An ion beam device according to the present invention includes a gas field ion source (1) including an emitter tip (21) supported by an emitter base mount (64), a ionization chamber (15) including an extraction electrode (24) and being configured to surround the emitter tip (21), and a gas supply tu
An ion beam device according to the present invention includes a gas field ion source (1) including an emitter tip (21) supported by an emitter base mount (64), a ionization chamber (15) including an extraction electrode (24) and being configured to surround the emitter tip (21), and a gas supply tube (25). A center axis line of the extraction electrode (24) overlaps or is parallel to a center axis line (14A) of the ion irradiation light system, and a center axis line (66) passing the emitter tip (21) and the emitter base mount (64) is inclinable with respect to a center axis line of the ionization chamber (15). Accordingly, an ion beam device including a gas field ion source capable of adjusting the direction of the emitter tip is provided.
대표청구항▼
1. An ion beam device comprising: a gas field ion source, including a vacuum chamber, a vacuum exhaust mechanism, an emitter tip that composes a needle-shaped anode, an extraction electrode that composes a cathode in the vacuum chamber, and a cooling mechanism which cools the emitter tip, for supply
1. An ion beam device comprising: a gas field ion source, including a vacuum chamber, a vacuum exhaust mechanism, an emitter tip that composes a needle-shaped anode, an extraction electrode that composes a cathode in the vacuum chamber, and a cooling mechanism which cools the emitter tip, for supplying gas molecules to a vicinity of a distal end of the emitter tip and ionizing the gas molecules with an electric field at the distal end of the emitter tip;an ion beam device main body including a lens system which focuses an ion beam extracted from the emitter tip, a sample chamber incorporating a sample, and a secondary particle detector which detects secondary particles released from the sample; anda mount which supports the ion beam device main body,wherein a vibration proofing mechanism is arranged in a heat transmission path for transmitting heat generated in the cooling mechanism from the cooling mechanism to the emitter tip in the vacuum chamber. 2. The ion beam device according to claim 1, wherein the cooling mechanism comprises a coldness generation means configured to generate cooling by expanding a pressurized gas generated in a compressor unit, and a heat transmission means configured to cool at least the emitter tip with a gas cooled by the coldness generated by the coldness generation means. 3. The ion beam device according to claim 2, wherein the cooling mechanism is a mechanism for cooling at least the emitter tip with an inactive gas cooled by a refrigerator. 4. The ion beam device according to claim 1, wherein the cooling mechanism is a refrigerator, and the vibration proofing mechanism is a gas pot which accommodates a cooling stage of the refrigerator, and wherein the cooling mechanism cools inactive gas in the gas pot with the refrigerator to cool the at least the emitter tip through the cooled inactive gas. 5. The ion beam device according to claim 4, wherein a bellows is arranged between the gas pot and a supporting mechanism of the refrigerator. 6. The ion beam device according to claim 1, wherein the cooling mechanism comprises a coldness generation means configured to generate cooling by expanding a first pressurized gas generated in a compressor unit and circulating means configured to circulate a second pressurized gas cooled with the coldness of the coldness generation means to cool at least the emitter tip. 7. The ion beam device according to claim 2, wherein the cooling mechanism includes a refrigerator and a mechanism which cools at least the emitter tip by circulating a pressurized gas cooled with the coldness of the refrigerator. 8. The ion beam device according to claim 1, wherein the vibration proofing mechanism includes a deformable member which is arranged between the emitter tip and a cooling stage of the cooling mechanism. 9. The ion beam device according to claim 1, wherein the cooling mechanism includes a cooling agent produced by cooling a cooling medium gas, which is in a gas state under normal temperature and atmosphere pressure, to a liquid or solid state, and the vibration proofing mechanism includes a deformable member which is arranged in a heat transmission path between the cooling mechanism and the emitter tip. 10. The ion beam device according to claim 1, further comprising: a base plate for supporting a main body of the ion beam device; a mount which supports the base plate; and a second vibration proofing mechanism which is arranged between the base plate and the main body of the ion beam device, wherein the cooling mechanism is supported by a supporting mechanism fixed to a floor on which the ion beam device is installed or fixed to the mount. 11. The ion beam device according to claim 1, further comprising: an objective lens and a lens, which focus an ion beam extracted from the emitter tip; a sample chamber incorporating a sample; and a secondary particle detector which detects secondary particles released from the sample, wherein an ion beam diameter is focused to 0.5 nm by reducing a distance from a distal end of the objective lens to a surface of the sample to less than 2 mm. 12. The ion beam device according to claim 1, wherein a structural dimension of the sample is measured with an accelerating voltage of the ion beam equal to or greater than 50 kV. 13. The ion beam device according to claim 1, wherein hydrogen gas is used. 14. The ion beam device according to claim 1, wherein an energy of the ion beam is smaller than 1 keV. 15. An ion beam device comprising: a vacuum chamber;an extraction electrode for extracting an ion beam;a gas field ion source which ionizes gas molecules with an electric field at a distal end of an emitter tip;a cooling mechanism which cools the emitter tip;a focusing lens system which focuses the ion beam extracted from the emitter tip;a sample chamber which accommodates a sample;a charged particle detector which detects a secondary charged particle released from the sample; anda heat transmission section which is coupled with the emitter tip and is configured to transmit heat to the emitter tip,wherein the cooling mechanism is spatially separated from the emitter tip and the heat transmission section, cools a gas to arrange the cooled gas to a space between the cooling mechanism and the heat transmission section, and cools the emitter tip by cooling the heat transmission section through the cooled gas, andwherein a vibration proofing mechanism is arranged in the heat transmission section for transmitting heat generated in the cooling mechanism from the cooling mechanism to the emitter tip in the vacuum chamber. 16. An ion beam device comprising: a vacuum chamber;an extraction electrode for extracting an ion beam;a gas field ion source which ionizes gas molecules with an electric field at a distal end of an emitter tip;a cooling mechanism which cools the emitter tip;a focusing lens system which focuses the ion beam extracted from the emitter tip;a sample chamber which accommodates a sample;a charged particle detector which detects a secondary charged particle released from the sample; anda heat transmission section which is coupled with the emitter tip and is configured to transmit heat to the emitter tip,wherein the cooling mechanism includes an exhaust section which solidifies a cooling agent by lowering atmospheric pressure and cools the emitter tip by cooling the heat transmission section through the solidified cooling agent. 17. The ion beam device according to claim 16, further comprising a temperature measuring section which measures a temperature of the cooling agent.
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