1. Field of the Invention
The present invention relates to a drawing apparatus for drawing on a substrate with a plurality of charged particle beams, a drawing data generation method, a storage medium which stores a program for generating drawing data, and an article manufacturing method.
2. Description of the Related Art
In recent years, as micronization of the element, increasingly complex circuit patterns, or a higher capacity of pattern data advance, the drawing accuracy of drawing apparatuses for use in the manufacturing of devices such as semiconductor integrated circuits need to be improved. As a method for realizing such requirements, a drawing apparatus that draws a pattern on a substrate by controlling the deflection and blanking of a charged particle beam such as an electron beam or the like is known. As such a drawing apparatus, Japanese Patent Laid-Open No. 2002-353113 discloses a multiple beam-type charged particle beam exposure apparatus using a plurality of charged particle beams in order to achieve improvements in throughput. The charged particle beam exposure apparatus includes a blanking deflector array (blanker array) in which a plurality of pairs of electrodes for independently deflecting a plurality of charged particle beams is formed into a single flat plate. In addition, M. J. Wieland, “Throughput enhancement technique for MAPPER maskless lithography”, SPIE vol. 7637, 76371Z-1, discloses a drawing apparatus with an increase in the total number of charged particle beams for improving the productivity of a multiple beam-type charged particle beam drawing apparatus. The drawing apparatus includes a blanking deflector array integrated with a pair of electrodes and a C-MOS circuit.
In the multiple beam-type charged particle beam drawing apparatus, it is contemplated that the number of charged particle beams is further increased to realize further improvement in throughput. However, an increase in the number of charged particle beams entails an increase in the scale of the circuit incorporated in the blanking deflector array. Here, since the rate of operation of the circuit incorporated in the blanking deflector array varies with a drawing pattern, the current flowing through the circuit provided in the blanking deflector array may vary with time during drawing processing. A charged particle beam passing through the pair of electrodes provided in the blanking deflector array becomes readily unstable under the influence of the variation of the magnetic field due to a change in current. Thus, an increase in the scale of the circuit may undesirably increase the influence of the variation of the magnetic field on the resolution performance or the superposition accuracy of the drawing apparatus.
The present invention provides, for example, a drawing apparatus that is advantageous in decreasing of influence of a magnetic field generated by a blanking deflector array.
According to an aspect of the present invention, a drawing apparatus that performs drawing on a substrate with a plurality of charged particle beams is provided that includes a blanking deflector array including a plurality of blanking deflectors configured to respectively blank the plurality of charged particle beams; and a controller configured to control the blanking deflector array based on drawing data, wherein the controller is configured to control the blanking deflector array such that a position error of the plurality of charged particle beams on the substrate due to a magnetic field generated by the blanking deflector array is less than that in a case where the controller controls the blanking deflector array in accordance with initial drawing data.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
Firstly, a description will be given of a charged particle beam drawing apparatus (hereinafter referred to as “drawing apparatus”) according to one embodiment of the present invention. In particular, the drawing apparatus of the present embodiment is intended to employ a multiple beam system in which a plurality of electron beams (charged particle beams) is deflected and turning the irradiation of electron beams ON and OFF is independently controlled so as to draw predetermined drawing data at a predetermined position on a substrate to be treated (a substrate). Here, a charged particle beam of the present embodiment is not limited to an electron beam, but may be other charged particle beams such as an ion beam.
The electron gun 2 has a mechanism that emits an electron beam by applying heat or electric field. In
Here, a detailed description will be given of the configuration of the blanking deflector array 13.
The substrate stage 5 is movable (drivable) at least in the XY axis direction while holding the substrate to be treated 7 using, for example, electrostatic adsorption. The position of the substrate stage 5 is measured in real time by an interferometer (laser length measuring machine) (not shown).
The control unit 6 has various control circuits that control the operation of the components related to drawing with the drawing apparatus 1, and a main control unit 30 that supervises the control circuits. As the control circuits, firstly, a first lens control circuit 31, a second lens control circuit 32, and a third lens control circuit 33 control the operation of the collimator lens 10, the first electrostatic lens array 12, and the second electrostatic lens array 16, respectively. A drawing pattern generation circuit 34 generates a drawing pattern. A bit map conversion circuit 35 converts the drawing pattern into bit map data. A blanking command generation circuit 36 generates the command information based on the bit map data. Here, the control unit 6 includes the blanking command generation circuit 36 and functions as a control unit that controls the blanking deflector array 13. A deflection amplifier unit 37 controls the operation of the deflector array 15 based on a deflection signal generated by a deflection signal generation circuit 38. A stage control circuit 39 calculates a command target value to be input to the substrate stage 5 based on the stage position coordinates which are the command transmitted from the main control unit 30, and drives the substrate stage 5 such that the position of the substrate stage 5 after being driven reaches the target value. During pattern drawing, the stage control circuit 39 continuously scans the substrate to be treated 7 (the substrate stage 5) in the Y-axis direction. At this time, the deflector array 15 deflects an image on the surface of the substrate to be treated 7 in the X-axis direction based on the length measurement result of the substrate stage 5 obtained by an interferometer or the like. Then, the blanking deflector array 13 performs the ON/OFF operation of the irradiation of the electron beam so as to obtain a target dose on the substrate to be treated 7.
Next, a description will be given of the effect of the drawing apparatus 1. If the number of electron beams to be employed is increased so as to achieve improvements in throughput, the scale of the circuit constituting the blanking deflector array 13 also increases. For example, the rate of operation of each of the drive circuits 21 incorporated in the blanking deflector array 13 varies with a drawing pattern, and the current flowing through the circuit provided in the blanking deflector array 13 may vary with time during drawing processing. At this time, an electron beam passing through the opening between each of the pair of electrodes provided in the blanking deflector array 13 is affected by the variation of the magnetic field that has increased due to an increase in the scale of the circuit accompanying an increase in the number of electron beams, resulting in a change in the position of the electron beam. Accordingly, in the drawing apparatus 1 of the present embodiment, the blanking command generation circuit 36 provided in the control unit 6 corrects the drawing pattern (drawing data) output from the bit map conversion circuit 35 so as to reduce the variation.
Firstly, a description will be given of internal processing performed by the blanking command generation circuit (command generation unit: hereinafter referred to as “command generation circuit”) 36 according to the present embodiment.
Hereinafter, a detailed description will be given of the calculation steps and the correction step. Firstly, a description will be given of calculation of the change in the rate of operation of the drive circuits 21 in step S100.
Here, the command generation circuit 36 calculates the difference between the number of operation circuits of the drive circuits 21 at the first timing and the number of operation circuits of the drive circuits 21 at the second timing to thereby be able to obtain the change in the rate of operation of the drive circuits 21. Note that a method for dividing a plurality of the blanking devices 22 into blocks is not limited to the method described above. The command generation circuit 36 may also be adapted to capture a change in the operation state by considering the positions of the blanking devices 22 in operation instead of capturing the change in the rate of operation.
Next, a description will be given of calculation of a change (variation) in current flowing through the blanking deflector array 13 in step S101. The current generated when the blanking deflector array 13 is in operation, that is, when a plurality of the drive circuits 21 is in operation, depends on the specification of the blanking deflector array 13. In other words, current can be estimated from, for example, the gate capacitance, junction capacitance, wiring capacitance, and load capacitance of the CMOS circuit and the voltage and frequency of the drive signal applied thereto. Electric current can also be obtained by direct measurement by actually driving the blanking deflector array 13. Then, once the command generation circuit 36 multiplies the current obtained as described above by a change in the rate of operation of the drive circuits 21 obtained from Table 1, the change in current can be calculated. Note that a wiring (not shown) for connecting the drive circuit 21 to the pair of electrodes 20 is also present in the Z-axis direction, and thus, current also flows in the Z-axis direction.
Next, a description will be given of calculation of a change (variation) in magnetic field generated by the blanking deflector array 13 in step S102. For example, the magnetic field variation ΔB due to the variation of current in any one block (specific block) of the first block 50 to the sixth block 55 in the operation state shown in
Here, μ represents permeability of vacuum, ΔIn (n is a number for specifying a block) represents a change (the amount of variation) in current, and Rn represents the distance between a specific block and other blocks. The distance can be calculated as a distance between the central points of the blocks. In other words, a change in magnetic field of any one block is the result of integrating the changes in magnetic field generated by the blocks located therearound.
Next, a description will be given of calculation of the amount of shift in step S103. The command generation circuit 36 calculates the amount of deflection of the electron beam due to a change in magnetic field based on the calculation results of the change in magnetic field described above. When the direction of a change in magnetic field is the X-axis direction, the deflected direction of an electron beam due to a change in magnetic field is the Y-axis direction. Then, the command generation circuit 36 calculates the amount of shift (position error) ΔY of the electron beam on the substrate to be treated 7 using the following Formula 2.
ΔY=ΔB×L×2×l [Formula 2]
Here, L represents the distance between the blanking deflector array 13 and the substrate to be treated 7 placed on the substrate stage 5, and l represents the size of the blanking deflector array 13 in the direction of travel to the electron beam (the Z-axis direction). Then, the command generation circuit 36 corrects (changes) the initial drawing pattern based on the amount of shift ΔY in step S104. While, in the present embodiment, the command generation circuit 36 executes the calculation of a change in current or magnetic field based on a change in the rate of operation of the drive circuits 21, the present invention is not limited thereto. For example, the command generation circuit 36 may also measure the amount of shift (position error) of the electron beam in various operation states of the drive circuits 21 using a detector disposed at the upper part of the substrate stage 5 so as to correct the initial drawing pattern based on the results of measurement.
As described above, according to the present embodiment, a drawing apparatus that is advantageous for decreasing the influence of the magnetic field generated by a blanking deflector array may be provided. For executing the processes as described above, the command generation circuit 36 may also include a logic circuit such as a CPU, an FPGA, or an ASIC, and a memory. Also, in the present embodiment, the command generation circuit 36 is included in the control unit 6 and is a component that is separated from the blanking deflector array 13 (the circuit board including the blanking deflector array 13). However, the arrangement of the command generation circuit 36 is not limited thereto. For example, a device (circuit element) for executing a part or all of the functions of the command generation circuit 36 may also be integrated into a circuit board including the blanking deflector array 13.
The present invention may also be realized by executing the following processing. Specifically, a program (software) for realizing the functions of the embodiment is provided in a system or apparatus via network or various storage media. Then, the provided (and stored) program is (read from a storage medium) executed by a computer (a CPU, an MPU, or the like) of the system or apparatus. In this case, the program and the storage medium on which the program is stored constitute the present invention.
An article manufacturing method according to an embodiment of the present invention is preferred in, for example, manufacturing a micro device, such as a semiconductor device or the like or an article such as an element or the like having a microstructure. The article manufacturing method may include the step of forming a latent image pattern on a substrate on which a photosensitizing agent is coated using the aforementioned drawing apparatus (a step of drawing a pattern on a substrate); and developing the substrate on which the latent image pattern has been formed in the latent image pattern step. Furthermore, the article manufacturing method may include other known steps (oxidizing, film forming, vapor depositing, doping, flattening, etching, resist peeling, dicing, bonding, packaging, and the like). The article manufacturing method of the present embodiment has an advantage, as compared with a conventional article manufacturing method, in at least one of performance, quality, productivity and production cost of an article.
While the embodiments of the present invention have been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2011-211863 filed Sep. 28, 2011 which are hereby incorporated by reference herein it their entirety.
Number | Date | Country | Kind |
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2011-211863 | Sep 2011 | JP | national |