Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.

A charged particle beam system capable of reducing contamination has a sample chamber (15) in which the sample (S) is irradiated with a charged particle beam and a receptacle chamber (21) which is connected into the sample chamber (15) via an isolation valve (25) and is connected to the ambient via a door (26). A transport mechanism (22) conveys the sample (S) from the ambient via the door (26) into the receptacle chamber (21) and via the isolation valve (25) into the sample chamber (15). A cleaning portion supplies active oxygen into the receptacle chamber which can then be evacuated by a vacuum pump.

There is provided a charged particle beam system capable of reducing contamination of at least one sample. The charged particle beam system (100) has a sample chamber (15) in which the sample (S) is irradiated with a charged particle beam. The system (100) has a receptacle chamber (21) which is connected into the sample chamber (15) via an isolation valve (25) and in which the sample (S) is accommodated. The system further includes a transport mechanism (22) for conveying the sample (S) from the receptacle chamber (21) into the sample chamber (15), an exhaust portion (24) for vacuum pumping the receptacle chamber (21), and a cleaning portion (30) for cleaning the sample (S) accommodated in the receptacle chamber (21).

The present invention has for its object to provide a charged particle beam irradiation method and a charged particle beam apparatus which can suppress unevenness of electrification even when a plurality of different kinds of materials are contained in a pre-dosing area or degrees of density of patterns inside the pre-dosing area differs with positions. To accomplish the above object, a charged particle beam irradiation method and a charged particle beam apparatus are provided according to which the pre-dosing area is divided into a plurality of divisional areas and electrifications are deposited to the plural divisional areas by using a beam under different beam irradiation conditions. With the above construction, the electrifications can be deposited to the pre-dosing area on the basis of such an irradiation condition that the differences in electrification at individual positions inside the pre-dosing area can be suppressed and consequently, an influence an electric field has upon the charged particle beam and electrons given off from the sample can be suppressed.

Systems and methods for implementing charged particle flooding in a charged particle beam apparatus are disclosed. According to certain embodiments, a charged particle beam system includes a charged particle source and a controller which controls the charged particle beam system to emit a charged particle beam in a first mode where the beam is defocused and a second mode where the beam is focused on a surface of a sample.