WO2011019036A1 - パルス電圧を用いた荷電粒子ビームの取り出し方法 - Google Patents
パルス電圧を用いた荷電粒子ビームの取り出し方法 Download PDFInfo
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- WO2011019036A1 WO2011019036A1 PCT/JP2010/063566 JP2010063566W WO2011019036A1 WO 2011019036 A1 WO2011019036 A1 WO 2011019036A1 JP 2010063566 W JP2010063566 W JP 2010063566W WO 2011019036 A1 WO2011019036 A1 WO 2011019036A1
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H7/00—Details of devices of the types covered by groups H05H9/00, H05H11/00, H05H13/00
- H05H7/10—Arrangements for ejecting particles from orbits
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05H—PLASMA TECHNIQUE; PRODUCTION OF ACCELERATED ELECTRICALLY-CHARGED PARTICLES OR OF NEUTRONS; PRODUCTION OR ACCELERATION OF NEUTRAL MOLECULAR OR ATOMIC BEAMS
- H05H13/00—Magnetic resonance accelerators; Cyclotrons
- H05H13/04—Synchrotrons
Definitions
- the present invention relates to an accelerator mainly composed of a circular accelerator called a synchrotron, and more particularly to a technique for extracting an accelerated charged particle beam.
- the “horizontal direction” of the charged particle beam is a direction in which the direction in which the radius of the orbital surface of the charged particle beam in the synchrotron increases is positive.
- the charged particle beam extraction port is generally arranged outside the circular orbit so that the circular beam line and the extraction beam line do not interfere with each other. And when taking out a charged particle beam, a part of particles which go around the outermost side out of the charged particle beam which goes around are taken out.
- the magnetic field generated by the hexapole magnet defines the size of the stable region in the phase space in the horizontal direction of the charged particle beam, and the larger the magnetic field, the smaller the stable region.
- the phase space can be expressed as a plane in which each charged particle adopts the relative position with respect to the center of the design trajectory drawn by the reference particle on the horizontal axis and the momentum deviation of each charged particle on the vertical axis. Commonly used in the description of beam behavior.
- Patent Document 1 is disclosed as equivalent to the charged particle beam extraction method (3) described above.
- the invention described in Patent Document 1 increases the emittance before starting the extraction of the charged particle beam (Claim 1). Further, the emittance in the horizontal direction or the vertical direction at the start of the extraction of the charged particle beam is made substantially constant regardless of the beam energy. Further, the emittance in the horizontal direction or the vertical direction is kept substantially constant at the start of acceleration or from the middle of acceleration to the end of acceleration (claim 3).
- emittance means the “phase spatial spread” of the beam due to the momentum error of each individual charged particle with respect to the motion trajectory of the ideal charged particle.
- FIG. 8 is a schematic diagram showing the principle of a conventional charged particle beam extraction method for extracting a charged particle beam by changing the energy of the charged particle beam.
- the vertical axis indicates the movement deviation ( ⁇ p / p) in the charged particle beam on the vertical axis.
- (T) is represented on the horizontal axis.
- the motion deviation ( ⁇ p / p) in the charged particle beam is determined by the deflection magnetic field, and the momentum deviation ( ⁇ p) between the charged particle (reference particle) having the energy that goes around the design trajectory and the traveling direction of each charged particle, It is the ratio of the momentum (p) in the traveling direction of the reference particles.
- T 0 is the time (circulation cycle) required for the reference particle to make one round of the synchrotron.
- the entire charged particle beam 6 (dotted line) accelerated by the radio frequency voltage 2c (dotted line) generated from the radio frequency accelerated cavity is provided separately from the radio frequency accelerated cavity.
- a high frequency voltage 6e (solid line) from the high frequency generator and further accelerating the entire charged particle group 6a (solid line) immediately before taking out the charged particle beam (upward arrow) the stable region is moved out of the stable region 8a.
- the charged particle group 6b (colored portion) is selectively taken out to the emission line 4 by an emission deflector, for example.
- the beam intensity [A] of the extracted charged particle beam cannot be made constant for the following reason.
- the radio frequency voltage has both functions of confining the charged particle beam in the traveling direction and accelerating the charged particle beam. Also, the resonant frequency in the horizontal direction, the magnetic field strength of the bending electromagnet, and also the magnetic field strength in an attempt to make a constant state by the magnetic field strength of the focusing electromagnet, the magnetic field strength due to the effects of power supply noise 10-4 order variation range ( 8 fluctuates in a double arrow between the solid line and the dotted line in the non-stable region 8a.
- RF radio frequency voltage
- the charged particle beam extraction condition is that the charged particle energy error (momentum deviation) in the charged particle beam is greater than a certain value, that is, the charged particle beam circulates away from the design trajectory in the horizontal direction. And that the fractional part of the resonance frequency determined by the magnetic field strength reaches 1/3.
- the conventional charged particle beam extraction method (1) a method in which the energy of the charged particle beam is made constant, that is, the magnetic field strength of the hexapole magnet is changed without accelerating the charged particle beam, (2) A method of accelerating a charged particle beam with a constant magnetic field strength of a hexapole electromagnet, (3) A magnetic field strength of a hexapole electromagnet and energy of a charged particle beam are made constant, and a horizontal resonance frequency is applied in a horizontal direction. In addition, any method of vibrating has been used.
- the charged particle beam always exists just below the “resonance condition”, and the horizontal betatron frequency also fluctuates as the magnetic field fluctuates due to noise.
- the moment that meets the condition that the fractional part of the resonance frequency determined by ⁇ ⁇ ⁇ ⁇ reaches 3 and the moment that does not match the condition are determined by noise. Since noise is not a controllable factor, the method of paragraphs (1) and (2) can only obtain a beam intensity with a strong temporal variation.
- the extraction condition that is, the beam intensity of the extracted charged particle beam is controlled to be constant over time. I could't.
- FIG. 9 is a distribution of charged particles in a phase space in a conventional circular accelerator.
- the horizontal axis x is the horizontal direction, where 0 is the design trajectory, (+) direction is outside the design trajectory, and ( ⁇ ) direction is inside the design trajectory.
- a group of charged particles that make up a charged particle beam circulates while oscillating betatron, and when a stable state in which the charged particle beam continues to circulate around the synchrotron is continuously plotted, each charged particle is in this phase space.
- the charged particle beam orbiting the synchrotron expands in the X and Y directions due to repulsion due to the charge of ions in the absence of external force. For this reason, a beam converging force is generated by a quadrupole electromagnet so that it can circulate stably in the vacuum duct.
- the charged particle beam circulates in the synchrotron while performing the oscillating motion described by the same equation as the spring motion from the relationship between the repulsive force and the converging force.
- a resonance frequency in which the vibration amplitude increases with time when a specific frequency is applied to a charged particle beam.
- the transverse frequency in one round of the charged particle beam is called tune, and the resonance condition in the beam occurs when the fractional part of the tune is a fraction of 1/2, 1/3,. I know that.
- the charged particles that make up the charged particle beam are slightly different in momentum and position, and adjusting the resonance amplitude does not affect the timing relationship in the circulation direction in the charged particle beam, but it does not satisfy the resonance condition. Only the particles increase their lateral amplitude and reach the extraction trajectory.
- the resonance amplitude can be adjusted by adjusting the current of the quadrupole electromagnet or the hexapole electromagnet to generate the resonance condition.
- the region where the charged particle beam can stably circulate (stable region) and the region where the amplitude increases (unstable region) are determined by the position of the charged particle beam. Since the vibration frequency is different depending on the momentum, it is divided by a triangular region as shown in FIG. The inside of the triangle is the stable region and the outside is the unstable region.
- the fractional part of the tune circulates in a state slightly larger than 1/3 or 2/3, if the energy of the charged particle beam is increased while keeping the magnetic field applied to the charged particle beam constant, the tune decreases. Therefore, the unstable region in the figure is reduced.
- the charged particle beam moves so as to return to almost the same coordinates in the phase space when the synchrotron is rotated three times, so that the stable region has a shape close to a triangle.
- Individual charged particles constituting the charged particle beam have different ⁇ p / p.
- the betatron frequency is determined by the strength of the deflecting electromagnet and the converging electromagnet constituting the synchrotron, and the size of the stable region is determined by the hexapole magnet. That is, whether or not a certain charged particle draws a closed orbit is determined by whether or not ⁇ p / p is equal to or less than a certain value determined by a hexapole magnet.
- the limit of the stable region when ⁇ p / p and hexapole magnet strength are assumed to be a certain value is inside the triangle determined in FIG.
- the stable region becomes smaller as ⁇ p / p increases, and the size of the stable region becomes 0 for charged particles having ⁇ p / p of a certain threshold value or more. . That is, even when the magnetic field of the hexapole magnet is constant, the charged particles are always extracted when ⁇ p / p exceeds a certain value. In other words, the size of the stable region varies depending on ⁇ p / p of each charged particle.
- the inside of the triangle (large) surrounded by the boundary 8d indicated by the dotted line is the stable region 8b of the charged particle 6d (black dot) being accelerated.
- the charged particle 6c increases its momentum
- the stable region 8c becomes smaller as ⁇ p / p increases.
- the charged particle 6d having a small ⁇ p / p is not extracted because it draws a closed orbit in the stable region 8b.
- an output deflector is provided that generates an electric field only in a region beyond a certain position in the lateral direction and largely deflects the trajectory of charged particles that have jumped into the region in the lateral direction.
- the region (extraction region 8e) in which the electric field is generated is determined when the output deflector is designed.
- the charged particles 6d located in the non-stable region 8a enter the extraction region 8e and are extracted to the emission line 4.
- the charged particles 6c in the stable region 8c continue to circulate in the synchrotron and are taken out by further increasing ⁇ p / p with the high-frequency voltage 6e.
- FIG. 10 shows an accelerator using a high-frequency accelerating cavity that realizes the charged particle beam extraction method of Patent Document 1 as shown in FIG.
- the conventional accelerator 1 a includes an incident line 3, a synchrotron 2 n, an exit line 4, and a beam utilization line 5.
- the incident line 3 includes a pre-accelerator 3a that accelerates charged particles generated by an ion source to a predetermined speed, an injector 3b that makes charged particles enter the synchrotron 2n via a transport tube 3c, and the like.
- the synchrotron 2n is a circular accelerator that accelerates an incident charged particle beam 6 and emits the accelerated charged particle beam to the emission line 4 using third-order resonance.
- the synchrotron 2n includes a deflecting electromagnet 2i that keeps the charged particle beam 6 on the design orbit 2a inside the vacuum duct, a converging electromagnet 2j or diverging electromagnet 2k that is a quadrupole electromagnet having a converging or diverging force, and a charged particle with a high-frequency voltage 2c.
- the charged particle beam 6 circulates around the design orbit 2a while being oscillated with betatron.
- the emission line 4 includes an output device 4a such as an output deflector, a transport pipe 4b, and the like.
- the beam utilization line 5 is a laboratory or a medical site. In the coordinate system, the rotating direction of the charged particle beam 6 is s, the horizontal direction is x (the outside is +, the inside is-), and the vertical direction is y.
- Patent Documents 2 to 6 are disclosed as methods for accelerating a charged particle beam using an induction acceleration cell.
- Patent Document 2 provides an acceleration method that enables confinement and acceleration of all types of ions by induced voltages applied to a charged particle beam from two types of induction acceleration cells for confinement and acceleration.
- the extraction energy by the ion source is equal to or higher than the lowest energy that can be circulated by the synchrotron, the former accelerator can be dispensed with.
- Patent Documents 3 to 6 a method for controlling the generation timing of the induced voltage applied from the induction accelerating cell, a method for controlling the generation timing of the induced voltage and controlling the orbit of the charged particle beam, and the induced voltage as a charged particle beam. To provide a method for controlling the synchrotron oscillation frequency.
- Patent Document 6 discloses a method of accelerating a charged particle beam by controlling the generation timing of an induced voltage composed of the same rectangular positive induced voltage and the same rectangular negative induced voltage applied from a set of induction accelerating devices. Is to provide.
- the administration dose is an amount proportional to the time integration of the charged particle beam current.
- the irradiation field of the charged particle beam is a three-dimensional space region intended for radiation irradiation. If the required dose is inaccurate or uneven within the intended field, or if the dose is excessive, the probability of serious side effects increases. On the other hand, if the administration dose is insufficient, the probability of tumor recurrence from the irradiation site increases.
- the charged particle beam intensity can be temporally controlled in order to administer a high dose in a short time. Is extremely important.
- the charged particle beam extracted from the synchrotron is several centimeters in diameter
- the charged particle beam is separated from the wobbler electromagnet installed in the extraction beam line 5. It is deflected by a so-called rotating magnetic field, and the irradiation area is enlarged to irradiate the target.
- This method is called a wobbler irradiation method. Since the rotation frequency of the rotating magnetic field is 100 Hz or less, when adopting a charged particle beam extraction method in which the beam intensity is not temporally stable, in the treatment irradiation, the charged particle beam is changed many times while changing the starting point of the rotating magnetic field. Repeated irradiation required uniform dose in the irradiation field. Therefore, in the charged particle beam irradiation treatment, the treatment time increases due to the fact that the beam intensity is not temporally stable, which has been a very heavy burden on the patient.
- a spot scanning irradiation method in which a charged particle beam is scanned in a two-dimensional plane in the same way as electron beam scanning of a cathode ray tube television and a necessary irradiation dose is supplied to a necessary irradiation point. The method is adopted.
- the local dose change is realized by the spot scanning irradiation method
- the local dose is determined by the charged particle beam itself. For this reason, when the beam intensity is not stable in time, the average beam intensity is decreased, and the irradiation dose is adjusted by performing irradiation for a long time, which further burdens the patient.
- the present invention uses a pulsed voltage to take out a charged particle beam stably at high speed, further uniform the intensity of the extracted charged particle beam, and enable highly accurate irradiation dose control.
- An object of the present invention is to provide a method for taking out the image.
- the present invention applies a pulse voltage to a part of the accelerated charged particle beam in a circular accelerator that accelerates the charged particle beam, and generates a momentum deviation only in a part of the charged particle beam.
- a part of the charged particles having a large momentum deviation is positioned in the non-stable region and the extraction region, and the charged particle group positioned in the non-stable region and the extraction region.
- the charged particle beam extraction method is characterized in that it is selectively deflected in the horizontal direction and extracted.
- a beam monitor is provided in the extraction line of the charged particle beam, and feedback control is provided for determining the number of times of application of the pulse voltage to the charged particle beam based on a beam intensity signal from the beam monitor.
- the charged particle beam was extracted.
- the charged particle beam extraction method according to any one of the above wherein the pulse voltage is a positive or negative voltage with respect to the traveling direction of the charged particle beam.
- the charged particle beam extraction method according to any one of the above is characterized in that the voltage value or application time of the pulse voltage is adjusted to adjust the beam intensity of the extracted charged particle beam.
- the accelerator includes a charged particle injection device, a synchrotron for accelerating charged particles by a high-frequency acceleration cavity, a charged particle emission device, and a charged particle beam utilization line.
- a pulse voltage generator that applies a pulse voltage is provided on the orbital design trajectory of the charged particle beam, and a pulse voltage is applied to a part of the accelerated charged particle beam to generate a momentum deviation only in a part of the charged particle beam.
- a part of the charged particles having a large momentum deviation is positioned in the non-stable region and the extraction region, and the charged particle group positioned in the non-stable region and the extraction region is A configuration of an accelerator characterized by being extracted to the charged particle beam utilization line by an extraction device that selectively deflects largely in the horizontal direction It was.
- a feedback control is provided in which a beam monitor is provided in the charged particle beam extraction line to the charged particle utilization line, and the number of times of application of the pulse voltage to the charged particle beam is determined based on a beam intensity signal of the beam monitor.
- the pulse voltage generator has a passing signal from a bunch monitor for detecting the passage of a charged particle beam provided on the design trajectory and the design trajectory.
- the present invention exhibits the following effects by the above-described configuration.
- the extracted charged particle beam intensity can be made uniform. Therefore, when the present invention is adopted in a medical accelerator, it is possible to control the irradiation particle dose intensity and irradiation dose with extremely high accuracy and instantaneously to the irradiation site, and accurately irradiate the administration dose necessary for treatment. As a result, the intended therapeutic effect can be reliably obtained, and at the same time, the occurrence of unexpected unwanted side effects can be significantly reduced.
- FIG. 1 is a schematic diagram of an accelerator according to the present invention.
- the accelerator 1 used in the method for extracting the charged particle beam 6 according to the present invention includes a beam extraction control that controls the extraction of the incident line 3, the synchrotron 2, the emission line 4, the beam utilization line 5, and the charged particle beam 6. It consists of a mechanism 10.
- the beam extraction control mechanism 10 includes a pulse voltage generator 7 and a beam monitor 9.
- the pulse voltage generator 7 replaces the high frequency voltage applying device 2m shown in FIG.
- the pulse voltage generation device 7 may be any device that generates any pulse voltage 7 a as long as the pulse voltage 7 a enables acceleration and deceleration of the charged particle beam 6.
- the shape of the pulse voltage is not limited to a rectangle.
- An example of the pulse voltage 7a generation control method and the configuration of the pulse voltage generator 7 are shown in FIG.
- FIG. 2 illustrates an example of the configuration of the pulse voltage generator 7 that applies a pulse voltage 7 a as an induced voltage to a part of the charged particle beam 6 in synchronization with the acceleration of the charged particle beam 6.
- the pulse voltage generator 7 includes an induction accelerating cell 7d that generates a pulse voltage 7a that is an induced voltage, and a controller 7e that controls the generation of the pulse voltage 7a.
- the basic configuration is the same as that of Patent Document 6 as long as the pulse voltage 7a as an induced voltage can be applied to a part of the charged particle beam 6.
- the induction accelerating cell 7d may be the same as the induction accelerating cell that generates induction voltages for acceleration and confinement used in Patent Documents 2 to 6.
- a pulse voltage 7 a is applied to a part of the charged particle beam 6, a resonance vibration is generated in a part of the charged particle beam 6, and is extracted to the output line 4 by an output deflector or the like by tertiary resonance.
- the resonance order is not limited to the third order, and may be, for example, the second order.
- the application of the pulse voltage is controlled, that is, the charged particle beam is emitted linearly only by the pulse voltage by moving the pulse voltage to the region not affected by the magnetic field from the orbit. It is also possible to take it out to the line.
- FIG. 3 is a schematic cross-sectional view of the induction accelerating cell connected to the vacuum duct.
- the induction accelerating cell 7d has the same structure in principle as the induction accelerating cell for a linear induction accelerator that has been manufactured so far.
- the induction accelerating cell 7d has a double structure composed of an inner cylinder 7p and an outer cylinder 7q, and a magnetic body 7r is inserted into the outer cylinder 7q to create an inductance.
- a part of the inner cylinder 7p connected to the vacuum duct 2p around which the charged particle beam 6 circulates is made of an insulator 7s such as ceramic.
- a pulse voltage 7t When a pulse voltage 7t is applied from a DC charger 7i connected to a switching power supply 7h to a primary side electric circuit surrounding the magnetic body 7r, a primary current 7u flows through the primary side conductor.
- the primary current 7u generates a magnetic flux around the primary conductor, and the magnetic body 7r surrounded by the primary conductor is excited.
- the induction accelerating cell 6 is a one-to-one transformer in this example.
- the induction accelerating cell 7d receives the pulse voltage 7t from the switching power supply 7h in the primary side electric circuit, is induced in the secondary side insulating portion, and generates the induced voltage 7a applied to the charged particle beam 6.
- the control device 7e of the pulse voltage generator 7 includes a position monitor 2e, a bunch monitor 2d, a digital signal device 7n, a pattern generator 7k, a switching power supply 7h, a DC charger 7i, a transmission line 7g, an induction voltage monitor 7f, etc., and is generated in the induction acceleration cell 7d.
- This is a device for controlling the generation timing of the pulse voltage 7 a to be applied to a part of the charged particle beam 6. Details are described in Patent Document 6.
- the position monitor 2e is a monitor that is provided in the vacuum duct 2p and senses the position of the center of gravity of the charged particle beam 6. The position monitor 2e detects how much the charged particle beam 6 is displaced inward or outward in the horizontal direction from the design trajectory 2a. To do.
- the position monitor 2e is a device that outputs a voltage value proportional to the displacement of the charged particle beam 6 with respect to the design trajectory 2a.
- the position monitor 2e is constituted by two conductors having slits oblique to the traveling direction s. As the charged particle beam 6 passes, charges are induced on the conductor surface.
- a detected position signal 2g which is position information in the horizontal direction of the charged particle beam, is input to the digital signal device 7n and used for controlling the generation of the pulse voltage 7a.
- the position signal 2g is mainly used for controlling the deviation of the trajectory in the horizontal direction suitable for the taken-out state.
- the bunch monitor 2d is a monitor that is provided in the vacuum duct 2p and senses the passage of the charged particle beam 6, and generates a passing signal 2f that is a pulse at the moment when the charged particle beam passes.
- the detected passing signal 2f which is the passing information of the charged particle beam, is input to the digital signal device 7n and used for controlling the generation of the pulse voltage 7a.
- the passage signal 2f is mainly used for control to synchronize the generation of the pulse voltage 7a with the passage of the charged particle beam 6.
- the switching power supply 7h applies a pulse voltage 7t to the induction accelerating cell 7d via the transmission line 7g, and can operate at high repetition.
- the switching power supply 5b generally has a plurality of current paths, adjusts the current passing through each branch, and controls the direction of the current to generate positive and negative voltages in the load (here, the induction accelerating cell 7d).
- the DC charger 7i supplies power to the switching power supply 7h.
- the on / off operation of the switching power supply 7h is controlled by the pattern generator 7k and the digital signal processing device 7n.
- the induced voltage monitor 7 f is a monitor that measures the induced voltage value applied from the induction accelerating cell 6.
- the pulse voltage 7a is a positive pulse voltage for accelerating a part of the charged particle beam in the traveling direction s, and a negative pulse that works in the opposite direction to the traveling direction while avoiding magnetic saturation of the induction accelerating cell. Voltage, and any pulse voltage may be applied to the charged particle beam.
- the pattern generator 7k generates a gate signal pattern 7j that controls the on / off operation of the switching power supply 7h. That is, it is a device that converts the current path of the switching power supply 7h into a combination of on and off based on the gate master signal 7m.
- the digital signal processing device 7n calculates a gate parent signal 7m which is a signal based on the generation of the gate signal pattern 7j by the pattern generator 7k.
- the gate signal pattern 7j is a pattern for controlling the pulse voltage 7a applied from the induction accelerating cell 7d.
- the pulse voltage 7a When applying the pulse voltage 7a, it is a signal for determining the application time and generation timing, and a signal for determining a pause time between the positive pulse voltage and the negative pulse voltage. Therefore, the application timing and application time of the pulse voltage 7a can be adjusted according to the length of the charged particle beam accelerated by the gate signal pattern 7j.
- the beam monitor 9 is a monitor that is provided in the transport path of the extracted charged particle beam 6 and measures and monitors the current intensity of the charged particle beam 6 at the moment when the charged particle beam 6 passes through the beam monitor 9.
- the beam monitor 9 has a principle equivalent to a general current transformer in which the charged particle beam 6 is represented by a primary side coil and the detector side is represented by a secondary side coil. Is passed through the magnetic body and the voltage or current induced in the secondary coil is measured to measure the instantaneous current value of the charged particle beam without destroying the charged particle beam.
- the charged particle beam intensity [A] obtained by the beam monitor 9 is converted into numerical information by an analog / digital converter.
- This digital numerical information is sent to the pulse voltage generator 7 as a beam intensity signal 9a, and is used for extraction control of the charged particle beam 6 after the next beam circulation in the synchrotron 2 (referred to as "feedback control 9b"). .
- the beam intensity signal 9 a is input to the digital signal device 7 n of the pulse voltage generator 7.
- Information on the charged particle beam current intensity to be taken out at a certain moment is stored in the digital signal device 7n and compared with the beam intensity signal 9b.
- the information on the charged particle beam intensity current to be extracted is not limited to a method given in advance as data, and may be given by real-time calculation using a function or the like as an example.
- the pulse voltage 7a is controlled so as to decrease the extracted beam intensity.
- a negative pulse voltage is applied to a region where a positive pulse is applied in the traveling direction of the charged particle beam, or the time width of the positive pulse voltage is reduced.
- the stable region of the charged particles increases as ⁇ p / p decreases, the extraction intensity of the charged particle beam can be reduced or stopped.
- the pulse voltage is controlled to increase the extracted beam intensity because the beam intensity is insufficient. Specifically, for a local area where a positive pulse is applied in the traveling direction of the charged particle beam, the pulse voltage application rate for each round is increased or the time width of the pulse voltage is increased for extraction. Increase the contributing beam current.
- FIG. 4 is a schematic diagram of an example of a pulse voltage generator. It is a principle schematic diagram of the extraction method of the charged particle beam of the present invention, and represents the momentum deviation ( ⁇ p / p) in the traveling direction of the charged particle beam 6 as a distribution with respect to the time (t) based on the circulation time of the reference particle. did. The meaning of the symbols is the same as in FIG.
- a pulse voltage (positive pulse voltage 7b) indicated by an alternate long and short dash line is applied to a part of the charged particle beam 6 accelerated by a high frequency voltage 2c indicated by a wavy line (chain line) from the high frequency acceleration cavity 2b.
- a pulse voltage positive pulse voltage 7b
- a high frequency voltage 2c indicated by a wavy line (chain line) from the high frequency acceleration cavity 2b.
- the negative pulse voltage 7c can be applied to the charged particle beam 6 and used to decelerate the charged particle beam 6 as needed, as well as canceling the magnetic saturation.
- the pulse voltage 7a is applied to increase the momentum deviation ( ⁇ p / p) of only a part of the charged particle beam 6 (charged particle group 6a)
- the charged particle beam 6 that does not receive the pulse voltage 7a is not stable. There is a distance from the region, and unnecessary charged particle beam 6 extraction due to noise does not occur. Accordingly, the beam intensity of the extracted charged particle beam 6 can be intentionally adjusted using the pulse voltage 7a.
- FIG. 5 shows the distribution of charged particles in the phase space when a pulse voltage is applied to the charged particle beam.
- the meaning of the symbols is the same as in FIG.
- a portion obtained by removing the stable region 8 c from the stable region 8 b becomes a charged particle outside stable region 8 a in which a part of the charged particle beam 6 receives the pulse voltage 7 a. Therefore, only the black dot charged particles 6d positioned in the out-of-stable region 8a are positioned in the extraction region 8e and extracted to the emission line 4.
- the charged particle group that is not subjected to the application of the pulse voltage 7a is located sufficiently inside the stable region (resonance condition), so that it is extremely free from the influence of noise. It can be extracted with a constant beam intensity.
- the intensity of the extracted beam can be adjusted by changing the voltage value and the pulse length of the induced voltage 7a.
- feedback control 9b that changes the number of occurrences, loss, voltage value, and pulse length of the pulse voltage based on the detection value of the beam monitor 9, highly accurate beam intensity control can be performed.
- FIG. 6 is a comparison of simulation results of the charged particle beam extraction method of the present invention (B) when the charged particle beam is not extracted (A).
- the synchrotron used in the particle beam therapy system that is actually designed and manufactured is used as a model, and the synchrotron circumference, deflection magnetic field strength, convergence magnetic field strength, hexapole magnetic field strength, and extraction position of the output deflector are actually realized.
- the parameters were set and used for normal operation.
- the left figure shows the phase space distribution of the charged particles in the traveling direction s
- the right figure shows the phase space distribution of the charged particles in the horizontal direction x.
- a positive pulse voltage 7b was applied to 20% of charged particles.
- the distribution is a plot in which all the phase space positions of charged particles at 1000 rounds are overlaid.
- the charged particles move in a closed orbit within the stable region so that they rotate counterclockwise in the triangular stable region. .
- the physical parameters are the same except that the pulse voltage is applied locally. That is, it can be seen that only the pulse voltage contributes to the extraction of the charged particle beam. It can also be seen that the charged particle beam is kept in a stable region, and unintentional extraction due to noise or the like is not performed.
- the pulse voltage 7a to some charged particles of the charged particle beam having different momentum deviation ⁇ p / p, the particles in the horizontal direction (x) draw different trajectories for each ⁇ p / p, and the pulse voltage It can be seen that only charged particles to which 7a is applied are taken out.
- FIG. 7 is a comparison result (simulation) of the present invention (broken line) and the conventional (solid line) charged particle beam intensity by the charged particle beam extraction method).
- the simulation is based on an extraction method (conventional extraction method) assuming Patent Document 1 and an extraction method in which the pulse voltage 7a of the present invention is applied to the charged particle beam 6 after 1000 charged particles have been rotated 1000 times. This is an assumed measurement value in the beam monitor 9.
- the vertical axis represents the beam intensity [A]
- the horizontal axis represents time (seconds)
- 1.5 seconds represents the time for taking out the charged particle beam in the synchrotron.
- the beam intensity of the extracted charged particle beam inevitably increases with time.
- the horizontal outer edge of the charged particle beam is always in contact with the resonance line (boundary line), and the fluctuation of the beam intensity due to noise triggers the charged particle beam.
- An eject / stop phenomenon occurs.
- the rate of decrease of the stable region in the lateral direction of the charged particle beam is not constant over time.
- uncontrollable extraction of the charged particle beam due to noise occurs, so that the beam intensity of the extracted charged particle beam cannot be made constant.
- the charged particle beam can be extracted at the corresponding portion in 1000 rounds and 0.3 msec.
- Application of the pulse voltage to a part of the charged particle beam can be achieved at a time sufficiently faster than 1 msec. Therefore, the charged particle beam can be extracted with high speed and high accuracy at a constant beam intensity even at 1 msec or less. It can be controlled.
- a charged voltage group to be extracted is applied to a part of the charged particle beam (a charged particle group to be extracted) that applies a pulse voltage to which an acceleration voltage (in some cases, a deceleration voltage) is applied.
- an acceleration voltage in some cases, a deceleration voltage
- the charged particle beam caused by noise is reduced by reducing the momentum deviation ( ⁇ p / p) in the traveling direction of the entire charged particle beam and keeping the stable region from receiving the charged particle beam extracted by noise.
- ⁇ p / p the momentum deviation
- the method of changing the charged particle distribution in the traveling direction can be easily performed by changing the amplitude and shape of the voltage confining the charged particle beam in the traveling direction, and there are many examples.
- the charged particle beam extraction method of the present invention uses a pulse voltage to extract a charged particle beam stably at high speed, further uniform the intensity of the extracted charged particle beam, and enables high-precision irradiation dose control. Therefore, it can be expected to be used especially in the medical field, shortening of the irradiation time and high-precision irradiation treatment are possible, and the burden on the treatment to the patient can be reduced.
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Abstract
Description
(2)6極電磁石の磁場強度を一定にして荷電粒子ビームを加速させる方法、(3)6極電磁石の磁場強度及び荷電粒子ビームのエネルギーを一定にして、水平方向の共鳴周波数で水平方向にさらに振動させる方法の何れかが用いられてきた。
1a 加速器
2 シンクロトロン
2a 設計軌道
2b 高周波加速空洞
2c 高周波電圧
2d バンチモニタ
2e 位置モニタ
2f 通過シグナル
2g 位置シグナル
2h 高周波電圧
2i 偏向電磁石
2j 収束電磁石
2k 発散電磁石
2m 高周波電圧印加装置
2n シンクロトロン
2p 真空ダクト
3 入射ライン
3a 前段加速
3b 入射器
3c 輸送管
4 出射ライン
4a 出射器
4b 輸送管
5 ビーム利用ライン
6 荷電粒子ビーム
6a 荷電粒子群
6b 荷電粒子群
6c 荷電粒子
6d 荷電粒子
6e 高周波電圧
7 パルス電圧発生装置
7a パルス電圧
7b 正のパルス電圧
7c 不のパルス電圧
7d 誘導加速セル
7e 制御装置
7f 誘導電圧モニタ
7g 電送線
7h スイッチング電源
7i DC充電器
7j ゲート信号パターン
7k パターン生成器
7m ゲート親信号
7n デジタル信号処理装置
7p 内筒
7q 外筒
7r 磁性体
7s 絶縁体
7t パルス電圧
7u 1次電流
7v 端部
7w 電場
7x 加速ギャップ
8 6極電磁石
8a 安定外領域
8b 安定領域
8c 安定領域
8d 境界
8e 取り出し領域
8f 境界
9 ビームモニタ
9a ビーム強度シグナル
9b フィードバック制御
10 ビーム取出制御機構
Claims (7)
- 荷電粒子ビームを加速する円形加速器において、加速された荷電粒子ビームの一部にパルス電圧を印加し、荷電粒子ビームの一部のみに運動量偏差を発生させ、荷電粒子ビームの進行方向に対する水平方向の位相空間内において、運動量偏差が大きい一部の荷電粒子を安定外領域かつ取り出し領域に位置させ、前記安定外領域かつ取り出し領域に位置した荷電粒子群を選択的に水平方向に大きく偏向させて取り出すことを特徴とする荷電粒子ビームの取り出し方法。
- 前記荷電粒子ビームの取り出しラインにビームモニタを設け、前記ビームモニタからのビーム強度シグナルを基に、前記荷電粒子ビームに対する前記パルス電圧の印加回数を決定するフィードバック制御を備えることを特徴とする請求項1に記載の荷電粒子ビームの取り出し方法。
- 前記パルス電圧が、荷電粒子ビームの進行方向に対して正又は負の電圧であることを特徴とする請求項1又は請求項2に記載の荷電粒子ビームの取り出し方法。
- 前記パルス電圧の電圧値又は印可時間を調節し、取り出される荷電粒子ビームのビーム強度を調節することを特徴とする請求項1~請求項3の何れか1項に記載の荷電粒子ビームの取り出し方法。
- 荷電粒子の入射装置と、高周波加速空洞により荷電粒子を加速するシンクロトロンと、荷電粒子の出射装置と、荷電粒子ビーム利用ラインとからなる加速器であって、
さらに荷電粒子ビームの一部にパルス電圧を印加するパルス電圧発生装置を荷電粒子ビームの周回設計軌道上に備え、加速された荷電粒子ビームの一部にパルス電圧を印加し、荷電粒子ビームの一部のみに運動量偏差を発生させ、荷電粒子ビームの進行方向に対する水平方向の位相空間内において、運動量偏差が大きい一部の荷電粒子を安定外領域かつ取り出し領域に位置させ、前記安定外領域かつ取り出し領域に位置した荷電粒子群を選択的に水平方向に大きく偏向させる出射装置により、前記荷電粒子ビーム利用ラインに取り出すことを特徴とする加速器。 - 前記荷電粒子利用ラインへの荷電粒子ビームの取り出しライン中に、ビームモニタを設け、前記ビームモニタのビーム強度シグナルを基に、前記荷電粒子ビームに対する前記パルス電圧の印加回数を決定するフィードバック制御手段を備えることを特徴とする請求項5に記載の加速器。
- 前記パルス電圧発生装置が、前記設計軌道上に備えられた荷電粒子ビームの通過を感知するバンチモニタからの通過シグナル及び前記設計軌道上に備えられた荷電粒子ビームの重心位置を感知する位置モニタからの位置シグナルを基に、誘導加速セルから荷電粒子ビームの一部にパルス電圧を印可することを特徴とする請求項5又は請求項6に記載の加速器。
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EP10808219.9A EP2466997B1 (en) | 2009-08-11 | 2010-08-10 | Method for extracting a charged particle beam using pulse voltage |
US13/390,002 US8525449B2 (en) | 2009-08-11 | 2010-08-10 | Charged particle beam extraction method using pulse voltage |
JP2011526768A JP5682967B2 (ja) | 2009-08-11 | 2010-08-10 | パルス電圧を用いた荷電粒子ビームの取り出し方法および加速器 |
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JP2015179585A (ja) * | 2014-03-19 | 2015-10-08 | 住友重機械工業株式会社 | 荷電粒子線治療装置 |
WO2022130680A1 (ja) * | 2020-12-14 | 2022-06-23 | 株式会社日立製作所 | 加速器および粒子線治療装置 |
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US9119281B2 (en) * | 2012-12-03 | 2015-08-25 | Varian Medical Systems, Inc. | Charged particle accelerator systems including beam dose and energy compensation and methods therefor |
JP7002952B2 (ja) * | 2018-01-29 | 2022-01-20 | 株式会社日立製作所 | 円形加速器、円形加速器を備えた粒子線治療システム、及び円形加速器の運転方法 |
FR3123139B1 (fr) * | 2021-05-18 | 2023-04-28 | Synchrotron Soleil | Electro-aimant multipolaire |
CN113952637B (zh) * | 2021-09-29 | 2022-09-06 | 清华大学 | 一种实现束团分离的方法和装置 |
CN114205987B (zh) * | 2021-12-13 | 2022-10-14 | 清华大学 | 同步加速器粒子分离后的引出方法及装置 |
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JPWO2011019036A1 (ja) | 2013-01-17 |
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