the visualized image is transferred, and a second cleaning brush to which a bias is applied with the same polarity as that of the toner remaining on the surface of the image bearing member.

Abstract: An electrophotographic photoreceptor including a conductive substrate, a photosensitive layer, and a surface layer, which satisfies the following inequations: 0.005<WRa(LMH)<0.03??(i) 0.010<WRa(LHH)<0.03??(ii) 0.005<WRa(LML)<0.20??(iii) WRa(LLH)>WRa(LMH)??(iv) WRa(LLH)>WRa(LHH)??(v) wherein WRa (?m) represents a center-line average roughness of frequency components LHH, LHL, LMH, LML, LLH, and LLL that are obtained by subjecting a one-dimensional data array of a surface profile of the electrophotographic photoreceptor to wavelet transformation multiresolution analysis so as to be separated into 6 frequency components; thinning a one-dimensional data array of the lowest frequency component so that the number of data array is reduced to 1/40; and subjecting the thinned one-dimensional data array to wavelet transformation multiresolution analysis so as to be separated into the 6 frequency components LHH, LHL, LMH, LML, LLH, and LLL.

Abstract: An image forming apparatus including an image bearing member having a photosensitive layer and the surface including concave portions having a concave diameter of from 5 to 200 ?m, an irradiation device that irradiates the surface of the image bearing member with light to form a latent electrostatic image thereon, a development device that develops the latent electrostatic image with a development agent containing toner to obtain a visualized image, a transfer device that transfers the visualized image to a transfer medium, a first cleaning brush to which a bias is applied with a polarity reverse to that of the toner remaining on the surface of the image bearing member after the visualized image is transferred, and a second cleaning brush to which a bias is applied with the same polarity as that of the toner remaining on the surface of the image bearing member.

Abstract: An electrophotographic photoreceptor including a conductive substrate, a photosensitive layer, and a surface layer, which satisfies the following inequations: 0.005<WRa(LMH)<0.03??(i) 0.010<WRa(LHH)<0.03??(ii) 0.005<WRa(LML)<0.20??(iii) WRa(LLH)>WRa(LMH)??(iv) WRa(LLH)>WRa(LHH)??(v) wherein WRa (?m) represents a center-line average roughness of frequency components LHH, LHL, LMH, LML, LLH, and LLL that are obtained by subjecting a one-dimensional data array of a surface profile of the electrophotographic photoreceptor to wavelet transformation multiresolution analysis so as to be separated into 6 frequency components; thinning a one-dimensional data array of the lowest frequency component so that the number of data array is reduced to 1/40; and subjecting the thinned one-dimensional data array to wavelet transformation multiresolution analysis so as to be separated into the 6 frequency components LHH, LHL, LMH, LML, LLH, and LLL.

Abstract: A thermal image transfer recording method includes the steps of holding a thermal image transfer recording medium including a support material and a thermal image transfer layer provided on the support material, and an image recording material between a line edge thermal head and a platen roller, with a contact pressure being applied therebetween; transferring the thermal image transfer recording layer imagewise from the thermal image transfer recording medium to the image recording material with imagewise application of heat by use of the line edge thermal head; and taking up the thermal image transfer recording medium after the image transfer, with the take-up tension applied to the thermal image transfer recording medium being set larger than both the shearing strength and peeling strength at 70.degree. C. of the thermal image transfer layer. A thermal image transfer recording medium including a thermal image transfer layer with a shearing strength of 200 g/cm or more at 25.degree. C.

Abstract: A thermal image transfer recording method includes the steps of holding a thermal image transfer recording medium including a support material and a thermal image transfer layer provided on the support material, and an image recording material between a line edge thermal head and a platen roller, with a contact pressure being applied therebetween; transferring the thermal image transfer recording layer imagewise from the thermal image transfer recording medium to the image recording material with imagewise application of heat by use of the line edge thermal head; and taking up the-thermal image transfer recording medium after the image transfer, with the take-up tension applied to the thermal image transfer recording medium being set larger than both the shearing strength and peeling strength at 70.degree. C. of the thermal image transfer layer. A thermal image transfer recording medium including a thermal image transfer layer with a shearing strength of 200 g/cm or more at 25.degree. C.

Abstract: A thermal image transfer recording method includes the steps of holding a thermal image transfer recording medium including a support material and a thermal image transfer layer provided on the support material, and an image recording material between a line edge thermal head and a platen roller, with a contact pressure being applied therebetween; transferring the thermal image transfer recording layer imagewise from the thermal image transfer recording medium to the image recording material with imagewise application of heat by use of the line edge thermal head; and taking up the thermal image transfer recording medium after the image transfer, with the take-up tension applied to the thermal image transfer recording medium being set larger than both the shearing strength and peeling strength at 70.degree. C. of the thermal image transfer layer. A thermal image transfer recording medium including a thermal image transfer layer with a shearing strength of 200 g/cm or more at 25.degree. C.