Aspects and embodiments of the invention most generally pertain to a charged particle accelerator apparatus, accelerator components, fabrication methods, and applications; more particularly to a wafer-based charged particle accelerator, radio-frequency (RF) charged particle accelerator wafers, RF charged particle accelerator wafer assemblies, and electrostatic quadrupole (ESQ) focusing wafers, manufacturing methods, and applications; most particularly to a multi-beam, wafer-based charged particle accelerator, RF and ESQ wafers and assemblies, and manufacturing methods, and applications. The described accelerator structure can revolutionize the cost, size, weight, and power consumption of charged particle accelerators. By having each component of the accelerator structure fabricated on a wafer like substrate, we aim to leverage batch fabrication capabilities of silicon and other substrates to reduce the need for traditional machining of metals. The same wafers, armed with integrated electronics for closed loop control of the accelerating and guiding electric fields will eliminate or greatly reduce electronics equipment away from the prime accelerator, thus reducing size weight and power of the overall accelerator. By using micromachining approaches to make small gaps, moderate voltages can be used to achieve substantial focusing effects on charged particles. The existence of miniature UHV (ultra-high vacuum) pumps that can also be light-weight attached to the system further enables the possibility of light weight and small MeV (106 electron volt) class accelerators. We envision accelerators that are vehicle- and even man-portable to provide charged particle beams for many applications for x-ray generation, neutron beam generation, and medical therapies, that are not possible due to the size, weight, and power of existing accelerators, which rely heavily on metal based machined structures.
Our approach is informed from the MEQALAC (Multiple-electrostatic-quadrupole array linear accelerator) approach that breaks one charged beam into several charged beams, in the context of scaling the amount of current an accelerator can accelerate. The MEQALAC development can be attributed to Alfred W. Maschke and colleagues at Brookhaven National Laboratory. Reference is made to U.S. Pat. No. 4,350,927 (Means For The Focusing And Acceleration Of Parallel Beams Of Charged Particles), Gammel et al., MEQALAC DEVELOPMENT AT BROOKHAVEN, Particle Accelerator Conference, Mar. 11-13, 1981 Shoreham Hotel, Washington, D.C., and Adams et al., DESCRIPTION OF THE M1 MEQALAC AND OPERATING RESULTS, Brookhaven National Laboratory, the subject matters of all of which are incorporated by reference in their entireties.
Many types of particle accelerators, including the original MEQALAC and others, require resonant cavities and high voltage sources, and have other characteristics some or all of which make them unwieldy in terms of size, cost, complexity, scalability, and other problematic attributes. In view of this, the inventors have recognized the need for, and advantages and benefits to be obtained from, improved performance, manufacturing processes, and operating architectures for more efficient, compact, and better performing MEQALAC-type charged particle accelerators, which are provided by the embodied invention disclosed herein.
Exemplary, non-limiting aspects and embodiments of the invention include MEMS- and microfabrication-, and laser micro-fabrication-based MEQALAC building blocks, methods for making RF and pulsed high voltage accelerator stage wafers and electro-static quadrupole (ESQ) ion and electron beam focusing stage wafers, internalized high-voltage sources, and applications. Process descriptions are provided for printed-circuit board (PCB)-based RF and pulsed high voltage accelerator and ESQ focusing wafers, silicon-based wafers, glass-based wafers, and 3D printed wafers. Internalized, triggered, high-voltage-providing circuitry is described.
An aspect of the embodied invention is an RF charged particle accelerator wafer sub-assembly. In a non-limiting, exemplary embodiment the RF charged particle accelerator wafer sub-assembly includes a wafer having electrical isolation between at least a first and a second electrically conductive electrode, wherein at least the first and the second electrode are disposed on respective and opposing first and second sides of the wafer, and create an electric field,
further wherein the wafer has one or more orifices through which a charged particle beam can travel, encountering the electric field generated by the at least first and second electrode, further wherein the second electrode is in the form of an RF resonator configured as either a) a thin film inductor in series with an air gap capacitor, or b) a coplanar waveguide resonator, so as to transform a low voltage on the first side of the substrate to a high voltage on the second side of the substrate; and RF voltage-generating electronics disposed on the substrate; and
a power supply coupled to the at least one RF charged particle accelerator wafer sub-assembly. In a non-limiting, exemplary embodiment the RF charged particle accelerator wafer sub-assembly includes two RF charged particle accelerator wafer sub-assemblies, wherein the two RF charged particle accelerator wafers are linearly separated by a drift space having a drift distance, βλ/2 where λ is the wavelength of electromagnetic waves in space at the accelerator frequency (λ=c/v, v is the accelerator RF frequency), and β is the ratio of the speed of the charged particles to that of speed of light. The frequency v is the period of an oscillating voltage used to generate an accelerating electric field, further wherein the second side of a first one of the RF charged particle accelerator wafer is immediately adjacent an input end of the drift distance and the second side of the second one of the RF charged particle accelerator wafer is immediately adjacent an output end of the drift distance.
An aspect of the embodied invention is an ESQ (ElectroStatic Quadrupole) charged particle beam focusing wafer. In a non-limiting, exemplary embodiment the ESQ charged particle beam focusing wafer comprises an electrically insulative wafer or planar substrate having at least one through-hole, each through-hole providing a beam path to focus the charged particle beam, each through-hole having at least four electrodes disposed at the inner perimeter of the through-hole, where each electrode further comprises one of a) exposed areas of the wafer covered by a conductive material in selected areas to form an electric field distribution to focus the charged particle beam, or b) conductive pillar-like structures coupled to insulating connectors, connected to the wafer. The conductive pillar-like structures may each one of a solid rod or a hollow cylinder.
An aspect of the embodied invention is a method for making an ESQ charged particle beam-focusing wafer. In a non-limiting, exemplary embodiment the method includes four electrical isolated electrodes arranged around a hole through the wafer for charged particles to pass through the wafer. For a focusing effect the sidewalls of these electrodes are biased at +V, −V, +V, −V; that is, alternating voltages. Normally the surfaces of the electrodes are shaped so that a linear electrical field near the center of the hole is achieved. A single ESQ wafer will provide focusing only in one direction orthogonal to the beam propagation and will defocus the beam in the other direction. Using two (or more) ESQs, a focusing effect in both directions can be achieved as previously identified in past accelerator work. On board electronics, integrated directly on the accelerator and ESQ wafers, or onto separate sensor wafers can be used to sense the charged particle beams. This feedback can be used to provide feedback to modify control voltages to provide active focusing and accelerations of the charged particle beams.
An aspect of the embodied invention is a wafer-based charged particle accelerator. In a non-limiting, exemplary embodiment the accelerator includes a charged particle source; at least one RF charged particle accelerator wafer sub-assembly comprising a wafer having electrical isolation between at least a first and a second electrically conductive electrode, wherein at least the first and the second electrode are disposed on respective and opposing first and second sides of the wafer, and create an electric field, further wherein the wafer has one or more orifices through which a charged particle beam can travel, encountering the electric field generated by the at least first and second electrode, further wherein the second electrode is in the form of an RF resonator configured as either a) a thin film inductor in series with an air gap capacitor, or b) a coplanar waveguide resonator, so as to transform a low voltage on the first side of the substrate to a high voltage on the second side of the substrate; and RF voltage-generating electronics disposed on the substrate; and a power supply coupled to the at least one RF charged particle accelerator wafer sub-assembly. The wafer-based charged particle accelerator may further comprise a beam current-sensor disposed in either a) a single RF wafer, or b) a separate wafer disposed in the drift space. The wafer-based charged particle accelerator may further comprise at least a second RF charged particle accelerator wafer sub-assembly; and at least one ESQ charged particle focusing wafer. The at least one ESQ charged particle focusing wafer may comprise an electrically insulative wafer or planar substrate having at least one through-hole, each through-hole providing a beam path to focus the charged particle beam, each through-hole having at least four electrodes disposed at the inner perimeter of the through-hole, where each electrode further comprises one of a) exposed areas of the wafer covered by a conductive material in selected areas to form an electric field distribution to focus the charged particle beam, and b) conductive pillar-like structures coupled to insulating connectors, connected to the wafer, linearly aligned with the RF charged particle accelerator wafer sub-assemblies. The conductive pillar-like structures may each be one of a solid rod or a hollow cylinder.
Both Electrostatic Quadrupole (ESQ) wafers and RF wafers for a wafer-based charged particle accelerator include an insulating wafer substrate with one or more of insulated holes, holes with sidewall metal coatings, holes with partial sidewall metal coatings, metal-filled vias, as well as top and bottom patterning for routing of electrical signals and contact to sidewall metals or vias. Insulated substrates may include printed circuit boards (PCBs; e.g., FR4), glass with Through-Glass-Vias (TGVs), and silicon, as well as 3D printed structures.
Different versions of ESQ and RF wafers with different performance vs ease of fabrication tradeoffs may require implementation of one or more of the following structures on an insulating substrate, some of which are illustrated in
In addition, the substrate should allow high-breakdown fields so that large voltages (>1 kV) can be applied across adjacent metal, via, and sidewall-metal structures to help with electrostatic focusing, guiding, or acceleration of charged particles. The metal thickness is chosen to minimize resistive losses at RF frequencies associated with direct resistance and skin effects. Aspect ratios, gaps, and thickness of the substrate will depend on the particular device and the choice of fabrication, each introducing potential cost and performance tradeoffs. We describe five (i-v) different fabrication approaches for the embodied RF and ESQ wafers.
(i) Fabrication of ESQ and RF Wafers Using PCB Machining and Contour Routing with a Drill Bit
Two-sided printed circuit boards (PCB's) can be machined by a combination of drilling, contour routing, electroless plating, electroplating, lamination, photolithography, and etching, well known to those skilled in the art. In the embodied method, due to the inherent nature of electroless plating, all the sidewalls of vias are covered with metal, since regular PCBs used in electronics only require vias with all sidewalls metal-coated. However, ESQ wafers require removal of metal sidewalls in certain parts of the via. This may be realized by traversing a drill bit over a contour that overlaps with the boundary of the sidewalls over which metal needs to be removed. This process is summarized in
(ii) Fabrication of ESQ and RF Wafers Using PCB Machining with Laser
Compared to what is available from a standard two layer PCB fabrication process, there are additional requirements for ESQ and RF wafers. As RF wafers do not require sidewall metal coating, their fabrication process is simpler compared to the process for ESQ wafers. Since any process to fabricate an ESQ wafer can also be used to fabricate an RF wafer, we illustrate the fabrication steps for an ESQ wafer, which in general may require: (1) non-circular vias; and (2) partially metal-coated sidewalls. Both of these aspects can be accommodated using a laser cutter (e.g., LPKF ProtoLaser U, which removes copper or FR4 material by abrasion. Using laser micromachining, top and bottom metal layers can be patterned and holes can be made through the board. Alignment between top and bottom is achieved by using an integrated vision system and pre-fabricated alignment fiducials. Furthermore, by using the integrated camera of the tool, top and bottom layers can be registered for alignment. Main steps of an exemplary process to fabricate an ESQ wafer are illustrated in
(iii) Fabrication of ESQ and RF Wafers using glass micromachining and Through-Glass Vias
Instead of FR4, glass may be used as the insulating substrate with Through-Glass-Vias (TGV). This allows fabrication on a low cost substrate with smaller features than what might be possible with PCB fabrication. Furthermore, high vacuum compatibility of glass and high breakdown voltages are advantageous. The basic steps of the process flow are illustrated in
ESQ wafers and RF wafers can also be fabricated by 3D printing. An advantage of 3D printing is the ability to form structures with small 3D features such as protrusions and holes in a low cost dielectric polymer substrate. In one implementation, the ESQ electrode diameter is 1 to 2 mm and the minimum feature size achievable in 3D printing is 50 to 100 μm. For ESQ structures, one implementation is to form two of the required four electrodes that constitute an ESQ in the polymer substrate on two separate wafers. The top surface of the polymer wafers is then coated with a few micron thick layer of, e.g., copper, which also coats the sides of the cylindrical ESQ electrodes. Two copper coated wafers with two ESQ electrodes of the same polarity per beamlet are then stacked together to form the finished ESQ wafer with the selected number of ESQs.
RF (or wafers that provide high voltage pulses) for ion acceleration consist of holes for beams to transvers and rings of metal electrodes on a dielectric substrate. The arrays for holes can also be formed by 3D printing. Metal electrodes can be formed by (local) metal coating of rings around the electrodes.
Based on the beam dynamics simulations with WARP3D and beam envelope codes, we have designed and are developing RF (radio-frequency)-acceleration wafers and ESQ (electrostatic quadrupole) wafers. We have tested ESQ and RF wafers and have achieved ion acceleration in a 3×3 beamlet array with a stack of RF wafers, accelerating argon ions (12 μA total current per beamlet) from 10 keV to about 11.7 keV. High voltages for incremental acceleration of charged particles can be provided by RF or by high voltage pulses (e.g., from power transistors).
Our modeling run included six RF stages (i.e., 12 acceleration gaps) and ESQ doublets between each of the RF stages. We started with a matched injection condition that we had calculated with beam envelope codes (vs. particle-in-cell simulations with WARP, which are more computationally demanding). We calculated and optimized the phase offset and RF-gaps (RF-gap=βλ/2; where β is the ratio of ion velocity divided by the speed of light and λ is the RF wavelength). We also increased the ESQ value by 2% between each gap. The simulations are for xenon ions (Xe1+), injected with 40 keV from an ion source, where a realistic beam emittance from our multi-cusp type plasma ion source is assumed. The current per beamlet is 20 N A, with a 40 μm beam radius in an aperture (or beamlet channel) with a radius of 90 μm. The simulations (
We tracked ion loss and found transmission of 85% of ions. Most losses occur right after injection and losses in later cells are below 1% per cell. Based on past experience with injecting and matching symmetric beams to an alternating gradient focusing lattice, we expect to significantly reduce the initial particle loss by tuning the strength of the first 4-6 electrostatic quadrupoles. Although the simulations were performed with xenon, first beam experiments are being conducted with argon, which is much lower in cost compared to xenon.
In earlier simulations of single gaps, illustrated in
The simulations also show that under these specific conditions we implemented an energy tilt on the ions in the bunch and this could be optimized for drift compression if desired.
Continuous wave (RF) operation of the MEQALAC requires a large, external high voltage source. The accelerator can also be operated in pulsed mode. This approach requires feedback and relies on detection of the incoming beams and switching of accelerating voltages with electronically adjusted delays. This approach is illustrated in
Operation of Accelerator Structures from the PCB Process
We assembled a stack of four RF wafers and mounted them in a vacuum chamber together with an ion source for first beam tests. We tested the multi-cusp plasma ion source and extracted about 26 μA of argon beam (Ar1+) per beamlet from a 3×3 array of beamlets. In these first PCB beamlet structures, the beamlet diameter is of order 1 mm.
Using the setup shown in
The plasma ion source has a three grid extraction system. A floating grid, followed by a grid that is biased at −2 kV with respect to the source body. The following electrode is held at +1 kV when no ions are extracted and the potential is lowered to approx. −3 kV during extraction (also with respect to the source body). For the following runs, we biased the source at 10 kV. The RF wafer stack consists of four wafers. The first and last are grounded and the second and third are connected to the RF. We went with this layout, since a) the vacuum gap between wafer 1 and 2 and between 3 and 4 can hold higher voltages vs. the voltage across an RF wafer and b) RF losses in the FR4 are no concern in this configuration. The RF-stack is followed by a mesh that we can bias to high voltage. We use this as an energy filter, e.g., if the voltage RF sub-assemblies is higher than the beam potential, no ions will pass the mesh. This way we can test if our beam has been accelerated by the RF. The mesh will also have a focusing or de-focusing effect.
We extract the beam from the source at 10 kV and send the beam through the RF wafer stack (two RF acceleration gaps). The beam then passes through an energy filter (positive biased mesh) and is captured by a Faraday-cup. We measure the beam energy by scanning the mesh voltage and see when the current drops to zero. We repeat this with the RF amplitude set to different levels and test different frequencies. We clearly see that the beam gets accelerated by up to 1 kV; e.g., the drop-off moves from 10.5 kV to 11.5 kV (
We see that for the RF data, the beam charge vs. mesh voltage drops off at higher voltages, showing that the beam gained energy in the RF structure. We can also see that the energy spread of the beam increased during RF acceleration, which is to be expected, since we entered the RF structure with a 4 μs long beam pulse, which corresponds to about 80 RF oscillations at ˜20 MHz. The energy gain can still be optimized, since in our current setup the frequency is not optimized for the fixed RF-gap between RF-wafers 2 and 3. Therefore, the second RF-acceleration gap might have had the wrong phase. Also, the ion source and extraction was not yet fully optimized for these runs, so ion currents can be further increased.
We have achieved first ESQ operation with focusing of 5 keV He+ beamlets (˜10 μA/beamlet). We used He+ to increase light output from the scintillator. We operated at ±100 V ESQ bias.
For the first ESQ beam tests we chose to operate with helium ions at 5 keV. The lighter helium ions produce a proportionally higher light out-put in the plastic scintillator. The multi-cusp ion source can produce well in excess of 80 mA/cm2 He+ ions when driven to high discharge power. For heavier ions the current density decreases and we expect to be able to extract ˜10 mA/cm2 of xenon ions from this type of ion source. This translates into 100 μA to 800 μA for Xe+ and He+ ions, respectively, that we can inject into 1 mm2 beamlets. We will determine limits on transportable current in our ESQ lattice and compare measurements with calculated limits (e. g. following the analysis by A. Maschke). For the current ESQ tests, we injected at a modest current density of 10 μA per beamlet, which is adequate for testing of ESQ focusing and RF acceleration.
We image the beam induced pattern of emitted light from the scintillator with a gated camera. In the first experiments we also observed background light from the ion source filament.
We have tested the HV holding capability of ESQ wafers based on PCB. In
The instant application claims priority to U.S. provisional application Ser. 62/331,614 filed May 4, 2016, the subject matter of which is incorporated by reference herein in its entirety.
This invention was made with government support under Contract No. DE-AC02-05CH11231 awarded by the U.S. Department of Energy. The government has certain rights in this invention.
Number | Date | Country | |
---|---|---|---|
62331614 | May 2016 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16098537 | Nov 2018 | US |
Child | 16538563 | US |