A charged particle beam writing apparatus includes a processing circuitry configured to calculate a third proximity effect correction irradiation coefficient where at least one correction irradiation coefficient term up to k-th order term, in correction irradiation coefficient terms of from a first order term to a n-th order term for a first proximity effect correction irradiation coefficient which does not take account of a predetermined effect, are replaced by at least one correction irradiation coefficient term up to the k-th order term, for a second proximity effect correction irradiation coefficient which takes account of the predetermined effect; and a processing circuitry configured to calculate a dose by using the third proximity effect correction irradiation coefficient.

The present disclosure provides a method that includes forming a first patternable material layer on a substrate; forming a second patternable material layer over the first patternable material layer; and performing a charged particle beam lithography exposure process to the first patternable material layer and the second patternable material layer, thereby forming a first latent feature in the first patternable material layer.

An IC manufacturing model is disclosed, wherein input variables and an output variable are measured using a calibration set of patterns. The model can or cannot include a PSF. The output variable may be a dimensional bias between printed patterns and target patterns or simulated patterns. It can also be a Threshold To Meet Experiments. The input variables may be defined by a metric which uses kernel functions, preferably with a deformation function which includes a shift angle and a convolution procedure. A functional or associative relationship between the input variables and the output variable is defined. Preferably this definition includes normalization steps and interpolation steps. Advantageously, the interpolation step is of the kriging type. The invention achieves a much more accurate modeling of IC manufacturing, simulation or inspection processes.

In a method for forming a resist film, a first resist film is formed on a light shielding film formed on a substrate, by using a spin coating method. A protective film is formed on the first resist film. The protective film and the first resist film are simultaneously removed at the same region to expose a portion of the light shielding film. A first region in which the second resist film is formed on the light shielding film and a second region in which the second resist film is formed on the first resist film through the protective film, are provided. The protective film and the second resist film are simultaneously removed in the second region to expose the first resist film. A region in which the first resist film, and a region in which the second resist film, is formed, are separately provided on the substrate.

A method for nanometre etching or printing using an electron beam in a humid environment, which belongs to the field of electronic exposure. The method comprises: first, attaching a solution, humid atmosphere or humid environment curing layer to the surface of a substrate required to be etched and printed; then placing same in an electron beam exposure device to conduct electron beam exposure, so that a required nanometre micromachining pattern can be etched and printed on the substrate. The humid environment solution used in the method is mostly deionized water, solution containing metal ions, complex or other environment-friendly solutions. In this method, a nanoscale micromachining finished product can be obtained after electron beam exposure without chemical components such as photoresist, etc. required in the traditional electron beam etching or printing process and complicated machining processes such as fixation, rinsing, etching, gold-plating, etc. Moreover, the electron beam exposure rate is fast, the line width of electron beam photoetching or printing is uniform, and the size of the line width is the same as that of the electron beam. Therefore, the production efficiency can be greatly increased, thereby reducing nanoscale micromachining production costs.

Methods and systems for direct lithographic pattern definition based upon electron beam induced alteration of the surface chemistry of a substrate are described. The methods involve an initial chemical treatment for global definition of a specified surface chemistry (SC). Electron beam induced surface reactions between a gaseous precursor and the surface are then used to locally alter the SC. High resolution patterning of stable, specified surface chemistries upon a substrate can thus be achieved. The defined patterns can then be utilized for selective material deposition via methods which exploit the specificity of certain SC combinations or by differences in surface energy. It is possible to perform all steps in-situ without breaking vacuum.

Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a blanker aperture array (BAA) for an e-beam tool is described. The BAA is a non-universal cutter.

In a charged particle beam writing apparatus, a charged particle optical system includes a first, second, and third deflection control system configured to form a shot of a charged particle beam, control a shape and size of the shot, and control an irradiation position of the shot respectively. A shot data generation processing device generates shot data of writing a latent image on a resist layer in a sample, using (1) design data of a pattern to be formed in a member, wherein the member is formed in a sample, and the resist layer is formed on the member, and (2) correction information of a shot size and an irradiation shot position obtained from in-plane distribution data of an XY dimension variation amount of dimension measurement patterns. The dimension measurement patterns are formed by writing test patterns on a resist layer and transferring the test patterns onto a member.

The present disclosure provides a method that includes forming a first patternable material layer on a substrate; forming a second patternable material layer over the first patternable material layer; and performing a charged particle beam lithography exposure process to the first patternable material layer and the second patternable material layer, thereby forming a first latent feature in the first patternable material layer.

The disclosure relates to a multiple charged particle beam writing apparatus that includes a dose representative value calculator that determines a representative dose for each mesh region irradiated by multiple beams. A calculation processor computes the temperature rise in a mesh region of interest due to beam irradiation, using a convolution of the dose values and a thermal spread function. An effective temperature calculator repeats this process while shifting the processing region along the stripe to obtain multiple temperature rises of the mesh area of interest and calculate a representative value of the multiple temperature rises as an effective temperature of the mesh area of interest. Based on the effective temperature, a dose corrector adjusts the beam doses to compensate for resist heating effects.