RU2707270C1 - Charged particle spectrometer - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to spectrometry of charged particles and can be used for measurement of energy spectrum of pulse-periodic and continuous beams of charged particles. In a charged particle spectrometer comprising series-arranged electroconductive absorbing elements isolated from each other and a voltage pulse recording and processing system, wherein total thickness of absorbing elements is in accordance with extrapolated range of charged particles with maximum energy in material of absorbing elements, according to the invention, the novel feature is that each absorbing element is connected to the grounding bus through a smoothing integrating RC-filter consisting of parallel-connected resistor and capacitor, at that, the recording and processing system is connected to the non-ground terminal of the resistor.EFFECT: suppressing high-frequency harmonics in the detected signal while maintaining the possibility of determining the distribution of voltages on the absorbing elements with subsequent recovery of the energy spectrum of the charged particles in real time.1 cl, 3 dwg

Description

The invention relates to the field of charged particle spectrometry and can be used to measure the energy spectrum of pulse-periodic and continuous beams of charged particles.

A device is known for measuring the energy spectrum of pulsed beams of charged particles, containing sequentially arranged metal foils, which are connected through one to the storage capacitors, and the remaining foils located between them are grounded, and the second capacitor leads not connected to the foils are also grounded (copyright certificate SU No. 550884, “ The charged particle spectrometer ”, published on 01/05/1978).

The known device operates by braking a pulsed beam of charged particles and the accumulation of charges in the signal foils. Knowing the charge accumulated on the signal foils, one can reconstruct the energy spectrum of charged particles from known relations.

The disadvantage of this device is that using this scheme, it is possible to work only with a pulsed beam of charged particles. When a pulse-periodic pulse consisting of subnanosecond electron bunches or a continuous beam hits a plate, charges accumulate on the capacitor plates and the voltage rises until the breakdown and failure of the capacitor. This device does not allow measurements of the spectrum of a pulse-periodic or continuous beam of charged particles in real time.

It is also known a device containing sequentially arranged metal foils completely coated with a dielectric film, and storage tanks having separate connectors for charging characteristics (patent RU No. 2581728, “Foil charge spectrograph”, published on 04/20/2016).

The known device operates by braking a beam of accelerated electrons and the accumulation of charge in foils. The total thickness of the foils is selected from the condition of equality to the extrapolated range of electrons of maximum energy. The measured charge that accumulates in the foils, by reduction allows you to determine the energy spectrum of a beam of charged particles. Each foil is coated with a dielectric film. The application of a dielectric film serves to reduce the measurement error caused by the secondary emission of electrons from the foul and the presence of space charges in the air.

The disadvantage of this device is that with the help of this circuit it is impossible to work with a pulse-periodic or continuous beam of charged particles, since there is an accumulation of charges on the plates of the capacitors and the voltage increases until the breakdown and failure of the capacitor. This device also does not allow the measurement of the spectrum of charged particles in real time.

The set of features that is closest to the set of essential features of the invention is inherent in the well-known charged particle spectrometer (Arkhipov O.V., Bobyleva L.V., Brudanin V.D. et al. Communications of the Dubna Joint Institute for Nuclear Research, Energy Measurement of a High-Current Magnetized Electron Beam in LIU, 1990).

The known device contains a set of titanium foils (absorbing elements), isolated among themselves using ceramic washers. The entire foil bag is pulled together with insulated studs. All foils are loaded on identical low-inductance shunts composed of parallel-connected TVO resistors. Signals from shunts are output via cable lines and fed to a line of attenuators with matched input resistances and different division factors. The signals are attenuated and fed through the delay line with discrete manual switching to the input of the charge-to-digital converter. Further, the generated signals are transmitted to the oscilloscope and visualized on the screen. Based on the results of these measurements, the energy spectrum of the charged particle beam is restored.

The disadvantages of the known device adopted for the prototype is that there are parasitic capacitive couplings between the absorbing elements, and pulse-periodic beams of charged particles with subnanosecond pulse durations will introduce large errors in the measurements, since between adjacent absorbing elements forming high-frequency circuits, spurious oscillations occur.

The problem to which the invention is directed is to create a device that allows the measurement of the distribution of charges in the absorbing elements and the restoration of the energy spectra of periodic-periodic and continuous beams of charged particles with high accuracy.

The technical result of the present invention is the suppression of high-frequency harmonics in the recorded signal while maintaining the ability to determine the voltage distribution on the absorbing elements with the subsequent restoration of the energy spectrum of charged particles in real time.

The technical result of the invention is ensured by the fact that in a charged particle spectrometer containing electrically conductive absorbing elements arranged in series along the beam propagation, isolated from each other, and a voltage pulse recording and processing system, the total thickness of the absorbing elements being in accordance with the extrapolated range of charged particles with the maximum energy in the material of the absorbing elements, according to the invention, is new, that each absorbing element the cop is connected to the grounding bus through a smoothing integrating RC filter consisting of a resistor and a capacitor connected in parallel, while the recording and processing system is connected to the non-grounded output of the resistor.

The invention is illustrated by drawings.

In FIG. 1 schematically shows the inventive device, where:

1 - electrically conductive absorbing elements;

2 - smoothing integrating RC filter;

3 - analog-to-digital converter;

4 - controller;

5 - a personal computer with software.

In FIG. 2 shows the distribution of stresses on electrically conductive absorbing elements.

In FIG. 3 shows the restored energy spectrum of a charged particle beam.

The charged particle spectrometer includes a set of electrically conductive absorbing elements 1, each of which is connected to the ground bus through a smoothing integrating RC filter 2, consisting of a resistor and a capacitor connected in parallel. The total thickness of the electrically conductive absorbing elements slightly exceeds the extrapolated range of charged particles with maximum energy in the material of the absorbing elements. This is done in order to ensure complete absorption of all charged particles in the absorbing elements. The non-earthed terminals of the RC filter resistors are connected to the inputs of the multi-channel analog-to-digital converter 3, whose outputs are connected to the inputs of the multi-channel controller 4. The output of the controller is connected to the input of a personal computer 5.

The device operates as follows. During generation, a repetitively pulsed beam of charged particles with a subnanosecond pulse duration sequentially passes through each electrically conductive absorbing element of the assembly. In this case, charged particles lose part of their kinetic energy and are inhibited in the absorbing elements, causing current to flow through the resistors of the RC filters.

A smoothing integrating RC filter passes the constant component and cuts off the high-frequency voltage ripples arising on the absorbing elements as a result of the passage of bunches of a pulse-periodic beam of charged particles with subnanosecond pulse durations.

Due to the presence of a capacitor in each filter, an equilibrium is established between the charge accumulated on the capacitor and the charge flowing through the resistor to the ground, despite the pulse-periodic temporal structure of the beam.

The resistors used in the smoothing integrating RC filter are selected based on the expected values of currents and the required voltage on the plates. The values of the capacitors are selected so as to provide a discharge time constant that is much longer than the period of the clumps in a pulse-periodic beam of charged particles at the lowest frequency of the accelerator.

The recorded voltages on the absorbing elements are removed from the non-grounded terminals of the resistors of the RC filters and fed to the inputs of the multi-channel analog-to-digital converter 3. The digitized signals are fed to the inputs of the multi-channel controller 4, and then the combined signal from the controller output is fed to the input of a personal computer 5. On the computer, using software, the received signals are visualized and restored to the energy spectrum of charged particles. The signals from the absorbing elements are averaged by the controller over ten measurements to compensate for interference, which ensures improved measurement accuracy.

A complete survey of all n absorbing elements with averaging over ten measurements takes place in less than 0.1 seconds, which allows realizing the work of the proposed charged particle spectrometer in real time. This significantly expands the functionality for tuning and operation of charged particle accelerators and makes it possible to control the operating parameters of the accelerator, such as the energy spectrum and beam current of charged particles.

An example of a device. A charged particle spectrometer was manufactured containing, as absorbing elements, 23 isolated aluminum plates 100 × 100 mm in size and 0.15 mm thick with an air gap of 2 mm between each pair of plates. The plates are insulated with each other by means of dielectric washers and pulled together by insulated studs. A pulse-periodic beam of accelerated electrons with an average energy of 1.5 MeV, a bunch duration of 1 ns, and a follow-up period of bunches of 10 ns was fed at right angles to the plates. In FIG. 2 shows the stress distribution over aluminum plates. In FIG. Figure 3 shows the restored energy spectrum of an accelerated electron beam with an average energy of 1.5 MeV.

Claims (1)

A charged particle spectrometer containing electrically conductive absorbing elements arranged in series along the beam propagation, isolated from each other, and a voltage pulse recording and processing system, the total thickness of the absorbing elements being in accordance with the extrapolated range of charged particles with maximum energy in the material of the absorbing elements, different the fact that each absorbing element is connected to the ground bus through a smoothing integrating RC filter, consisting a resistor and a capacitor connected in parallel, while the registration and processing system is connected to an ungrounded terminal of the resistor.

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