Abstract: In a method and an apparatus for inspecting a thermally assisted magnetic recording head element, a specimen is mounted on a table movable in a plane of a scanning probe microscope device, evanescent light is generated from a portion of light emission of evanescent light of the specimen, scattered light of the evanescent light is detected by moving the table in the plane while a cantilever of the scanning probe microscope having a probe is vertically vibrated in the vicinity of a surface of the specimen, and an intensity distribution of the evanescent light emitted from the portion of light emission of evanescent light or a surface profile of the portion of light emission of evanescent light of the specimen is inspected using position information of generation of the evanescent light based on the detected scattered light.

Abstract: To detect both of near-field light and magnetic field generated by a thermal assist type magnetic head and to perform inspection of the head, a cantilever of a scanning probe microscope has a lever in which a probe is formed, a thin magnetic film formed on a surface of the probe, and fine particles or thin film of noble metal or an alloy including noble metal formed on a surface of the magnetic film. An inspection apparatus has the cantilever, a displacement detection unit to detect vibration of the cantilever, a near-field light detection unit to detect scattered light caused by near-field light generated from a near-field light emitter and enhanced on the surface of the probe of the cantilever, and a processing unit to process signals obtained by detection with the displacement detection unit and the near-field light detection unit.

Abstract: The magnetic head inspection method includes, exciting the cantilever of a magnetic force microscope at a predetermined frequency, the cantilever being provided with a magnetic probe on the end thereof, floating the magnetic probe over the writing head of the magnetic head and two-dimensionally scanning a search range, detecting the specific position of the writing head based on the search two-dimensional magnetic field intensity of the writing head with exciting state of the cantilever in the two-dimensional scan, setting a shape detection range smaller than the search range for detecting the shape of the writing head based on the specific position, and floating the magnetic probe over the writing head with exciting state of the cantilever, detecting the shape of the writing head by detecting the detection two-dimensional magnetic field intensity of the writing head in the two-dimensional scan.

Abstract: In a method of manufacturing this cantilever for the magnetic force microscope, a magnetic film is formed on a probe at a tip of the cantilever for the magnetic force microscope. When a non-magnetic rigid protective film is formed around the probe, the film is formed from the front of the probe of the cantilever for the magnetic force microscope at an angle (15° to 45°) and from the back of the probe of the cantilever for the magnetic force microscope in two directions each at an angle in a range of (15° to 30°).

Abstract: In a method and an apparatus for inspecting a thermally assisted magnetic recording head element, a specimen is mounted on a table movable in a plane of a scanning probe microscope device, evanescent light is generated from a portion of light emission of evanescent light of the specimen, scattered light of the evanescent light is detected by moving the table in the plane while a cantilever of the scanning probe microscope having a probe is vertically vibrated in the vicinity of a surface of the specimen, and an intensity distribution of the evanescent light emitted from the portion of light emission of evanescent light or a surface profile of the portion of light emission of evanescent light of the specimen is inspected using position information of generation of the evanescent light based on the detected scattered light.

Abstract: In a method and an apparatus for inspecting a thermally assisted magnetic recording head element, a specimen is mounted on a table movable in a plane of a scanning probe microscope device, evanescent light is generated from a portion of light emission of evanescent light of the specimen, scattered light of the evanescent light is detected by moving the table in the plane while a cantilever of the scanning probe microscope having a probe is vertically vibrated in the vicinity of a surface of the specimen, and an intensity distribution of the evanescent light emitted from the portion of light emission of evanescent light or a surface profile of the portion of light emission of evanescent light of the specimen is inspected using position information of generation of the evanescent light based on the detected scattered light.

Abstract: Applying an alternating current to a magnetic head as a sample generates an alternate-current magnetic field from the sample. A cantilever includes a probe that is made of a magnetic material or is coated with a magnetic material. The cantilever is displaced when it approaches the sample. Detecting the displacement of the cantilever detects distribution of the magnetic field from the sample. It is possible to fast measure distribution of the magnetic field generated from the sample when a frequency of the alternating current applied to the sample differs from a resonance frequency of the cantilever.

Abstract: A magnetic head manufacturing method is provided. The method includes a wafer process, a rowbar process for slicing a bar-shaped rowbar from a wafer passing through the wafer process, and performing lapping, air bearing surface (ABS) formation, cleaning, and carbon protective film deposition processes on the rowbar, a write pole test process for measuring an effective track width of the magnetic heads in the bar-shaped rowbar by using a magnetic force microscope (MFM), a scanning Hall probe microscope (SHPM), or a scanning magneto resistance effect microscope (SMRM), a read element test process for measuring electromagnetic conversion characteristics of each of read elements within the bar-shaped rowbar, a slider process for dividing up each of the magnetic heads and machining the bar-shaped rowbar into individual chip shape sliders, and a head gimbal assembly (HGA) process.

Abstract: In a method and an apparatus for inspecting a thermally assisted magnetic recording head element, a specimen is mounted on a table movable in a plane of a scanning probe microscope device, evanescent light is generated from a portion of light emission of evanescent light of the specimen, scattered light of the evanescent light is detected by moving the table in the plane while a cantilever of the scanning probe microscope having a probe is vertically vibrated in the vicinity of a surface of the specimen, and an intensity distribution of the evanescent light emitted from the portion of light emission of evanescent light or a surface profile of the portion of light emission of evanescent light of the specimen is inspected using position information of generation of the evanescent light based on the detected scattered light.

Abstract: In a method of manufacturing this cantilever for the magnetic force microscope, a magnetic film is formed on a probe at a tip of the cantilever for the magnetic force microscope. When a non-magnetic rigid protective film is formed around the probe, the film is formed from the front of the probe of the cantilever for the magnetic force microscope at an angle (15° to 45°) and from the back of the probe of the cantilever for the magnetic force microscope in two directions each at an angle in a range of (15° to 30°).

Abstract: A device for transporting a magnetic head, a device for inspecting a magnetic head, and a method for manufacturing a magnetic head are provided. The device for transporting a magnetic head is capable of freely changing a posture of a thin film magnetic head when transporting a row bar-shaped thin film magnetic head. The transporting device for transporting a slender rectangular plate-like, that is, row bar-shaped magnetic head, cut from a wafer is capable of performing vertical installation and horizontal installation. The transporting device for transporting a slender rectangular plate-like, i.e., row bar-shaped magnetic head, is capable of performing the vertical installation and horizontal installation, and changing the posture of the magnetic head from vertical installation into horizontal installation and from horizontal installation into vertical installation when transporting the magnetic head between processes.

Abstract: A magnetic head inspection device inspects the write track width of a thin film magnetic head in a phase as early as possible during the manufacturing process. A recording signal (excitation signal) is input from bonding pads to the thin film magnetic head in a rowbar, and the magnetic field generated by the write pole (element) included in the thin film magnetic head is observed directly by using a magnetic force microscope (MFM), a scanning Hall probe microscope (SHPM), or a scanning magneto resistance effect microscope (SMRM) that performs a scanning motion at a position equivalent to the flying height of the magnetic head. In this manner, a shape of the generated magnetic field instead of the physical shape of the write pole (element) is measured; thus, a non-destructive inspection can be performed on the effective magnetic track width.

Abstract: A magnetic head inspection method is provided with the step that an area smaller than a half of a scanning and measurement area of a magnetic probe in a cantilever unit of the MFM is set as a scanning and measurement area on a surface of a recording portion of the magnetic head that is scanned by the AFM, so as to greatly reduce the inspection time (tact time) of the AFM.

Abstract: An SPM probe includes: an SPM cantilever; a thermal resistance formed at a probe portion of the SPM cantilever; an insulating film formed on the thermal resistance; and one wire for converting the micro-scale energy source into heat or propagating light, formed on the insulating film.

Abstract: A magnetic head inspection method is provided with the step that an area smaller than a half of a scanning and measurement area of a magnetic probe in a cantilever unit of the MFM is set as a scanning and measurement area on a surface of a recording portion of the magnetic head that is scanned by the AFM, so as to greatly reduce the inspection time (tact time) of the AFM.

Abstract: A device for transporting a magnetic head, a device for inspecting a magnetic head, and a method for manufacturing a magnetic head are provided. The device for transporting a magnetic head is capable of freely changing a posture of a thin film magnetic head when transporting a row bar-shaped thin film magnetic head. The transporting device for transporting a slender rectangular plate-like, that is, row bar-shaped magnetic head, cut from a wafer is capable of performing vertical installation and horizontal installation. The transporting device for transporting a slender rectangular plate-like, i.e., row bar-shaped magnetic head, is capable of performing the vertical installation and horizontal installation, and changing the posture of the magnetic head from vertical installation into horizontal installation and from horizontal installation into vertical installation when transporting the magnetic head between processes.

Abstract: Applying an alternating current to a magnetic head as a sample generates an alternate-current magnetic field from the sample. A cantilever includes a probe that is made of a magnetic material or is coated with a magnetic material. The cantilever is displaced when it approaches the sample. Detecting the displacement of the cantilever detects distribution of the magnetic field from the sample. It is possible to fast measure distribution of the magnetic field generated from the sample when a frequency of the alternating current applied to the sample differs from a resonance frequency of the cantilever.

Abstract: A magnetic head inspection device inspects the write track width of a thin film magnetic head in a phase as early as possible during the manufacturing process. A recording signal (excitation signal) is input from bonding pads to the thin film magnetic head in a rowbar, and the magnetic field generated by the write pole (element) included in the thin film magnetic head is observed directly by using a magnetic force microscope (MFM), a scanning Hall probe microscope (SHPM), or a scanning magneto resistance effect microscope (SMRM) that performs a scanning motion at a position equivalent to the flying height of the magnetic head. In this manner, a shape of the generated magnetic field instead of the physical shape of the write pole (element) is measured; thus, a non-destructive inspection can be performed on the effective magnetic track width.