Abstract: In an electron beam device provided with two columns including an irradiation optical system and an imaging optical system, a photoelectron image for use in adjusting the irradiation optical system is made sharper. The electron beam device includes: an irradiation optical system which irradiates a sample placed on a stage with an electron beam; a light irradiation unit 50 which irradiates the sample with light containing ultraviolet rays; a sample voltage control unit 44 which applies a negative voltage to the sample so that, before the electron beam reaches the sample, the electron orbit inverts; and an imaging optical system which acquires a mirror electron image by forming an image of mirror electrons reflected by application of the negative voltage.

Abstract: It is necessary to guarantee performance by quantitatively evaluating the defect detection sensitivity of an inspection device for using the mirror electron image to detect defect in a semiconductor substrate. The size and position of accidentally formed defects are random, however, and this type of quantitative evaluation has been difficult. This semiconductor substrate 101 for evaluation is for evaluating the defect detection sensitivity of an inspection device and comprises a plurality of first indentations 104 that are formed through the pressing, with a first pressing load, of an indenter having a prescribed hardness and shape into the semiconductor substrate for evaluation. Further, a mirror electron image of the plurality of first indentations of the semiconductor substrate for evaluation is acquired, and the defect detection sensitivity of an inspection device is evaluated through the calculation of the defect detection rate of the plurality of first indentations in the acquired mirror electron image.

Abstract: Provided is a mirror electronic inspection device which is a defect inspection device for detecting a defect of a semiconductor substrate or the like, and evaluates temperature dependence of the defect in a vacuum. A heating stage including a heater (heat generating element) covered with an electrically insulated insulating material, a heater base on which a sample is mounted, and a heat shielding plate and equipotential surface is mounted on a moving stage installed in a sample chamber of a device via an electrically insulated and thermally insulated fixing member. A heater power supply is connected to the heater (heat generating element), and a sample application power supply is connected to the heater base. The heater power supply and the sample application power supply are electrically separated.

Abstract: In order to optimize defect contrast in a charged particle beam device that inverts charged particles directly above a sample and observes the electrons, this charged particle beam device is provided with a charged particle source, an electron gun control device which applies a first voltage to the charged particle source, a substrate voltage control device which applies a second voltage to a sample, an image forming optical system which includes an imaging lens for imaging charged particles incident from the direction of the sample, a detector which includes a camera for detecting the charged particles, and an image processing device which processes the detected signal, wherein the imaging optical system is configured so as not to image secondary electrons emitted from the sample, but forms an image with mirror electrons bounced back by the electric field formed on the sample by means of the potential difference between the first and the second voltages.

Abstract: A defect inspection device includes a sample support member, a negative voltage, an imaging element, an ultraviolet light source, a movement stage, and a control device. The control device controls the movement stage such that a portion of a linear part included in the image or a location on an extensional line of the linear part is positioned at a specific location in an irradiated region of the electron beam. The control device also repeats the control of the movement stage until an end of the linear part is positioned within the irradiated region of the electron beam.

Abstract: A purpose of the present invention is to provide a charged particle beam apparatus that performs apparatus adjustment based on a proper evaluation of a beam. To achieve the abovementioned purpose, with the present invention, proposed is a charged particle beam apparatus comprising: an irradiation optical system including a lens for converging charged particle beams emitted from a charged particle source; and an imaging optical system for imaging the charged particles obtained by irradiating the charged particle beams toward a sample on an imaging element, wherein the charged particle beam apparatus comprises a control apparatus for controlling the lens, and the control apparatus evaluates for each lens condition the size of a specific brightness area obtained by the charged particle beam being made to reach the sample, and selects the lens condition for which the size information fulfills a designated condition.

Abstract: It is necessary to guarantee performance by quantitatively evaluating the defect detection sensitivity of an inspection device for using the mirror electron image to detect defect in a semiconductor substrate. The size and position of accidentally formed defects are random, however, and this type of quantitative evaluation has been difficult. This semiconductor substrate 101 for evaluation is for evaluating the defect detection sensitivity of an inspection device and comprises a plurality of first indentations 104 that are formed through the pressing, with a first pressing load, of an indenter having a prescribed hardness and shape into the semiconductor substrate for evaluation. Further, a mirror electron image of the plurality of first indentations of the semiconductor substrate for evaluation is acquired, and the defect detection sensitivity of an inspection device is evaluated through the calculation of the defect detection rate of the plurality of first indentations in the acquired mirror electron image.

Abstract: The purpose of the present invention is to provide a defect inspection device that can evaluate a defect having a long latent flaw with high precision. A defect inspection device of the present invention is characterized by being provided with: a sample support member that supports a sample irradiated by an electron beam emitted from an electron source; an imaging element at which an image of electrons (mirror electrons) reflected without reaching the sample is formed via a retarding electric field formed on the sample; an ultraviolet light source that emits an ultraviolet light toward the sample; a movement stage that moves the sample support member; and a control device that controls the movement stage.

Abstract: In order to optimize defect contrast in a charged particle beam device that inverts charged particles directly above a sample and observes the electrons, this charged particle beam device is provided with a charged particle source, an electron gun control device which applies a first voltage to the charged particle source, a substrate voltage control device which applies a second voltage to a sample, an image forming optical system which includes an imaging lens for imaging charged particles incident from the direction of the sample, a detector which includes a camera for detecting the charged particles, and an image processing device which processes the detected signal, wherein the imaging optical system is configured so as not to image secondary electrons emitted from the sample, but forms an image with mirror electrons bounced back by the electric field formed on the sample by means of the potential difference between the first and the second voltages.

Abstract: In an electron beam device provided with two columns including an irradiation optical system and an imaging optical system, a photoelectron image for use in adjusting the irradiation optical system is made sharper. The electron beam device includes: an irradiation optical system which irradiates a sample placed on a stage with an electron beam; a light irradiation unit 50 which irradiates the sample with light containing ultraviolet rays; a sample voltage control unit 44 which applies a negative voltage to the sample so that, before the electron beam reaches the sample, the electron orbit inverts; and an imaging optical system which acquires a mirror electron image by forming an image of mirror electrons reflected by application of the negative voltage.

Abstract: The objective of the present invention is to propose a charged particle beam device with which an imaging optical system and an irradiation optical system can be adjusted with high precision. In order to achieve this objective, provided is a charged particle beam device comprising: a first charged particle column which serves as an irradiation optical signal; a deflector that deflects charged particles which have passed through the inside of the first charged particle column toward an object; and a second charged particle column which serves as an imaging optical system.

Abstract: A purpose of the present invention is to provide a charged particle beam apparatus that performs apparatus adjustment based on a proper evaluation of a beam. To achieve the abovementioned purpose, with the present invention, proposed is a charged particle beam apparatus comprising: an irradiation optical system including a lens for converging charged particle beams emitted from a charged particle source; and an imaging optical system for imaging the charged particles obtained by irradiating the charged particle beams toward a sample on an imaging element, wherein the charged particle beam apparatus comprises a control apparatus for controlling the lens, and the control apparatus evaluates for each lens condition the size of a specific brightness area obtained by the charged particle beam being made to reach the sample, and selects the lens condition for which the size information fulfills a designated condition.

Abstract: An object of the present invention is to provide a charged particle beam device that suppresses the influence of an external electromagnetic wave, even when a shielding member, such as a vacuum valve, is in the open state. To achieve the above object, a charged particle beam device including a vacuum chamber (111) having an opening (104) that surrounds a sample delivery path is proposed. The charged particle beam device includes a conductive material (118) surrounding the opening (104) for conduction between the vacuum chamber (111) and a conductive member (106) disposed on the atmosphere side. According to an embodiment of the present invention, it is possible to restrict an electromagnetic wave (117) from reaching the sample chamber via the delivery path.

Abstract: The objective of the present invention is to propose a charged particle beam device with which an imaging optical system and an irradiation optical system can be adjusted with high precision. In order to achieve this objective, provided is a charged particle beam device comprising: a first charged particle column which serves as an irradiation optical signal; a deflector that deflects charged particles which have passed through the inside of the first charged particle column toward an object; and a second charged particle column which serves as an imaging optical system.

Abstract: The purpose of the present invention is to provide a defect inspection device with which it is possible to detect a latent flaw with a high precision or at a high speed. In order to fulfill this purpose, this defect inspection device is provided with: a sample support member that supports a sample irradiated by an electron beam emitted from an electron source; a negative voltage applying power source for forming a retarding electric field in relation to the electron beam that irradiates the sample supported by the sample support member; an imaging element at which an image of electrons reflected without reaching the sample is formed via the retarding electric field; an ultraviolet light source that emits an ultraviolet light toward the sample; and a computation processing device that processes an image generated on the basis of a signal obtained by the imaging element.

Abstract: There is proposed a column supporting structure that includes a viscoelastic sheet, a supporting plate which holds the viscoelastic sheet, and a fixation portion which connects the supporting plate to each lens barrel. The viscoelastic sheet is disposed to extend in a plane perpendicular to one lens barrel or the other lens barrel.

Abstract: There is proposed a column supporting structure that includes a viscoelastic sheet, a supporting plate which holds the viscoelastic sheet, and a fixation portion which connects the supporting plate to each lens barrel. The viscoelastic sheet is disposed to extend in a plane perpendicular to one lens barrel or the other lens barrel.

Abstract: A scanning electron beam device having: a deflector (5) for deflecting an electron beam (17) emitted from an electron source (1); an objective lens (7) for causing the electron beam to converge; a retarding electrode; a stage (9) for placing a wafer (16); and a controller (15); wherein the stage can be raised and lowered. In the low acceleration voltage region, the controller performs rough adjustment and fine adjustment of the focus in relation to the variation in the height of the wafer using electromagnetic focusing performed through excitation current adjustment of the objective lens. In the high acceleration voltage region, the controller performs rough adjustment of the focus in relation to the variation in the height of the wafer by mechanical focusing performed through raising and lowering of the stage, and performs fine adjustment by electrostatic focusing performed through adjustment of the retarding voltage.

Abstract: An object of the present invention is to provide a charged particle beam device that suppresses the influence of an external electromagnetic wave, even when a shielding member, such as a vacuum valve, is in the open state. To achieve the above object, a charged particle beam device including a vacuum chamber (111) having an opening (104) that surrounds a sample delivery path is proposed. The charged particle beam device includes a conductive material (118) surrounding the opening (104) for conduction between the vacuum chamber (111) and a conductive member (106) disposed on the atmosphere side. According to an embodiment of the present invention, it is possible to restrict an electromagnetic wave (117) from reaching the sample chamber via the delivery path.

Abstract: A scanning electron beam device having: a deflector (5) for deflecting an electron beam (17) emitted from an electron source (1); an objective lens (7) for causing the electron beam to converge; a retarding electrode; a stage (9) for placing a wafer (16); and a controller (15); wherein the stage can be raised and lowered. In the low acceleration voltage region, the controller performs rough adjustment and fine adjustment of the focus in relation to the variation in the height of the wafer using electromagnetic focusing performed through excitation current adjustment of the objective lens. In the high acceleration voltage region, the controller performs rough adjustment of the focus in relation to the variation in the height of the wafer by mechanical focusing performed through raising and lowering of the stage, and performs fine adjustment by electrostatic focusing performed through adjustment of the retarding voltage.