JPH0656800B2 - Charge beam device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charged beam device, and more particularly to a synchrotron radiation (synchronization) generated by accelerating and accumulating a charged beam such as an electron beam, and a deflecting portion of the charged beam. (Also referred to as tron radiation).

[Conventional technology]

FIG. 4 is a plan view showing a conventional charged particle beam system. 1
Is a charged beam accelerating injector having a function of accelerating the charged beam to a predetermined energy and then injecting the charged beam into a charged beam storage ring described later. The charged beam transport unit 3 provided for transporting to and from the beam storage ring is a charged beam storage ring for storing a charged beam having a predetermined energy for a long time and utilizing the emitted light 9. In this charged beam storage ring 3, a radiation light beam line (the beam here is a photon beam) 4 for guiding the radiation light to the outside, a deflection electromagnet 6 for deflecting the charged beam to generate radiation light 9, In addition, there is a vacuum donut 7 for keeping the degree of vacuum at, for example, about 10 ⁻⁹ Torr in order to keep the charged beam rotating for a long time. Reference numeral 8 in the figure shows the equilibrium orbit of the charged beam, and it is known that the radiated light 9 is emitted from the curved portion of the equilibrium orbit 8 of the charged beam in the tangential direction thereof. Further, 10 is a high frequency cavity. In addition to this, although there is a vacuum exhaust device and an electromagnet for adjusting the orbit, which are not shown, only the portions related to the present invention are shown. Although only two radiated light beam lines 4 are shown in the figure, a plurality of radiated light beam lines 4 usually come out from each deflection section. A linear accelerator, a synchrotron or the like is usually used as the charged beam accelerating injector 1. The operation of this type of conventional device will be described in detail below.

The charged beam accelerated by the charged beam accelerating injector 1 to a predetermined energy (here, E) is incident on the charged beam storage ring 3 via the vacuum beam transport unit 2.
After that, the energy E remains as it is and the equilibrium orbit 8 continues to rotate. However, since the charged beam emits the radiated light 9 every time it is deflected, an energy loss occurs due to the radiation loss. This is not compensated by the high frequency cavity 10 shown in the figure, and a predetermined energy is maintained. Furthermore, it is important that the number of charged particles rotating in the charged beam storage ring 3 decreases with time. This mechanism is as follows.

Inside the vacuum donut 7, which is evacuated to high vacuum,
Despite the high vacuum, some residual molecules are present. Therefore, the residual molecules collide with the charged beam and are scattered, and collide with the wall surface of the vacuum donut 7, and the charged beam, that is, the group of charged particles gradually decreases with time. In addition to this, it is known that the number of particles in the charged beam decreases with a certain probability. In fact, in conventional devices, the charged beam is depleted, usually with a lifetime of several hours. The lifetime is generally defined as the time until the number of charged particles contained in the charged beam decreases to 1/2 or 36.8% (1 / e) of the original number of particles. Is. When expressing the number of charged particles, the current value of the charged beam (denoted by Ib here) is often used. When the velocity of the charged beam is sufficiently close to the light velocity (this condition is satisfied in a charged beam device for normal use of synchrotron radiation), the current value Ib of the charged beam is proportional to the number N of charged particles.

Ib = f · g · N (1) where g is the charge of one charged particle and f is the rotation frequency of the charged particle in the ring.

That is, in summary of what has been described here, since the energy of the charged beam in the charged particle storage ring 3 does not change with the passage of time, the current value of the charged beam decreases with the passage of time. is there.

Now, the intensity of emitted light will be described. The intensity of the synchrotron radiation is calculated from the energy E of the charged beam and the current value Ib of the charged beam as shown in the document “Favorite Lithography Technology for the Next Generation”, Nobufumi Arita, Journal of Japanese Science and Technology 84. = Α · E ⁴ · Ib (2) Here, P is the intensity or total power of the radiated light, and α is a constant determined by the shape of the charged beam storage ring.

Therefore, the intensity of the emitted light decreases with time.
That is, the amount of emitted light decreases with time,
It is inconvenient to use.

[Problems to be solved by the invention]

In the conventional charged beam apparatus described above, the intensity or quantity of the radiated light emitted from the charged beam that has once entered the charged beam storage ring from the charged beam accelerating injector through the charged beam transport unit decreases with time, It was inconvenient. Also, the number of synchrotron radiation beamlines that can be effectively used per device is limited by the spatial dimension of the port for synchrotron radiation beamlines from the vacuum donut. Therefore, it is naturally conceivable to increase the number of available synchrotron radiation beam lines by providing a number of charged beam storage rings for one charged beam accelerating injector, but the biggest problem in this case is That is, the intensity or the amount of emitted light emitted from the beam storage ring is different from each other, which causes a problem in use. That is, although the intensities or amounts of emitted light obtained from a plurality of emitted light beam lines arranged in a single charged beam storage ring are equal to each other,
The problem is that the intensity of emitted light varies between different charged beam storage rings. The reason for this is that even if the charged beam storage rings are designed and manufactured in exactly the same manner and the same vacuum exhaust equipment is provided, the rate of desorption of adsorbed gas from the vacuum donuts depends on the conditions at the time of degassing at the material stage (for example, There are slight differences based on subtle differences in baking temperature and atmosphere) and variations in materials. Furthermore, a slight difference in finishing accuracy between the deflection electromagnet and the orbital adjustment electromagnet and a variation in current value,
Alternatively, this is because the temporal change of the current value of the charged beam differs depending on each charged particle storage ring due to installation error or the like.

The present invention has been made to solve the conventional problems as described above, and it is possible to obtain a sufficient number of synchrotron radiation beam lines that can be effectively used, the radiant light intensity is substantially constant, and An object of the present invention is to obtain a charged beam device which can obtain a particle storage ring with uniform light intensity.

[Means for solving problems]

A charged beam apparatus according to the present invention comprises a single charged beam accelerating injector and a charged beam transporter, a plurality of charged beam storage rings, and a light amount monitor of emitted light or a current monitor of accumulated charge beams. Depending on the value monitored by the monitor or the current monitor, the charged beams are sequentially transferred from the charged beam accelerating injector to the charged beam transport unit so that the amount of the emitted light generated from each charged beam storage ring becomes constant at a predetermined value. The charged beam storage ring is replenished via the via.

[Action]

In the present invention, with the above-described configuration, the amount of emitted light is controlled to be constant at a predetermined value, and the property and amount of usable emitted light can be greatly improved.

〔Example〕

 An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a charged particle beam apparatus according to an embodiment of the present invention, and this embodiment shows a case in which two or more charged particle beam storage rings 3 are provided.

Reference numeral 5 denotes a light quantity monitor of the radiated light attached to the radiated light beam line 4 of each charged beam storage ring 3. Further, 13 receives a signal proportional to the light amount from the light amount monitor 5 of each charged beam storage ring 3 and generates and sends a control signal to the charged beam accelerating injector 1 so that the signal has a predetermined light amount. Is a control unit of. Reference numeral 11 denotes a plurality of charged-beam branching electromagnets provided in the middle of the charged-beam transport unit 2, which determines whether the charged beam is supplied to the high-charge beam transport unit 2 or the storage ring 3 thereafter. It is something to switch. As the light quantity monitor 5, a photoelectric conversion type monitor such as a photodiode is well known. In the present invention, there is no particular condition for the characteristics of the light quantity monitor, and it is sufficient that only the relative value of the light quantity can be grasped. Further, the control unit 6 may be either an analog type or a digital type, and it is sufficient if it has a general feedback type control function.

Next, the operation will be described with reference to FIG.

In FIG. 2, the horizontal axis represents time, and the vertical axis represents the charged beam current value in a charged beam storage ring 3. Point A is a beam current value (shown as I ₀ ) corresponding to a predetermined light amount value. The beam current value gradually decreases from point A with time, and the light amount also decreases in proportion thereto. The progress of this decrease is transmitted to the control unit 6 by a signal from the light quantity monitor 5, and for example, the value is a set value (indicated as I ₁ ).
At this time, the control unit 6 sends an operation command for replenishing the required storage ring 3 with the charged beam to the charged beam accelerating injector 1 and the charged beam distributing electromagnet 1, and the charged beam accelerating injector 1 The charged beam is replenished from 1. As a result, the beam current value in the charged beam storage ring 3 of interest is returned to I ₀ , and the amount of light also becomes a predetermined value. By performing this operation continuously, the amount of emitted light can be kept within a set range from a constant value. By performing this operation for each of the plurality of charged beam storage rings, the amount of emitted light from any of the charged beam storage rings can be kept within a certain setting range, and there is a problem in using the emitted light. Lost.

In the above-described embodiment, the method of replenishing the charged beam when a certain set value (I ₁ ) is reached has been described, but the difference between the signal from the radiant light intensity monitor and the predetermined radiant light intensity is set at regular intervals. In the method of replenishing the charged beam current value corresponding to
The effect is similar.

Further, in the above embodiment, the light quantity monitor is used to control the light quantity so that the light quantity becomes a predetermined light quantity, but instead of the light quantity monitor, the charged beam current value is indirectly measured as shown in FIG. It is also possible to use the current monitor 12 that operates. In this case, it is not necessary to use one radiant light beam line for monitoring as compared with the above embodiment, and there is a merit in terms of utilization ratio of radiant light. A DC current transformer system is generally used as the current monitor 12, but the system is not particularly limited, and any system may be used as long as it can accurately monitor only the beam current.

In the above embodiment, the number of charged beam storage rings is two.
Although the case of individual pieces has been described, it goes without saying that this is exactly the same for a larger number of cases.

〔The invention's effect〕

As described above, according to the present invention, a single charged-beam accelerating injector and charged-beam transporter are combined with a plurality of charged-beam storage rings, and the amount of emitted light is observed on a monitor and feedback control is performed. Since the amount of emitted light is controlled to be constant at a predetermined value, there is an effect that the property and amount of usable emitted light can be greatly improved.

[Brief description of drawings]

FIG. 1 is a plan view showing an embodiment of the present invention, FIG. 2 is a characteristic view for explaining the operation of the above embodiment, FIG. 3 is a plan view showing another embodiment of the present invention, and FIG. The drawing is a plan view showing a conventional device of this type. 1 is a charged beam accelerating injector, 2 is a charged beam transport unit, 3
Is a charged beam storage ring, 4 is a synchrotron radiation beam line, 5
Is a synchrotron radiation amount monitor, 6 is a deflection electromagnet, 7 is a vacuum donut, 8 is a charged beam equilibrium orbit, 9 is synchrotron radiation, 10 is a high-frequency cavity, 11 is a beam distribution electromagnet, 12 is a current monitor, and 13 is a control unit. Is. The same reference numerals in the drawings indicate the same or corresponding parts.

Claims (2)

[Claims] 1. A singular charged beam accelerating injector for generating and outputting a charged beam, a singular charged beam transporting unit for transporting the charged beam from the accelerating injector, and a branching means to the charged beam transporting unit. A plurality of connected charged beam storage rings, a plurality of light amount monitors for observing the light amount of the radiated light generated from each of the charged beam storage rings, and a charged beam storage ring according to the value of the light amount monitored by the light amount monitor. The charged beam accelerating injector is provided with a control unit for controlling the operations of the branching means so that the amount of emitted light is constant at a predetermined value. A charged beam apparatus characterized in that the charged beam storage ring is replenished via a section. 2. A single charged beam accelerating injector for generating and outputting a charged beam, a single charged beam transporting unit for transporting the charged beam from the accelerating injector, and a branching means for branching to the charged beam transporting unit. A plurality of connected charged beam storage rings, a plurality of current monitors for monitoring the current value stored in each of the charged beam storage rings, and a charged beam storage ring generated according to the value of the amount of light monitored by the current monitor. The charged beam accelerating injector and the control unit for controlling the operations of the branching means so that the amount of the emitted light becomes constant at a predetermined value. A charged particle beam device characterized in that the charged particle beam storage ring is replenished by way of the above.