Disclosed is a charged particle beam system comprising a charged particle beam column having a charged particle source forming a charged particle beam, an objective lens and a first deflection system for changing a position of impingement of the charged particle beam in a sample plane. The system further comprises a sample chamber comprising a sample stage for holding a sample to be processed, and a controller configured to create and store a height map of a sample surface. The controller is further configured to dynamically adjust the objective lens of the charged particle beam in dependence on a position of impingement of the charged particle beam according to the height map.

According to one aspect of the present invention, a charged particle beam apparatus includes fogging charged particle amount distribution operation processing circuitry that operates a fogging charged particle amount distribution by performing convolution integration of a distribution function in which a design distribution center of fogging charged particles is shifted and a exposure intensity distribution in which a design irradiation center of a charged particle beam is not shifted; positional displacement operation processing circuitry that operates a positional displacement based on the fogging charged particle amount distribution; correction processing circuitry that corrects an irradiation position using the positional displacement; and a charged particle beam column including an emission source that emits the charged particle beam and a deflector that deflects the charged particle beam to irradiate a corrected irradiation position with the charged particle beam.

A charged particle beam writing method includes acquiring the deviation amount of the deflection position per unit tracking deflection amount with respect to each tracking coefficient of a plurality of tracking coefficients having been set for adjusting the tracking amount to shift the deflection position of a charged particle beam on the writing target substrate in order to follow movement of the stage on which the writing target substrate is placed, extracting a tracking coefficient based on which the deviation amount of the deflection position per the unit tracking deflection amount is closest to zero among the plurality of tracking coefficients, and writing a pattern on the writing target substrate with the charged particle beam while performing tracking control in which the tracking amount has been adjusted using the tracking coefficient extracted.

A semiconductor device and method is disclosed. In one example, the method for forming a semiconductor device includes forming a trench extending from a front side surface of a semiconductor substrate into the semiconductor substrate. The method includes forming of material to be structured inside the trench. Material to be structured is irradiated with a tilted reactive ion beam at a non-orthogonal angle with respect to the front side surface such that an undesired portion of the material to be structured is removed due to the irradiation with the tilted reactive ion beam while an irradiation of another portion of the material to be structured is masked by an edge of the trench.

An ion implanter includes an ion source configured to generate an ion beam including an ion of a nonradioactive nuclide, a beamline configured to support an ion beam irradiated target, and a controller configured to calculate an estimated radiation dosage of a radioactive ray generated by a nuclear reaction between the ion of the nonradioactive nuclide incident into the ion beam irradiated target and the nonradioactive nuclide accumulated in the ion beam irradiated target as a result of ion beam irradiation performed previously.

An electron beam source comprising a cathode, an anode, a means for deflecting an electron beam over a target surface and at least one vacuum pump, the electron beam source further comprising a contraction area arranged between the anode and the means for deflecting the electron beam where a hole in the contraction area is aligned with a hole in the anode with respect to the cathode, a first vacuum pump is arranged between the contraction area and the anode and a second vacuum pump is arranged above the anode, a gas inlet is provided between the contraction area and the means for deflecting the electron beam, wherein a first crossover of the electron beam is arranged between the cathode and the anode and a second crossover is arranged at or in close proximity to the contraction area.

A multiple charged particle writing method includes performing a tracking operation by shifting the main deflection position of multiple beams using charged particle beams in the direction of stage movement so that the main deflection position of the multiple beams follows the stage movement while a predetermined number of beam shots of the multiple beams are performed, and shifting the sub deflection position of the multiple beams so that each beam of the multiple beams straddles rectangular regions among plural rectangular regions obtained by dividing a writing region of a target object into meshes by the pitch size between beams of the multiple beams, and the each beam is applied to a different position in each of the rectangular regions straddled, and applying a predetermined number of shots per beam using plural beams in the multiple beams to each of the plural rectangular regions, during the tracking operation.

A system and method for optimizing a ribbon ion beam in a beam line implantation system is disclosed. The system includes a mass resolving apparatus having a resolving aperture, in which the resolving aperture may be moved in the X and Z directions. Additionally, a controller is able to manipulate the mass analyzer and quadrupole lenses so that the crossover point of desired ions can also be moved in the X and Z directions. By manipulating the crossover point and the resolving aperture, the parameters of the ribbon ion beam may be manipulated to achieve a desired result. Movement of the crossover point in the X direction may affect the mean horizontal angle of the beamlets, while movement of the crossover point in the Z direction may affect the horizontal angular spread and beam current.

Apparatus include a plurality of electrode arrangements spaced apart from each other opposite an ion propagation axis and defining an ion transfer channel that extends along the ion propagation axis that tapers between an input end that is situated to receive ions and an output end that is situated to couple the received ions to an input end of an ion guide. Methods include positioning a plurality of electrode arrangements at oblique angles opposite an ion propagation axis so as to form a ion transfer channel that tapers between an input end and an output end, and coupling the output end of the ion transfer channel to an input end of an ion optical element so as to direct ions in the ion transfer channel into the ion optical element. Related systems are also disclosed.

Disclosed is a charged particle beam system comprising a charged particle beam column having a charged particle source forming a charged particle beam, an objective lens and a first deflection system for changing a position of impingement of the charged particle beam in a sample plane. The system further comprises a sample chamber comprising a sample stage for holding a sample to be processed, and a controller configured to create and store a height map of a sample surface. The controller is further configured to dynamically adjust the objective lens of the charged particle beam in dependence on a position of impingement of the charged particle beam according to the height map.