Your search keyword '"Particle beams"' showing total 3,819 results

1. High-precision realization for sensing charged particles based on optomechanically induced two-color second-order sidebands.

Author

Wang, Junfeng, Xue, Yafeng, Liu, Shaopeng, Li, Ying, and Liu, Bo

Subjects

NONLINEAR oscillators, PARTICLE beams, ABSORPTION spectra, SENSES

Abstract

We propose an effective scheme to sense charged particles by employing two-color second-order sidebands (TSSs) in a hybrid optomechanical system. This is realized in an optomechanical cavity with a double-oscillator structure, where the Coulomb force acting on two charged oscillators participates in nonlinear optomechanical interaction. With the aid of mechanical mode splitting induced by the Coulomb force, we report that the TSS spectrum can be generated and enhanced when the strong absorption in the transmission spectrum allows the TSS generated pathways to be readily accessed. More importantly, after seeking two correlations between the TSS spectra and the charged particles deposited on the oscillator, we design a dual-parameter sensor to measure the mass and the charge of the external particles simultaneously. Through evaluating the influence of the thermomechanical noise on the optomechanical sensing device, the resolution for detecting the mass and the charge of the measured particles can be identified as δ m ≈ 1.7 × 10 − 18 g and δ Q ≈ 1.6 × 10 − 18 C , respectively. [ABSTRACT FROM AUTHOR]

Published

2023

2. Extraction of polarization observables in two pion photoproduction reactions.

Author

Filippi, Alessandra

Subjects

POLARIZATION (Economics), PIONS, BARYONS, POLARIZED beams (Nuclear physics), PARTICLE beams

Abstract

The relevance of the study of polarization observables to gather insight on the features of baryonic resonances, and the procedure applied for the extraction of this information from the data, are illustrated. The reference reaction is the photoproduction of two charged pions with both a polarized beam and target, experimental conditions that were met in the g14 (2012) run of the CLAS experiment at Jefferson Lab. The method for the determination of the I⊙ observable is discussed and illustrated utilizing previously published data. [ABSTRACT FROM AUTHOR]

Published

2024

3. Particle Swarm Optimization of Interface Constitutive Model Parameters for Embedded Beam Formulations.

Author

Granitzer, Andreas-Nizar, Leo, Johannes, and Tschuchnigg, Franz

Subjects

BUILDING foundations, PARTICLE swarm optimization, BOUNDARY value problems, PARTICLE beams, SOIL structure

Abstract

The numerical simulation of boundary value problems involving a high number of pile-type structures, such as pile foundation systems of high-rise buildings, represents a standard task in computational geotechnics. Due to their ability to simplify the underlying pile modeling process and decrease the simulation runtime embedded beam formulations (EBFs) have attracted widespread interest from the geotechnical community. State-of-the art EBFs are typically equipped with nonlinear interface constitutive models to capture the soil–structure interaction behavior with reasonable accuracy. However, reliable information concerning the calibration of related parameters is limited, which decreases the confidence in the results obtained with EBFs. The present work addresses this research aspect for the first time, along with a theoretical discussion of inherent simplifications in the numerical description of the soil–structure contact associated with EBFs. The significance of selecting adequate embedded interface constitutive model parameters to ensure EBF predictions with high credibility is demonstrated by means of parametric studies. This has motivated the development of an automatic calibration software, leveraged by particle swarm optimization, that provides guidance in selecting suitable values. The effectiveness of the calibration software is confirmed by back-calculation of different pile problems with default and calibrated parameter sets. Likewise, the results provide insight into crucial factors driving the calibration framework, with a view to increasing its potential for take-up in engineering practice. Potential lines of research in the context of the automatic calibration software are explored throughout this work and may serve as valuable reference in future research. Practical Applications: The design of geotechnical problems involving a high number of pile-type structures, such as pile foundation systems of high-rise buildings or wind turbines, is routinely assisted by finite-element analyses. The computational expense of these simulations is significantly influenced by the pile modeling technique. Due to their exceptional ability to simplify the underlying modeling process and reduce the runtime to an acceptable limit, embedded beam formulations have therefore attracted widespread interest for geotechnical design tasks. As with all soil–structure interaction problems, it is essential in embedded beam formulations to accurately describe the interface behavior between the soil and the structure. This work presents the first attempt to highlight the relevance of this concern and visually describes relevant limitations resulting from an inadequate selection of interface constitutive model parameters. This observation has motivated the development of an automatic calibration software to increase the confidence in the parameter selection. The high potential of this software to increase the credibility of numerical predictions obtained with embedded beam formulations is demonstrated based on pile problems with different soil stratification layers, pile geometries, and pile arrangements. In all cases considered, the results confirm that the numerical fidelity could be significantly increased by employing calibrated parameter sets. [ABSTRACT FROM AUTHOR]

Published

2024

4. Design and performance of the Cluster Ion Counter (CIC).

Author

Mirme, Sander, Balbaaki, Rima, Manninen, Hanna Elina, Koemets, Paap, Sommer, Eva, Rörup, Birte, Wu, Yusheng, Almeida, Joao, Ehrhart, Sebastian, Weber, Stefan Karl, Pfeifer, Joschka, Kangasluoma, Juha, Kulmala, Markku, and Kirkby, Jasper

Subjects

GALACTIC cosmic rays, COMPLEX ions, COUNTER-ions, AIR flow, PARTICLE beams, ATMOSPHERIC nucleation

Abstract

A dilute plasma is continuously maintained in the troposphere by ionising particle radiation from galactic cosmic rays and radon decay. Small ions in the 1–2 nm size range play an important role in atmospheric processes such as ion-induced nucleation of aerosol particles. Consequently there is a need for precise and robust instruments to measure small ions both for atmospheric observations and for laboratory experiments that simulate the atmosphere. Here we describe the design and performance of the Cluster Ion Counter (CIC, Airel OÜ), which simultaneously measures the number concentrations of positively- and negatively-charged ions and particles below 5 nm mobility diameter, with low noise and fast time response. The detection efficiency is above 80 % for ions and charged particles between 1.2 and 2.0 nm, and above 90 % between 2.0 and 3.0 nm. The ion concentrations measured by the CIC agree well with reference instruments. The noise level (1 σ of background measurements) is typically between 20 and 30 ions cm-3 at 1 Hz sampling rate and an air flow rate of 7 l min-1 per analyzer. The noise level improves when higher flow rates and longer sampling periods are used. The CIC responds rapidly with 1 s time resolution to pulses of ionisation produced in the CLOUD chamber by a CERN particle beam. [ABSTRACT FROM AUTHOR]

Published

2024

5. Study of the Gyro and Divergence Characteristics of Relativistic Charged Particle Beam Propagation in Earth's Magnetic Field.

Author

Fang, Meihua, Liang, Zheng, Gong, Yingkui, Chen, Jianfei, Zhu, Guiping, Liu, Ting, Tian, Yu, Zhou, Yu, and Luciano, Gaetano

Subjects

GEOMAGNETISM, PARTICLE tracks (Nuclear physics), RELATIVISTIC particles, ELECTRON beams, ELECTRON diffusion, PARTICLE beams

Abstract

Relativistic charged particle beam can be used as a destructive beam weapon in space for debris removal tasks. The trajectories of charged particles are affected by both electric and magnetic forces in the Earth's magnetic field. In this paper, we firstly analyzed the correlation parameters of the charged particle beam as a weapon when it is propagated in the geomagnetic field. Then, the models were constructed based on COMSOL Multiphysics, and the IGRF model was adopted in the simulation. The gyroradius and the related uncertainty were analyzed by simulation of the charged particle transport in the geomagnetic field at different altitudes. The charged beam spot radius divergency was also simulated. The geomagnetic field can inhibite the diffusion of the electron beam. [ABSTRACT FROM AUTHOR]

Published

2024

6. STRAS: a new high time resolution aerosol sampler for PIXE analysis.

Author

Nava, Silvia, Vecchi, Roberta, Prati, Paolo, Bernardoni, Vera, Cadeo, Laura, Calzolai, Giulia, Carraresi, Luca, Cialdai, Carlo, Chiari, Massimo, Crova, Federica, Forello, Alice, Fratticioli, Cosimo, Giardi, Fabio, Manetti, Marco, Massabò, Dario, Mazzei, Federico, Repetto, Luca, Valli, Gianluigi, Vernocchi, Virginia, and Lucarelli, Franco

Subjects

PARTICLE induced X-ray emission, PARTICLE beams, ION beams, ION analysis, SCIENTIFIC community

Abstract

The joint use of hourly resolution sampling and analyses with accelerated ion beams such as Particle Induced X-ray Emission (PIXE) technique has allowed the measurement of hourly temporal patterns of particulate matter (PM) composition at many sites in different parts of the world. The demand within the scientific community for this type of analysis has been continuously increasing in recent years, but hourly resolution samplers suitable for PIXE analysis are now discontinued and/or suffer from some technical limitations. In this framework, a new hourly sampler, STRAS (Size and Time Resolved Aerosol Sampler), was developed for the collection of PM10, PM2.5 or PM1. It allows automatic sequential sampling of up to 168 hourly samples (1 week), it is mechanically robust, compact, and easily transportable. To increase PIXE sensitivity, each sample is concentrated on a small surface area on a polycarbonate membrane. The comparison between the elemental concentrations retrieved by STRAS samples and samples collected using a standard sequential sampler operated in parallel shows a very good agreement; indeed, if both the samplers use the same kind of membrane, the concentrations of all detected elements are in agreement within 10 %. [ABSTRACT FROM AUTHOR]

Published

2024

7. Analysis of the Problems of the Research and Modernization of Emission Units of Analytical Devices of Vacuum Electronics.

Author

Ibrayev, Alpamys T. and Sagyndyk, Aigerim B.

Subjects

PARTICLE beams, PROBLEM solving, CATHODES, ELECTRONS

Abstract

In various electron-optical and ion-beam devices and vacuum electronics installations, emission elements and units are used to extract and form beams of charged particles. Their focusing properties significantly affect the quality parameters and technical characteristics of the analytical devices and technological installations in which they are used. Due to the specificity of the initial conditions during the formation of the beams of charged particles in the area of charged particle extraction, the methods of studying single and conventional immersion electron lenses are not suitable for the high quality theoretical and numerical studies of the properties of immersion objectives. In this paper, theoretical and numerical studies were conducted on the problems in analyzing the focusing parameters of charged particles in emission elements and units when solving problems of designing and upgrading devices and installations of vacuum electronics. As a result of the studies, a theoretical method for studying cathode lenses with a curved optical axis was developed and options for solving problems in correcting aberrations of emission elements and units were proposed. [ABSTRACT FROM AUTHOR]

Published

2024

8. Analysis of the process e+e-→μ+μ- in the presence of a linearly polarized electromagnetic field.

Author

Ouali, M., Ouhammou, M., Jakha, M., Taj, S., and Manaut, B.

Subjects

LINEAR polarization, PARTICLE beams, ELECTROMAGNETIC fields, LASERS

Abstract

In the centre of mass frame, we have investigated the electroweak process e + e - → μ + μ - in the presence of a plane and monochromatic laser wave of linear polarization. We provide the theoretical calculations of the differential cross-section for this process by using the scattering-matrix approach and Dirac-Volkov formalism. The laser-assisted cross-section is computed, and its dependence on the laser parameters is analyzed. We have found that this cross-section increases significantly inside a linearly polarized laser wave co-propagating with the incident particle's beam, and it passes its corresponding laser-free cross-section by several orders of magnitude. [ABSTRACT FROM AUTHOR]

Published

2024

9. Bonner sphere measurements of high-energy neutron spectra from a 1 GeV/u 56Fe ion beam on an aluminum target and comparison to spectra obtained by Monte Carlo simulations.

Author

Di Chicco, Augusto, Horst, Felix, Boscolo, Daria, Schuy, Christoph, Weber, Uli, Zboril, Miroslav, Eke, Canel, and Rafiei, Mustafa Mohammad

Subjects

NEUTRON measurement, COSMIC rays, NUCLEAR energy, NEUTRON counters, NEUTRON temperature, RADIATION protection, ION beams, PARTICLE beams, NUCLEAR reactions

Abstract

The goal of this work is to characterize the secondary neutron spectra produced by 1 GeV/u56Fe beam colliding with a thick cylindric aluminum target and to perform a quantitative comparison with simulated results obtained with Monte Carlo codes. The measurements were performed using extended-range Bonner sphere spectrometers at two positions (15° and 40°) with respect to the beam direction. The secondary radiation field was simulated using four Monte Carlo codes (FLUKA, MCNP6, Geant4 and PHITS) and several physical models of nuclei transport and interaction. Neutron and proton energy distributions were simulated for the experimental measurement positions. The simulated neutron spectra, together with data measured with Bonner sphere spectrometers, after carrying out the correction of the contributions induced by the secondary protons, were used as input for the MAXED spectrum unfolding code to obtain the measured neutron spectra. Unfolded neutron spectra were compared with simulated ones to carry out a quantitative analysis of the performance of the chosen Monte Carlo codes and their corresponding physical models. This comparison showed that, because of experimental uncertainties and physical models, there are no unique solutions for each measurement location, but a range of solutions where the true experimental neutron spectra probably lie. The results showed deviations between 4.23% and 8.42% for some simulated spectra. Regarding the total integral values of neutron fluence and ambient equivalent dose, the unfolded neutron spectra showed deviations lower than 2%. [ABSTRACT FROM AUTHOR]

Published

2024

10. Quark/Gluon Plasma: When Protons Melt.

Author

Lincoln, Don

Subjects

STRONG interactions (Nuclear physics), PARTICLES (Nuclear physics), HEAVY nuclei, CIRCULAR motion, COLLISIONS (Nuclear physics), HEAVY ion collisions, JETS (Nuclear physics), PARTICLE beams, PROTON beams

Abstract

This article provides an overview of the concept of quark/gluon plasma (QGP), a state of matter that existed in the early universe and can be recreated in high-energy particle collisions. It explains that QGP can be observed through experimental signatures such as enhanced strange quark production and suppressed jet production. The article also discusses the history of QGP research, from its announcement in 2000 to ongoing measurements at accelerators like RHIC and LHC. It concludes by acknowledging that there is still much to be learned about QGP and its properties. [Extracted from the article]

Published

2024

11. Analytical and Numerical Solution of Kinetic Interaction Problems for Groups of Fast Particles.

Author

Aristov, V. V. and Voronich, I. V.

Subjects

MONTE Carlo method, ANALYTICAL solutions, PARTICLE beams, COLLISIONS (Nuclear physics), LONGITUDINAL waves

Abstract

We present a brief survey of problem formulations related to high-speed beams with emphasis on analytical solutions. Additionally, numerical solutions for some problems of this class are described. Within the framework of kinetic theory, the analytical method is used to consider the interaction of groups of particles (molecules) assuming that the particles' velocities are highly correlated (delta function is used as a distribution density). The problems of beam interaction with and without loss of particles are studied numerically using direct statistical Monte Carlo simulation. For the problem with loss of particles (intersection and interaction of thin beams), good agreement with the analytical solution is obtained. For the problem without loss of particles (collision of flows), we obtain a numerical solution of the type of a traveling shock wave of limiting compression that is formed when the flow collides with a wall. The role of collision transforms at the initial stage of the process is shown. The problem of beam penetration into a stationary gas up to the stage of plume formation is considered, and a similarity of its initial stage with the problem of thin beams is noted. It is emphasized that analytical methods are fruitful as applied to primary analysis of problems and to the verification of numerical solutions. [ABSTRACT FROM AUTHOR]

Published

2024

12. Development of a Miniaturized 2-Joule Pulsed Plasma Source Based on Plasma Focus Technology: Applications in Extreme Condition Materials and Nanosatellite Orientation.

Author

Soto, Leopoldo, Pavez, Cristian, Pedreros, José, Jain, Jalaj, Moreno, José, San Martín, Patricio, Castillo, Fermín, Zanelli, Daniel, and Altamirano, Luis

Subjects

PLASMA physics, PLASMA focus, FUSION reactors, PLASMA sources, DENSE plasmas

Abstract

Plasma focus devices represent a class of hot and dense plasma sources that serve a dual role in fundamental plasma research and practical applications. These devices allow the observation of various phenomena, including the z-pinch effect, nuclear fusion reactions, plasma filaments, bursts, shocks, jets, X-rays, neutron pulses, ions, and electron beams. In recent years, considerable efforts have been directed toward miniaturizing plasma focus devices, driven by the pursuit of both basic studies and technological advancements. In this paper, we present the design and construction of a compact, portable pulsed plasma source based on plasma focus technology, operating at the ~2–4 Joule energy range for versatile applications (PF-2J: 120 nF capacitance, 6–9 kV charging voltage, 40 nH inductance, 2.16–4.86 J stored energy, and 10–15 kA maximum current at short circuit). The components of the device, including capacitors, spark gaps, discharge chambers, and power supplies, are transportable within hand luggage. The electrical characteristics of the discharge were thoroughly characterized using voltage and current derivative monitoring techniques. A peak current of 15 kiloamperes was achieved within 110 nanoseconds in a short-circuit configuration at a 9 kV charging voltage. Plasma dynamics were captured through optical refractive diagnostics employing a pulsed Nd-YAG laser with a 170-picosecond pulse duration. Clear evidence of the z-pinch effect was observed during discharges in a deuterium atmosphere at 4 millibars and 6 kilovolts. The measured pinch length and radius were approximately 0.8 mm and less than 100 μm, respectively. Additionally, we explore the potential applications of this compact pulsed plasma source. These include its use as a plasma shock irradiation device for analyzing materials intended for the first wall of nuclear fusion reactors, its capability in material film deposition, and its utility as an educational tool in experimental plasma physics. We also show its potential as a pulsed plasma thruster for nanosatellites, showcasing the advantages of miniaturized plasma focus technology. [ABSTRACT FROM AUTHOR]

Published

2024

13. Relations between Shot Noise, Gain Bandwidth, and Saturation of Instabilities.

Author

Jing, Yichao, Litvinenko, Vladimir N., Ma, Jun, and Wang, Gang

Subjects

FREE electron lasers, LIGHT sources, BANDWIDTHS, LASERS, NOISE, PARTICLE beams

Abstract

There are numerous instabilities present in charged particle beams that undergo exponential growth and reach saturation. In various applications, such as free-electron lasers or micro-bunching light sources, achieving saturation is desirable. Conversely, there are applications where these instabilities are utilized as linear broad-band amplifiers for signals embedded in the charged beam. In the latter scenario, the saturation of an instability induces non-linear distortions in the imprinted signal, thereby limiting the useful range of such amplifiers. Accurate evaluation of these instabilities necessitates a complete and comprehensive modeling approach that includes shot noise within the beam. Unfortunately, such modeling is not always feasible or practical. In this paper, we introduce a methodology utilizing the frequency and bandwidth of the instability as key parameters. Through this, we derive an estimation for the range of linear instability growth. Our derivation is conducted in a model-independent manner, making it applicable to a broad spectrum of instabilities. To validate our approach, we employ established and thoroughly benchmarked simulations with a free electron laser (FEL) code as well as self-consistent 3-dimensional simulation of plasma-cascade instability using code SPACE. [ABSTRACT FROM AUTHOR]

Published

2024

14. Investigation of dosimetric characteristics of radiochromic film in response to alpha particles emitted from Americium‐241.

Author

Diaz‐Martinez, Victor D., Cyr, Mélodie, Devic, Slobodan, Tomic, Nada, Lewis, David F., and Enger, Shirin A.

Subjects

LINEAR energy transfer, ABSORBED dose, WATER use, CANCER treatment, RADIOISOTOPES, PHOTON beams, CHROMIUM isotopes, PARTICLE beams

Abstract

Background: In radiotherapy, it is essential to deliver prescribed doses to tumors while minimizing damage to surrounding healthy tissue. Accurate measurements of absorbed dose are required for this purpose. Gafchromic® external beam therapy (EBT) radiochromic films have been widely used in radiotherapy. While the dosimetric characteristics of the EBT3 model film have been extensively studied for photon and charged particle beams (protons, electrons, and carbon ions), little research has been done on α$\alpha$‐particle dosimetry. α$\alpha$‐emitting radionuclides have gained popularity in cancer treatment due to their high linear energy transfer, short range in tissue, and ability to spare surrounding organs at risk, thereby delivering a more localized dose distribution to the tumor. Therefore, a dose‐calibration film protocol for α$\alpha$‐particles is required. Purpose: This study aimed to develop a dose‐calibration protocol for the α$\alpha$‐particle emitting radionuclide 241Am, using Monte Carlo (MC) simulations and measurements with unlaminated EBT3 films. Methods: In this study, a MC‐based user code was developed using the Geant4 simulation toolkit to model and simulate an 241Am source and an unlaminated EBT3 film. Two simulations were performed: one with voxelized geometries of the EBT3 active volume composition and the other using water. The dose rate was calculated within a region of interest in the voxelized geometries. Unlaminated EBT3 film pieces were irradiated with the 241Am source at various exposure times inside a black box. Film irradiations were compared to a 6‐MV photon beam from a Varian TrueBeam machine. The simulated dose rate was used to convert the exposure times into absorbed doses to water, describing a radiochromic‐film‐based reference dosimetry protocol for α$\alpha$‐particles. The irradiated films were scanned and through an in‐house Python script, the normalized pixel values from the green‐color channel of scanned film images were analyzed. Results: The 241Am energy spectra obtained from the simulations were in good agreement with IAEA and NIST databases, having differences <$<$0.516% for the emitted γ$\gamma$‐rays and produced characteristic x‐rays and <$<$0.006% for the α$\alpha$‐particles. Due to the short range of α$\alpha$‐particles, there was no energy deposition in the voxels outside the active 241Am source region projected onto the film surface. Thus, the total dose rate within the voxels covering the source was 0.847 ±$\pm$ 0.003 Gy/min within the sensitive layer of the film (LiPCDA) and 0.847 ±$\pm$ 0.004 Gy/min in water, indicating that the active volume can be considered water equivalent for the 241Am beam quality. A novel approach was employed in α$\alpha$‐film dosimetry using an exponential fit for the green channel, which showed promising results by reducing the uncertainty in dose estimation within 5%. Although the statistical analysis did not reveal significant differences between the 6‐MV photon beam and the α$\alpha$ calibration curves, the dose–response curves exhibited the expected behavior. Conclusions: The developed MC user code simulated the experimental setup for α$\alpha$‐dosimetry using radiochromic film with acceptable uncertainty. Unlaminated EBT3 film is suitable for the dosimetry of α$\alpha$‐radiation at low doses and can be used in conjunction with other unlaminated GafChromic® films for quality assurance and research purposes. [ABSTRACT FROM AUTHOR]

Published

2024

15. Conceptual Design of the Moderator Test Station at the Spallation Neutron Source.

Author

Iverson, E.B., Johns, K.C., Gallmeier, F.X., and Grammer, K.B.

Subjects

NEUTRONS, MODERATORS (Fission reactors), PROTON beams, PARTICLE beams, PROTOTYPES

Abstract

We describe the Moderator Test Station (MTS), under construction at the Spallation Neutron Source. We will leverage the Beam Test Facility (BTF) at the Spallation Neutron Source to provide a moderator neutronics test stand with which we will verify the anticipated performance gains expected and required from the innovative moderator concepts central to the SNS Second Target Station (STS) and the future of the First Target Station (FTS). These concepts include large-volume para-hydrogen moderators and high-brightness tube moderators. The MTS will add to the existing BTF a proton beam chopper similar to that already used in the SNS at the RFQ exit (the so-called MEBT chopper), various proton beam transport components, a neutron-producing target, a cryogenic moderator test stand, a reflector-shielding assembly, and a performance assessment neutron beamline. The MTS will provide the ability to test a wide variety of moderators in a prototypic configuration, simultaneously measuring the neutronic performance of the moderator concept central to the anticipated STS gains and developing the instrumentation necessary to provide that performance in a production environment. The presentation will describe the MTS, its progress, and the way we optimize the prototypic nature of the moderators we will test. [ABSTRACT FROM AUTHOR]

Published

2024

16. HOW AI IS REVEALING LOST SECRETS OF THE ANCIENT WORLD.

Author

MONTGOMERY, DAVID

Subjects

MACHINE learning, COMPUTER science, ROMAN history, PARTICLE beams, COMPUTED tomography

Abstract

Scholars are using AI technology to read ancient papyrus scrolls that were previously too fragile to open. The breakthrough has the potential to rewrite history by revealing lost secrets of the ancient world. One competition, called the Vesuvius Challenge, offered a cash prize for participants who could develop programs to interpret 3D scans of the scrolls and detect writing on the charred material. A team of competitors successfully used AI to reveal 15 columns of text from a scroll buried by the eruption of Mount Vesuvius in 79 AD, exceeding the challenge's original goal. The progress made so far has excited scholars and could lead to the discovery of lost masterworks of Greek and Roman history, philosophy, and literature. [Extracted from the article]

Published

2024

17. Conditional guided generative diffusion for particle accelerator beam diagnostics.

Author

Scheinker, Alexander

Subjects

PARTICLE beams, SYNCHROTRON radiation, PARTICLE accelerators, RELATIVISTIC electron beams, FREE electron lasers, ELECTRON beams, LIGHT sources

Abstract

Advanced accelerator-based light sources such as free electron lasers (FEL) accelerate highly relativistic electron beams to generate incredibly short (10s of femtoseconds) coherent flashes of light for dynamic imaging, whose brightness exceeds that of traditional synchrotron-based light sources by orders of magnitude. FEL operation requires precise control of the shape and energy of the extremely short electron bunches whose characteristics directly translate into the properties of the produced light. Control of short intense beams is difficult due to beam characteristics drifting with time and complex collective effects such as space charge and coherent synchrotron radiation. Detailed diagnostics of beam properties are therefore essential for precise beam control. Such measurements typically rely on a destructive approach based on a combination of a transverse deflecting resonant cavity followed by a dipole magnet in order to measure a beam's 2D time vs energy longitudinal phase-space distribution. In this paper, we develop a non-invasive virtual diagnostic of an electron beam's longitudinal phase space at megapixel resolution (1024 × 1024) based on a generative conditional diffusion model. We demonstrate the model's generative ability on experimental data from the European X-ray FEL. [ABSTRACT FROM AUTHOR]

Published

2024

18. Neutral beam microscopy with a reciprocal space approach using magnetic beam spin encoding.

Author

Lowe, Morgan, Alkoby, Yosef, Chadwick, Helen, and Alexandrowicz, Gil

Subjects

ATOMIC beams, PARTICLE beams, MAGNETIC moments, SPATIAL resolution, NUMERICAL calculations

Abstract

The emerging technique of neutral beam microscopy offers a non-perturbative way of imaging surfaces of various materials which cannot be studied using conventional microscopes. Current neutral beam microscopes use either diffractive focusing or pin-hole scanning to achieve spatial resolution, and are characterised by a strong dependence of the imaging time on the required resolution. In this work we introduce an alternative method for achieving spatial resolution with neutral atom beams which is based on manipulating the magnetic moments of the beam particles in a gradient field, and is characterised by a much weaker dependence of the imaging time on the image resolution. The validity of the imaging approach is demonstrated experimentally by reconstructing one dimensional profiles of the beam which are in good agreement with numerical simulation calculations. Numerical simulations are used to demonstrate the dependence of the signal to noise on the scan resolution and the topography of the sample, and assess the broadening effect due to the spread of velocities of the beam particles. The route towards implementing magnetic encoding in high resolution microscopes is discussed. An alternative approach for achieving resolution in neutral beam microscopes is presented. The reciprocal space approach involves magnetically manipulating the spin of the beam atoms to encode their position and offers favourable scaling of the measurement time with the image resolution. [ABSTRACT FROM AUTHOR]

Published

2024

19. A conditional latent autoregressive recurrent model for generation and forecasting of beam dynamics in particle accelerators.

Author

Rautela, Mahindra, Williams, Alan, and Scheinker, Alexander

Subjects

CHARGED particle accelerators, PARTICLE accelerators, PARTICLE dynamics, AUTOREGRESSIVE models, PHASE space, PARTICLE beams

Abstract

Particle accelerators are complex systems that focus, guide, and accelerate intense charged particle beams to high energy. Beam diagnostics present a challenging problem due to limited non-destructive measurements, computationally demanding simulations, and inherent uncertainties in the system. We propose a two-step unsupervised deep learning framework named as Conditional Latent Autoregressive Recurrent Model (CLARM) for learning the spatiotemporal dynamics of charged particles in accelerators. CLARM consists of a Conditional Variational Autoencoder transforming six-dimensional phase space into a lower-dimensional latent distribution and a Long Short-Term Memory network capturing temporal dynamics in an autoregressive manner. The CLARM can generate projections at various accelerator modules by sampling and decoding the latent space representation. The model also forecasts future states (downstream locations) of charged particles from past states (upstream locations). The results demonstrate that the generative and forecasting ability of the proposed approach is promising when tested against a variety of evaluation metrics. [ABSTRACT FROM AUTHOR]

Published

2024

20. Extension of evaluated cross section database for charged particle monitor reactions.

Author

Tárkányi, F., Hermanne, A., Ignatyuk, A. V., Ditrói, F., Takács, S., and Capote-Noy, R.

Subjects

YIELD curve (Finance), DATABASES, COPPER, PARTICLE beams, FORECASTING, INTEGRALS

Abstract

The evaluation and deduction of recommended cross section values allowing extension of the database to monitor energy and intensity parameters of charged particle beams is presented. Included are 53 charged particle (p, d, 3He, 4He) induced reactions on suited C, Al, Ti, Fe, Ni, Cu, Nb and Au targets. The new data allow more systematic simultaneous use of multiple reactions on the same target and promote the backings of electrodeposited and sedimented targets as monitoring aids. Where possible the energy range is extended to above 100 MeV. Integral yield curves over the studied energy range are derived and compared to experimentally measured yields at specific energy points. A comparison with the theoretical excitation curve prediction of the TALYS-code as available in the TENDL 2021–2023 libraries is shown. [ABSTRACT FROM AUTHOR]

Published

2024

21. Plasma-induced damage on the tungsten surface using a kilojoule plasma focus device: Applicable to study the damages on nuclear fusion reactor related materials.

Author

Jain, Jalaj, Carrasco, Marcos Flores, Moreno, Jose, Davis, Sergio, Pavez, Cristian, Bora, Biswajit, and Soto, Leopoldo

Subjects

FUSION reactors, PLASMA focus, NUCLEAR reactor materials, PLASMA devices, SURFACE cracks, PARTICLE beams

Abstract

Damages induced on the tungsten surface at two different operating conditions of a kilojoule plasma focus device are studied. In one condition, the tungsten samples were exposed to axial plasma shocks that are formed after pinch disruption, and in the other condition, the pinch phenomenon was absent or weak. Melting, craters, and cracking on the surfaces were observed in both cases. In the former case, the charged particle beams and post-pinch material ejection will play a role in impacting the surface; however, in the latter case those phenomena will have small contributions because of the absence or weak formation of the pinch. A damage factor of ∼ 10 9 W m−2 s0.5 was estimated at a distance of 3 cm from the pinch exit using the method given in Akel et al. [J. Fusion Energy 35, 694–701 (2016)] and Klimov et al. [J. Nucl. Mater. 390, 721–726 (2009)] for the former case. The present work suggests that at pressures lower than the pinch-occurring pressure, only axial plasma shock effects on the targeted surface can be studied and that they can be separated from the effects produced by the charged particle beams mixed with axial plasma shocks in the case of pinch occurrence. [ABSTRACT FROM AUTHOR]

Published

2024

22. Tunable Photonic Hook Design Based on Anisotropic Cutting Liquid Crystal Microcylinder.

Author

Li, Renxian, Tang, Huan, Zhang, Mingyu, Liu, Fengbei, Yang, Ruiping, Khaleel, Naila, Arfan, Muhammad, Asif, Muhammad, Minin, Igor V., and Minin, Oleg V.

Subjects

BESSEL beams, PLANE wavefronts, DEGREES of freedom, LIQUID crystals, PARTICLE beams

Abstract

The selective control and manipulation of nanoparticles require developing and researching new methods for designing optical tweeters, mainly based on a photonic hooks (PHs) effect. This paper first proposes a tunable PH in which a structured beam illuminates an anisotropic cutting liquid crystal microcylinder based on the Finite-DifferenceTime-Domain (FDTD) method. The PHs generated by plane wave, Gaussian, and Bessel beam are analyzed and compared. The impact of beams and LC particle parameters on the PHs are discussed. Where the influence of the extraordinary refractive index ( n e ) on PHs is emphasized. Our results reveal that introducing birefringence can change the bending direction of PH. Besides, the maximum intensity of the PHs increases as n e increases regardless of the beam type. The PH generated by a plane wave has a higher maximum intensity and smaller FWHM than that generated by the Gaussian and Bessel beams. The smallest FWHM and maximum intensity of the PHs generated by the Gaussian falls between that generated by the plane wave and the Bessel beam. The PH generated by a Bessel beam has the minor maximum intensity and the largest FWHM. Still, it exceeds the diffraction limit and exhibits bending twice due to its self-recovery property. This paper provides a new way to modulate PH. This work offers novel theoretical models and the degree of freedom for the design of PHs, which is beneficial for the selective manipulation of nanoparticles. It has promising applications in Mesotronics and biomedicine. [ABSTRACT FROM AUTHOR]

Published

2024

23. Scattering of a Bessel Pincer Light-Sheet Beam on a Charged Particle at Arbitrary Size.

Author

Zhang, Shu, Chen, Shiguo, Wei, Qun, Li, Renxian, Wei, Bing, and Song, Ningning

Subjects

HIGH resolution imaging, PARTICLE beams, ELECTROMAGNETIC wave scattering, ABSORPTION coefficients, REFRACTIVE index

Abstract

Electromagnetic scattering is a routine tool for rapid, non-contact characterization of particle media. In previous work, the interaction targets of scattering intensity, scattering efficiency, and extinction efficiency of Bessel pincer light-sheet beams were all aimed at dielectric spheres. However, most particles in nature are charged. Considering the boundary condition on a charged sphere, the beam shape coefficients (BSCs) ( p m n , q m n ) of the charged spherical particle illuminated by a Bessel pincer light-sheet beam are obtained. The extinction, scattering, and absorption efficiencies are derived under the generalized Lorenz–Mie theory (GLMT) framework. This study reveals the significant differences in scattering characteristics of Bessel pincer light-sheet beams on a charged particle compared to traditional beams. The simulations show a few apparent differences in the far-field scattering intensity and efficiencies between charged and natural spheres under the influence of dimensionless size parameters. As dimensionless parameters increase, the difference between the charged and neutral spheres decreases. The effects of refractive index and beam parameters on scattering, extinction, and absorption coefficients are different but tend to converge with increasing dimensionless parameters. When applied to charged spheres with different refractive indices, the scattering, extinction, and absorption efficiencies of Bessel pincer light-sheet beams change with variations in surface charge. However, once the surface charge reaches saturation, these efficiencies become stable. This study is significant for understanding optical manipulation and super-resolution imaging in single-molecule microbiology. [ABSTRACT FROM AUTHOR]

Published

2024

24. Bistream instability.

Author

Flitti, Aicha

Subjects

PLASMA physics, THERMAL electrons, POSITRONS, PARTICLE beams, ELECTRON beams, ION beams, ELECTRON density

Abstract

Copyright of Przegląd Elektrotechniczny is the property of Przeglad Elektrotechniczny and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

25. Self-consistent effects in the ponderomotive acceleration of electron beams.

Author

Almansa, I., Russman, F., Peter, E., Marini, S., and Rizzato, F.B.

Subjects

BEAM dynamics, ACCELERATION (Mechanics), PHASE velocity, ELECTRON beams, PLASMA dynamics, SPACE charge, PARTICLE beams

Abstract

In the present work, we extend the results of a previous investigation on the dynamics of electrons under the action of an inverse free-electron-laser scheme (Almansa et al. , Phys. Plasmas , vol. 26, 2019, 033105). While the former work examined electrons as single test particles subject to the combined action of a modulated wiggler plus a laser field, we now look at electrons as composing a particle beam, where collective space-charge effects are relevant and included in the analysis. Our previous work showed that effective acceleration is achieved when the initial velocities of the particles are close enough to the phase velocity of the beat-wave mode formed by the laser and the wiggler fields. Electrons are then initially accelerated by a ponderomotive uphill effect generated by the beat mode and, once reaching the phase velocity of the beat, undergo a final strong resonant acceleration step resembling a catapult effect. The present work shows that, under proper conditions, space-charge effects play a similar role as the initial (or injected) velocity of the beam. Even if acceleration is absent when space charge is neglected, it may be present and effective when charge effects are taken into account. We also discuss how far the space charge can grow without affecting the sustainability of the acceleration process. [ABSTRACT FROM AUTHOR]

Published

2024

26. Correlations between X-rays, visible light and drive-beam energy loss observed in plasma wakefield acceleration experiments at FACET-II.

Author

Zhang, Chaojie, Storey, Doug, Claveria, Pablo San Miguel, Nie, Zan, Marsh, Ken A., Mori, Warren B., Adli, Erik, An, Weiming, Ariniello, Robert, Cao, Gevy J., Clark, Christine, Corde, Sebastien, Dalichaouch, Thamine, Doss, Christopher E., Emma, Claudio, Ekerfelt, Henrik, Gerstmayr, Elias, Gessner, Spencer, Hansel, Claire, and Knetsch, Alexander

Subjects

PLASMA diagnostics, PLASMA waves, VISIBLE spectra, PLASMA acceleration, PARTICLE beams, PARTICLE beam bunching

Abstract

This study documents several correlations observed during the first run of the plasma wakefield acceleration experiment E300 conducted at FACET-II, using a single drive electron bunch. The established correlations include those between the measured maximum energy loss of the drive electron beam and the integrated betatron X-ray signal, the calculated total beam energy deposited in the plasma and the integrated X-ray signal, among three visible light emission measuring cameras and between the visible plasma light and X-ray signal. The integrated X-ray signal correlates almost linearly with both the maximum energy loss of the drive beam and the energy deposited into the plasma, demonstrating its usability as a measure of energy transfer from the drive beam to the plasma. Visible plasma light is found to be a useful indicator of the presence of a wake at three locations that overall are two metres apart. Despite the complex dynamics and vastly different time scales, the X-ray radiation from the drive bunch and visible light emission from the plasma may prove to be effective non-invasive diagnostics for monitoring the energy transfer from the beam to the plasma in future high-repetition-rate experiments. [ABSTRACT FROM AUTHOR]

Published

2024

27. ATLAS Muon Spectrometer Upgrade for the HL-LHC Era's Challenges.

Author

Gazis, Evangelos N.

Subjects

LARGE Hadron Collider, PARTICLE beams, GAS detectors, CENTER of mass, LUMINOSITY, MUONS, PROTON-proton interactions

Abstract

The High-Luminosity Large Hadron Collider (HL-LHC) project aims to improve the performance of the LHC by increasing the proton–proton collision luminosity. New physics discoveries will be possible starting in 2027. The HL-LHC aims to improve the integrated luminosity by a factor of 10 concerning the current running LHC's design value. The HL-LHC project foresees delivering proton–proton collisions at 14 TeV CM (Center of Mass) energy providing the integrated luminosity to a value of 3 ab−1 for the ATLAS and CMS experiments, 50 fb−1 for LHCb, and 5 fb−1 for ALICE. The increased integrated luminosity for the above LHC experiments will provide the potential to discover rare processes while improving these measurements' signal-to-noise (S/N) ratio statistics. The ATLAS muon spectrometer has been upgraded to face the challenges of the luminosity at the HL-LHC run. The new sub-detectors are as follows: The New Small Wheel (NSW) has replaced the Cathode Strip Chambers (CSC) discs at the internal part of the ATLAS end cups. The new integrated small Monitored Drift Chambers (sMDT) with the Resistive Plate Chambers (RPC) are installed at the outer end of the ATLAS BI (Barrel Inner) layer, in the barrel–endcap transition region, at 1.0 < |η| < 1.3, where η is the pseudo-rapidity (pseudo-rapidity η is a commonly used spatial coordinate describing the angle of a particle relative to the beam axis, defined as η = − l n t a n θ 2 , where θ is the angle between the vector momentum p → and the positive direction of the beam axis). The NSW is an innovative technological achievement, including the MicroMegas (MM) gas detectors in large areas and small-strip Thin Gap Chambers (sTGC), enabling high pT (high pT is the high value of the particles' transverse momentum versus the beam collision axis) trigger and muon detection. The muon reconstruction, the background rate, other spectrometer parameters, and the NSW performance are also presented. [ABSTRACT FROM AUTHOR]

Published

2024

28. Shot noise-mitigated secondary electron imaging with ion count-aided microscopy.

Author

Agarwal, Akshay, Kasaei, Leila, Xinglin He, Kitichotkul, Ruangrawee, Hitit, Oğuz Kağan, Minxu Peng, Schultz, J. Albert, Feldman, Leonard C., and Goyal, Vivek K.

Subjects

FIELD ion microscopy, PARTICLE beams, HELIUM ions, ELECTRON microscopy, ACQUISITION of data

Abstract

Modern science is dependent on imaging on the nanoscale, often achieved through processes that detect secondary electrons created by a highly focused incident charged particle beam. Multiple types of measurement noise limit the ultimate trade-off between the image quality and the incident particle dose, which can preclude useful imaging of dose-sensitive samples. Existing methods to improve image quality do not fundamentally mitigate the noise sources. Furthermore, barriers to assigning a physically meaningful scale make the images qualitative. Here, we introduce ion count-aided microscopy (ICAM), which is a quantitative imaging technique that uses statistically principled estimation of the secondary electron yield. With a readily implemented change in data collection, ICAM substantially reduces source shot noise. In helium ion microscopy, we demonstrate 3x dose reduction and a good match between these empirical results and theoretical performance predictions. ICAM facilitates imaging of fragile samples and may make imaging with heavier particles more attractive. [ABSTRACT FROM AUTHOR]

Published

2024

29. Efficient guiding and focusing of intense laser pulse using periodic thin slits.

Author

Xu, L., Huang, T. W., Jiang, K., Wu, C. N., Peng, H., Chen, P., Li, R., Zhuo, H. B., and Zhou, C. T.

Subjects

LASER pulses, LASER-plasma interactions, PARTICLE beams, OPTICAL elements, PLASMA interactions, ENERGY transfer, WAVEGUIDES

Abstract

Slits have been widely used in laser–plasma interactions as plasma optical components for generating high-harmonic light and controlling laser-driven particle beams. Here, we propose and demonstrate that periodic thin slits can be regarded as a new breed of optical elements for efficient focusing and guiding of intense laser pulse. The fundamental physics of intense laser interaction with thin slits is studied, and it is revealed that relativistic effects can lead to enhanced laser focusing far beyond the pure diffractive focusing regime. In addition, the interaction of an intense laser pulse with periodic thin slits makes it feasible to achieve multifold enhancement in both laser intensity and energy transfer efficiency compared with conventional waveguides. These results provide a novel method for manipulating ultra-intense laser pulses and should be of interest for many laser-based applications. [ABSTRACT FROM AUTHOR]

Published

2024

30. Vibration Control Solutions for Microscopy.

Author

Morgan, John and Wigglesworth, Wes

Subjects

ACTIVE noise & vibration control, OPTICAL control, VIBRATION isolation, ELECTRON beams, MICROSCOPES, PARTICLE beams

Abstract

Vibration is always present in our environment at some level. It can have a deleterious effect on all types of microscopes and should always be considered when installing a microscope in a facility. Some microscope manufacturers, particularly those who make charged electron or particle beam microscopes, have detailed vibration specifications; others do not. In this article we discuss sources of vibration, techniques for mitigating vibration, and some general rules about which types of vibration control to use based on the type of microscope being used. [ABSTRACT FROM AUTHOR]

Published

2024

31. Physics-constrained machine learning for electrodynamics without gauge ambiguity based on Fourier transformed Maxwell's equations.

Author

Leon, Christopher and Scheinker, Alexander

Subjects

MAXWELL equations, FARADAY'S law, PARTICLE beams, FOURIER transforms, ELECTRODYNAMICS, MACHINE learning, GYROTRONS

Abstract

We utilize a Fourier transformation-based representation of Maxwell's equations to develop physics-constrained neural networks for electrodynamics without gauge ambiguity, which we label the Fourier–Helmholtz–Maxwell neural operator method. In this approach, both of Gauss's laws and Faraday's law are built in as hard constraints, as well as the longitudinal component of Ampère–Maxwell in Fourier space, assuming the continuity equation. An encoder–decoder network acts as a solution operator for the transverse components of the Fourier transformed vector potential, A ^ ⊥ (k , t) , whose two degrees of freedom are used to predict the electromagnetic fields. This method was tested on two electron beam simulations. Among the models investigated, it was found that a U-Net architecture exhibited the best performance as it trained quicker, was more accurate and generalized better than the other architectures examined. We demonstrate that our approach is useful for solving Maxwell's equations for the electromagnetic fields generated by intense relativistic charged particle beams and that it generalizes well to unseen test data, while being orders of magnitude quicker than conventional simulations. We show that the model can be re-trained to make highly accurate predictions in as few as 20 epochs on a previously unseen data set. [ABSTRACT FROM AUTHOR]

Published

2024

32. Dosimetric analysis of six whole-breast irradiation techniques in supine and prone positions.

Author

Kim, Dong Wook, Hong, Chae-Seon, Son, Junyoung, Kim, Se Young, Park, Ye-In, Chung, Mijoo, Chung, Weon Kuu, Han, Min Cheol, Kim, Jihun, Kim, Hojin, and Kim, Jin Sung

Subjects

BREAST, PATIENT positioning, LUNGS, SUPINE position, PARTICLE beams, RADIATION doses, IRRADIATION

Abstract

In breast cancer radiation therapy, minimizing radiation-related risks and toxicity is vital for improving life expectancy. Tailoring radiotherapy techniques and treatment positions can reduce radiation doses to normal organs and mitigate treatment-related toxicity. This study entailed a dosimetric comparison of six different external beam whole-breast irradiation techniques in both supine and prone positions. We selected fourteen breast cancer patients, generating six treatment plans in both positions per patient. We assessed target coverage and organs at risk (OAR) doses to evaluate the impact of treatment techniques and positions. Excess absolute risk was calculated to estimate potential secondary cancer risk in the contralateral breast, ipsilateral lung, and contralateral lung. Additionally, we analyzed the distance between the target volume and OARs (heart and ipsilateral lung) while considering the treatment position. The results indicate that prone positioning lowers lung exposure in X-ray radiotherapy. However, particle beam therapies (PBTs) significantly reduce the dose to the heart and ipsilateral lung regardless of the patient's position. Notably, negligible differences were observed between arc-delivery and static-delivery PBTs in terms of target conformity and OAR sparing. This study provides critical dosimetric evidence to facilitate informed decision-making regarding treatment techniques and positions. [ABSTRACT FROM AUTHOR]

Published

2024

33. Long-term outcomes after particle radiation therapy in patients with nasopharyngeal adenoid cystic carcinoma.

Author

Hu, Weixu, Hu, Jiyi, Huang, Qingting, Gao, Jing, Zhang, Haojiong, and Kong, Lin

Subjects

ADENOID cystic carcinoma, RADIOTHERAPY, PATIENT experience, PATIENTS' attitudes, PARTICLE beams, INTENSITY modulated radiotherapy

Abstract

Background: Nasopharyngeal adenoid cystic carcinoma (NACC) is a relatively rare salivary gland tumor that is generally associated with poor outcomes. High-dose radiotherapy is a key treatment for patients with NACC. This study reported the long-term efficacy and safety of particle beam radiation therapy (PBRT) for NACC. Methods and materials: Twenty-six patients with nonmetastatic NACC who received definitive PBRT alone were included in this retrospective study. The majority of patients (92.3%) had locally advanced disease. Twenty-five (96.15%) patients received intensity-modulated proton radiotherapy (IMPT) followed by a carbon ion radiotherapy (CIRT) boost, and one patient received CIRT alone. Overall survival (OS), local control (LC), regional control (RC), and distant metastasis control (DMC) rates were calculated via the Kaplan-Meier method. Results: The median follow-up time was 46.95 months for the entire cohort. Seven patients experienced local recurrence, and one patient experience neck lymph node recurrence. The 3- and 4-year OS, LC, RC, and DMC rates were 100% and 91.7%, 92.3% and 84.6%, 95.8% and 87.8%, and 90.2% and 71.3%, respectively. A total of 91.3% of the patients achieved complete remission of gross tumors at 1 year after PBRT. Severe acute toxicity was observed in only two patients. A grade 4 decrease in visual acuity was observed in one patient with orbital apex invasion. No late grade 3 or 5 toxicity was observed. Conclusion: Definitive PBRT provided a satisfactory 4-year OS for patients with locally advanced NACC. The toxicity was acceptable and mild. Further follow-up is necessary to confirm the efficacy and safety of definitive PBRT for patients with NACC. [ABSTRACT FROM AUTHOR]

Published

2024

34. CFD Investigations on Heavy Liquid Metal Alternative Target Design for the SPS Beam Dump Facility.

Author

Calviani, Marco, Carrelli, Carlo, Cervone, Antonio, Cioli Puviani, Pietro, Di Piazza, Ivan, Esposito, Luigi Salvatore, Manservisi, Sandro, Mazzola, Giuseppe, Tricarico, Luca, and Franqueira Ximenes, Rui

Subjects

LIQUID metals, HEAVY metals, PARTICLE beams, PARTICLE physics, COMPUTATIONAL fluid dynamics, PROTON beams

Abstract

This study introduces numerical advancements in an alternative design for the Super Proton Synchrotron (SPS) Beam Dump Facility (BDF) at the European Laboratory for Particle Physics (CERN). The design envisions a high-power operation target made of flowing liquid lead. The proposed BDF is a versatile facility for both beam-dump-like and fixed-target experiments. The target behavior is studied, assuming a proton beam with a momentum of 400 GeV/c, a pulse frequency of 1/7.2 Hz, and an average beam power of 355 kW. Using various Computational Fluid Dynamics (CFD) codes, we evaluate the behavior of liquid lead and predict the thermal stress on the target vessel induced by the pulsed heat source generated by the charged particle beam. The comparison increases the reliability of the results, investigating the dependencies on the CFD modeling approach. The beam is a volumetric heat source with data from the beam-lead interaction simulations provided by the European Laboratory for Particle Physics and obtained with a Monte Carlo code. Velocity field and stress profiles can enhance the design of the lead loop and verify its viability and safety when operated with a liquid metal target. [ABSTRACT FROM AUTHOR]

Published

2024

35. Nuclear photonics and nuclear isomers.

Author

Balabanski, Dimiter L. and Luo, Wen

Subjects

NUCLEAR excitation, ENERGY levels (Quantum mechanics), ISOMERS, PHOTONICS, PARTICLE beams, ELECTRON accelerators

Abstract

Nuclear photonics is a emerging field of science which combines research with new generation γ -ray sources based on traditional and laser-based electron accelerators. Here, we discuss isomeric studies carried out with γ -ray beams having either continuous, or quasi-monochromatic photon spectra. In experiments with high-power lasers, intense secondary radiation sources are generated. Such experiments explore isomer population or de-excitation in plasma environments. Laser-accelerated particle beams with high charge also facilitate high-energy nuclear excitations, leading to efficient production of nuclear isomers with higher lying isomeric state (reaching MeV energy level) within very-short time scales. The population of isomeric states is a sensitive diagnostic method for characterization of the laser-driven secondary radiation sources. [ABSTRACT FROM AUTHOR]

Published

2024

36. Digital Miniature Cathode Ray Magnetometer.

Author

Turqueti, Marcos, Wagner, Gustav, Goldschmidt, Azriel, and Carney, Rebecca

Subjects

CATHODE rays, PARTICLE beams, ELECTRON beams, MAGNETOMETERS, SCINTILLATORS, DIGITAL signal processing, MAGNETIC fields

Abstract

In this study, we introduce the concept and construction of an innovative Digital Miniature Cathode Ray Magnetometer designed for the precise detection of magnetic fields. This device addresses several limitations inherent to magnetic probes such as D.C. offset, nonlinearity, temperature drift, sensor aging, and the need for frequent recalibration, while capable of operating in a wide range of magnetic fields. The core principle of this device involves the utilization of a charged particle beam as the sensitivity medium. The system leverages the interaction of an electron beam with a scintillator material, which then emits visible light that is captured by an imager. The emitted scintillation light is captured by a CMOS sensor. This sensor not only records the scintillation light but also accurately determines the position of the electron beam, providing invaluable spatial information crucial for magnetic field mapping. The key innovation lies in the combination of electron beam projection, CMOS imager scintillation-based detection, and digital image signal processing. By employing this synergy, the magnetometer achieves remarkable accuracy, sensitivity and dynamic range. The precise position registration enabled by the CMOS sensor further enhances the device's utility in capturing complex magnetic field patterns, allowing for 2D field mapping. In this work, the optimization of the probe's performance is tailored for applications related to the characterization of insertion devices in light sources, including undulators. [ABSTRACT FROM AUTHOR]

Published

2024

37. Particle Beam Therapy and Surgery as Radical Treatments for Parotid Malignancies—A Single-Center Preliminary Case Study.

Author

Katagiri, Katsunori, Shiga, Kiyoto, Saito, Daisuke, Oikawa, Shin-Ichi, Ikeda, Aya, Tsuchida, Kodai, Miyaguchi, Jun, Kusaka, Takahiro, Kusaka, Iori, Ariga, Hisanori, Seto, Ichiro, Nakasato, Tatsuhiko, and Koto, Masashi

Subjects

PARTICLE beams, PAROTIDECTOMY, SURVIVAL rate, SURGERY, TREATMENT effectiveness

Abstract

Background/Objectives: Particle beam therapy (PBT) was approved in April 2018 for head and neck malignancies and has since been introduced as a radical therapy for parotid malignancies. However, its prevalence and effectiveness in relation to surgical treatment have not been investigated. Methods: In this study, we evaluated 36 patients with parotid malignancy who underwent surgery (n = 26) or PBT (n = 10) and then analyzed the annual changes in the number of patients, survival rates, and clinical factors affecting prognosis. Results: Of the ten patients who opted for PBT, two and eight patients underwent PBT before and after 2018, respectively. There was a significant difference between these two groups of patients (p = 0.04). Of the ten patients who underwent PBT, five patients were recurrent cases; meanwhile, all twenty-six patients who underwent surgery were receiving initial treatment. Only one patient in each group had local recurrence after the treatment. Conclusions: The use of PBT as a radical therapy for parotid malignancies has been increasing since 2018, and patients with recurrent tumors tended to choose PBT. The outcome of the patients who underwent PBT did not seem to be inferior compared with those of the patients who underwent surgery. The histopathological type was a crucial issue in the outcomes of patients who underwent radical therapy for parotid malignancies. [ABSTRACT FROM AUTHOR]

Published

2024

38. Design of Machine Learning-Based Algorithms for Virtualized Diagnostic on SPARC_LAB Accelerator.

Author

Latini, Giulia, Chiadroni, Enrica, Mostacci, Andrea, Martinelli, Valentina, Serenellini, Beatrice, Silvi, Gilles Jacopo, and Pioli, Stefano

Subjects

FREE electron lasers, MACHINE design, PARTICLE beams, PARTICLE accelerators, DIGITAL twins, MACHINE learning, ELECTRON beams

Abstract

Machine learning deals with creating algorithms capable of learning from the provided data. These systems have a wide range of applications and can also be a valuable tool for scientific research, which in recent years has been focused on finding new diagnostic techniques for particle accelerator beams. In this context, SPARC_LAB is a facility located at the Frascati National Laboratories of INFN, where the progress of beam diagnostics is one of the main developments of the entire project. With this in mind, we aim to present the design of two neural networks aimed at predicting the spot size of the electron beam of the plasma-based accelerator at SPARC_LAB, which powers an undulator for the generation of an X-ray free electron laser (XFEL). Data-driven algorithms use two different data preprocessing techniques, namely an autoencoder neural network and PCA. With both approaches, the predicted measurements can be obtained with an acceptable margin of error and most importantly without activating the accelerator, thus saving time, even compared to a simulator that can produce the same result but much more slowly. The goal is to lay the groundwork for creating a digital twin of linac and conducting virtualized diagnostics using an innovative approach. [ABSTRACT FROM AUTHOR]

Published

2024

39. Development of a non-intercepting weak beam current measurement electronics for Heavy Ion Accelerator Facility in Lanzhou.

Author

Wei, Yuan, Wu, Junxia, Li, Zhixue, Zhu, Guangyu, Ni, Fafu, Du, Ze, Su, Jianjun, Gu, Kewei, Wang, Tian, Zhang, Yong, Xie, Hongming, Li, Lili, Jing, Long, Qiu, Xiaoxuan, Lu, Shangshang, Tian, Ruixia, Yin, Jia, and He, Peilin

Subjects

HEAVY ion accelerators, HOMODYNE detection, PARTICLE beams, CHARGE measurement, CLINICAL pathology

Abstract

Non-destructive measurements of low-intensity charged particle beams are particularly challenging for beam diagnostics. At the Heavy Ion Accelerator Facility in Lanzhou (HIRFL), beams with weak currents below 1 µA are often provided for experiments. The detection of such low beam current is below the threshold of typical standard beam current transformers. Therefore, a low-intensity monitoring system is developed by using a sensitive capacitive pick-up (PU) and low-noise electronics. This device measures beam currents by digitally analyzing the amplitude of the PU signals using a homodyne detection scheme. During lab tests, the amplitude nonlinearity is <0.5% in the operational range of 1 nA–45 µA and the amplitude resolution is 0.94 nA. At present, four measurement systems for low beam currents are installed at HIRFL for the monitoring of standard operating conditions with low beam currents below 1 µA. After an absolute calibration with a Faraday cup, it can be used for accurate beam intensity measurement with a current resolution of about 1 nA. [ABSTRACT FROM AUTHOR]

Published

2024

40. Toward an integrated multi-gigahertz ionizing particle diagnostic.

Author

Bohon, J., Grace, C., Gulley, M., Jacobson, B., Kachiguine, S., Kim, D., Martinez-Mckinney, F., Nagel, N., Nizam, M., Padilla, R., Prakash, T., Prebys, E., Rowling, C., Schumm, B. A., Torrecilla, I. Silva, Smedley, J., Stuart, D., Wilder, M., and Zhu, D.

Subjects

PARTICLE beams, APPLICATION-specific integrated circuits, COMPUTER-aided design software

Abstract

Needs arising at both current and future accelerator facilities call for the development of radiation-hardened position-sensing diagnostics that can operate with multi-GHz repetition rates. Such instruments are likely to also have applications in the diagnosis of rapid plasma behavior. Building on the recent work of our Advanced Accelerator Diagnostics Collaboration, we are exploring the development of integrated multi-GHz ionizing particle detection systems based on chemical-vapor deposition diamond sensors, with the initial goal of producing a quadrant detector that can determine the intensity and centroid position of a particle beam at a repetition rate between 5 and 10 GHz. Results from our initial high-speed characterization work are presented, including those from a single-channel sensor with a GHz response. Approaches to achieving multi-GHz (5–10 GHz) rate capability, including the design of a dedicated Application Specific Integrated Circuit and the use of 3D RF-solver computer aided design software, are presented and discussed in more detail. 3D RF simulations suggest clean pulses of duration less than 250 ps (FWHM less than 125 ps) can be achieved with the approaches developed by this work. [ABSTRACT FROM AUTHOR]

Published

2024

41. The Role of Coulomb Fields in the Formation of Emittance in Photoguns.

Author

Ivanov, V. Ya. and Levichev, A. E.

Subjects

PARTICLE beams, NUMERICAL calculations, DENSITY

Abstract

A theoretical analysis is made of the formation of longitudinal and transverse emittance of beams of charged particles in photoguns under the influence of repulsive forces of Coulomb fields. In numerical calculations, the characteristics of bunches of charged particles with uniform and Gaussian charge density distributions are compared. The efficiency of the proposed numerical-analytical model is compared with calculations using the Astra program. The obtained numerical and analytical results can be useful in the design of photoinjectors to select the optimal parameters that determine the main characteristics of photoguns. [ABSTRACT FROM AUTHOR]

Published

2024

42. Excitation signal optimization for minimizing fluctuations in knock out slow extraction.

Author

Niedermayer, Philipp and Singh, Rahul

Subjects

PARTICLE physics, LIFE sciences, PARTICLE dynamics, MATERIALS science, RADIO frequency, PARTICLE beams, PARTICLE accelerators

Abstract

The synchrotron is a circular particle accelerator used for high energy physics experiments, material and life science, as well as hadron cancer therapy. After acceleration to the desired energies, particle beams are commonly extracted from the synchrotron using the method of resonant slow extraction. The goal is to deliver a steady particle flux—referred to as spill—to experiments and treatment facilities over the course of seconds while slowly emptying the storage ring. Any uncontrolled intensity fluctuations in the spill are detrimental to the efficiency of beam usage, as they lead to detector pileups or detector interlocks, hindering experiments and cancer treatment. Among the most widely used extraction scheme in medical facilities is the Radio Frequency Knock Out (RF-KO) driven resonant slow extraction, where the stored beam is transversely excited with a radio frequency (RF) field and the spill intensity is controlled by the excitation signal strength. This article presents particle dynamics simulations of the RF-KO system with the focus on finding effective mechanism for minimizing the intensity fluctuations while maintaining a good extraction efficiency and other advantages of KO extraction. An improved beam excitation signal which optimizes these main objectives is found, and is rigorously compared experimentally with other commonly applied techniques. [ABSTRACT FROM AUTHOR]

Published

2024

43. The Combination of the Azimuthally and Radially Polarized Beams: Helicity and Momentum Densities, Generation, and Optimal Chiral Light.

Author

Herrero‐Parareda, Albert and Capolino, Filippo

Subjects

ANGULAR momentum (Mechanics), LINEAR momentum, ENERGY density, ELECTRICAL load, ANATOMICAL planes, PARTICLE beams, CHIRALITY of nuclear particles

Abstract

Herein, the optical properties of the azimuthally radially polarized beam (ARPB), a superposition of an azimuthally polarized beam and a radially polarized beam, which can be tuned to exhibit maximum chirality at a given energy density, are investigated. This condition is called "optimal chiral light" since it represents the maximum possible local chirality at a given energy density. The transverse fields of an ARPB dominate in the transverse plane but vanish on the beam axis, where the magnetic and electric fields are purely longitudinal, leading to an optical chirality density and an energy density that stem solely from the longitudinal field components on the beam axis, where the linear and angular momentum densities vanish. The ARPB does not have a phase variation around the beam axis and nonetheless exhibits a power flow around the beam axis that causes a longitudinal orbital angular momentum density. Herein, a concise notation for the ARPB is introduced and field quantities are provided, especially for the optimally chiral configuration. The ARPB shows promise for precise 1D chirality probing and enantioseparation of chiral particles along the beam axis, relying solely on its longitudinal electric and magnetic fields. Herein, a setup is provided to generate ARPBs with controlled chirality and orbital angular momentum. [ABSTRACT FROM AUTHOR]

Published

2024

44. Thermal analysis with high accuracy of multi-beam mask fabrication.

Author

Zhang, Yanjun, Dong, Kaijun, Liu, Zhuming, and Chen, Delong

Subjects

THERMAL analysis, FINITE element method, THERMAL electrons, ELECTRON beams, PARTICLE beams

Abstract

For a 7 nm technology node and beyond, multi-beam mask fabrication based on charged particles has attracted attention widely and shows great advantages in terms of throughput. However, the heating effect during mask writing is a serious problem and makes deformation error. To address this issue, an accurate analysis of heating with multi-beam writing is necessary. In this study, the thermal effects of electron beams on a mask during writing time (exposure time and nonexposure time) were simulated with a finite element numerical method. The variation in the temperature field with two writing paths (S-shaped and E-shaped) was analyzed. A comparative analysis of the mask's deformation under different writing paths was conducted. Numerical research shows that the thermal analysis method in this study provides a guide for optimizing the process parameters of mask fabrication. [ABSTRACT FROM AUTHOR]

Published

2024

45. Manifestation of the Aharonov–Bohm effect in hydrodynamic instability of an electron beam moving along a semiconductor nanotube.

Author

Averkov, Yu. O., Prokopenko, Yu. V., and Yampol'skii, V. A.

Subjects

AHARONOV-Bohm effect, PARTICLE beams, ELECTROMAGNETIC fields, MAGNETIC flux, SEMICONDUCTORS, ELECTRON beams, NANOTUBES, CARBON nanotubes

Abstract

We theoretically study a manifestation of the Aharonov–Bohm effect in hydrodynamic instability of a tubular nonrelativistic electron beam moving along a semiconductor nanotube with dielectric filling placed in a coaxial dc magnetic field. The calculations are performed with taking into account the retardation effect for electromagnetic fields. The dispersion equation for the coupled waves of the structure under study and the electron beam, as well as the expression for the increment of the hydrodynamic instability have been derived and numerically analyzed. The mechanism of nonlinear stabilization of the hybrid bulk-surface and surface electromagnetic waves is studied by the method of slowly varying in time amplitudes and phases. The physical cause of excitation of such waves is the Cherenkov resonance, and the nonlinear stabilization mechanism is based on the trapping of beam particles by the field of the excited wave. The numerical analysis shows that the time of saturation of the instability and the maximum field amplitudes depend on the number of magnetic flux quanta in the nanotube and changes with the period equal to one magnetic flux quantum. These dependences are the result of the Aharonov–Bohm effect. [ABSTRACT FROM AUTHOR]

Published

2024

46. Global characterization of a laser-generated neutron source.

Author

Higginson, D.P., Lelièvre, R., Vassura, L., Gugiu, M.M., Borghesi, M., Bernstein, L.A., Bleuel, D. L., Goldblum, B. L., Green, A., Hannachi, F., Kar, S., Kisyov, S., Quentin, L., Schroer, M., Tarisien, M., Willi, O., Antici, P., Negoita, F., Allaoua, A., and Fuchs, J.

Subjects

PARTICLE beams, NEUTRON measurement, NEUTRON sources, PLASMA diagnostics, NEUTRON emission

Abstract

Laser-driven neutron sources are routinely produced by the interaction of laser-accelerated protons with a converter. They present complementary characteristics to those of conventional accelerator-based neutron sources (e.g. short pulse durations, enabling novel applications like radiography). We present here results from an experiment aimed at performing a global characterization of the neutrons produced using the Titan laser at the Jupiter Laser Facility (Livermore, USA), where protons were accelerated from 23 $\mathrm {\mu }$ m thick plastic targets and directed onto a LiF converter to produce neutrons. For this purpose, several diagnostics were used to measure these neutron emissions, such as CR-39, activation foils, time-of-flight detectors and direct measurement of $^7{\rm Be}$ residual activity in the LiF converters. The use of these different, independently operating diagnostics enables comparison of the various measurements performed to provide a robust characterization. These measurements led to a neutron yield of $2.0\times 10^{9}$ neutrons per shot with a modest angular dependence, close to that simulated. [ABSTRACT FROM AUTHOR]

Published

2024

47. Towards ion stopping power experiments with the laser-driven LIGHT beamline.

Author

Nazary, H., Metternich, M., Schumacher, D., Neufeld, F., Grimm, S.J., Brabetz, C., Kroll, F., Brack, F.-E., Blažević, A., Schramm, U., Bagnoud, V., and Roth, M.

Subjects

PARTICLE beams, THERMAL electrons, PROTON beams, DENSE plasmas, THERMAL plasmas, ION beams, LASER plasmas

Abstract

The main emphasis of the Laser Ion Generation, Handling and Transport (LIGHT) beamline at GSI Helmholtzzentrum für Schwerionenforschung GmbH are phase-space manipulations of laser-generated ion beams. In recent years, the LIGHT collaboration has successfully generated and focused intense proton bunches with an energy of 8 MeV and a temporal duration shorter than 1 ns (FWHM). An interesting area of application that exploits the short ion bunch properties of LIGHT is the study of ion-stopping power in plasmas, a key process in inertial confinement fusion for understanding energy deposition in dense plasmas. The most challenging regime is found when the projectile velocity closely approaches the thermal plasma electron velocity ($v_{i}\approx v_{e,\text {th}}$), for which existing theories show high discrepancies. Since conclusive experimental data are scarce in this regime, we plan to conduct experiments on laser-generated plasma probed with ions generated with LIGHT at a higher temporal resolution than previously achievable. The high temporal resolution is important because the parameters of laser-generated plasmas are changing on the nanosecond time scale. To meet this goal, our recent studies have dealt with ions of lower kinetic energies. In 2021, laser accelerated carbon ions were transported with two solenoids and focused temporally with LIGHT's radio frequency cavity. A bunch length of 1.2 ns (FWHM) at an energy of 0.6 MeV u $^{-1}$ was achieved. In 2022, protons with an energy of 0.6 MeV were transported and temporally compressed to a bunch length of 0.8 ns. The proton beam was used to measure the energy loss in a cold foil. Both the ion and proton beams will also be employed for energy loss measurements in a plasma target. [ABSTRACT FROM AUTHOR]

Published

2024

48. Combinatorial approach of immuno‐proton therapy in cancer: Rationale and potential impact.

Author

Gaikwad, Utpal, Bajpai, Jyoti, and Jalali, Rakesh

Subjects

CANCER treatment, LINEAR energy transfer, PARTICLE beams, PROTON therapy, NECK tumors, RADIOTHERAPY

Abstract

Cancer management is an expansive, growing, and evolving field. In the last decade or so, immunotherapy (IT) and particle beam therapy have made a tremendous impact in this domain. IT has already established itself as the fourth pillar of oncology. Recent emphasis has been centred around combination therapy, postulating additive or multiplicative effects of combining IT with one or more of the three conventional "pillars," that is, surgery, chemotherapy, and radiotherapy. Radio‐IT is being increasingly explored and has shown promising outcomes in both preclinical and clinical settings. Particle beam therapy such as protons, when used as the radiotherapeutic modality in conjunction with IT, can potentially limit toxicities and improve this synergism further. Modern proton therapy has demonstrated a reduction in integral dose of radiation and radiation‐induced lymphopenia in various sites. Protons, by virtue of their inherent clinically desirable physical and biological characteristics, namely, high linear energy transfer, relative biological effectiveness of range 1.1–1.6, and proven anti‐metastatic and immunogenic potential in preclinical studies, might have a superior immunogenic profile than photons. Proton‐IT combination is being studied currently by various groups in lung , head neck and brain tumors, and should be evaluated further in other subsites to replicate preclinical outcomes in a clinical setting. In this review, we summarize the currently available evidence for combinatorial approaches and feasibility of proton and IT combination, and thereafter highlight the emerging challenges for practical application of the same in clinics, while also proposing plausible solutions. [ABSTRACT FROM AUTHOR]

Published

2024

49. Toxicity profile of patients treated with proton and carbon‐ion therapy for primary nasopharyngeal carcinoma: A systematic review and meta‐analysis.

Author

Yahya, Noorazrul, Mohamad Salleh, Siti Athiyah, Mohd Nasir, Nurul Faiqah, and Abdul Manan, Hanani

Subjects

PROTON therapy, NASOPHARYNX cancer, PARTICLE beams, INTENSITY modulated radiotherapy, CONFIDENCE intervals

Abstract

Background: Proton and carbon‐ion therapy may spare normal tissues in regions with many critical structures surrounding the target volume. As toxicity outcome data are emerging, we aimed to synthesize the published data for the toxicity outcomes of proton or carbon‐ion therapy (together known as particle beam therapy [PBT]) for primary nasopharyngeal carcinoma (NPC). Materials and methods: We searched PubMed and Scopus electronic databases to identify original studies reporting toxicity outcomes following PBT of primary NPC. Quality assessment was performed using NIH's Quality Assessment Tool. Reports were extracted for information on demographics, main results, and clinical and dose factors correlates. Meta‐analysis was performed using the random‐effects model. Results: Twelve studies were selected (six using mixed particle‐photon beams, five performed comparisons to photon‐based therapy). The pooled event rates for acute grade ≥2 toxicities mucositis, dermatitis, xerostomia weight loss are 46% (95% confidence interval [95% CI]—29%–64%, I2 = 87%), 47% (95% CI—28%–67%, I2 = 87%), 16% (95% CI—9%–29%, I2 = 76%), and 36% (95% CI—27%–47%, I2 = 45%), respectively. Only one late endpoint (xerostomia grade ≥2) has sufficient data for analysis with pooled event rate of 9% (95% CI—3%–29%, I2 = 77%), lower than intensity‐modulated radiotherapy 27% (95% CI—10%–54%, I2 = 95%). For most endpoints with significant differences between the PBT and photon‐based therapies, PBT resulted in better outcomes. In two studies where dose distribution was studied, doses to the organs at risk were independent risk factors for toxicities. Conclusion: PBT may reduce the risk of acute toxicities for patients treated for primary NPC, likely due to dose reduction to critical structures. The pooled event rate for toxicities derived in this study can be a guide for patient counseling. [ABSTRACT FROM AUTHOR]

Published

2024

50. A systematic review and meta-analysis of radiotherapy and particle beam therapy for skull base chondrosarcoma: TRP-chondrosarcoma 2024.

Author

Masatoshi Nakamura, Masashi Mizumoto, Takashi Saito, Shosei Shimizu, Yinuo Li, Yoshiko Oshiro, Masako Inaba, Sho Hosaka, Hiroko Fukushima, Ryoko Suzuki, Takashi Iizumi, Kei Nakai, Kazushi Maruo, and Hideyuki Sakurai

Subjects

SKULL base, PARTICLE beams, CHONDROSARCOMA, TEMPORAL lobe, LITERATURE reviews, RADIOTHERAPY

Abstract

Introduction: Chondrosarcoma is a rare malignant bone tumor. Particle beam therapy (PT) can concentrate doses to targets while reducing adverse events. A meta-analysis based on a literature review was performed to examine the efficacy of PT and photon radiotherapy for skull base chondrosarcoma. Methods: The meta-analysis was conducted using 21 articles published from 1990 to 2022. Results: After PT, the 3- and 5-year overall survival (OS) rates were 94.1% (95% confidence interval [CI]: 91.0-96.2%) and 93.9% (95% CI: 90.6-96.1%), respectively, and the 3- and 5-year local control rates were 95.4% (95% CI: 92.0-97.4%) and 90.1% (95% CI: 76.8-96.0%), respectively. Meta-regression analysis revealed a significant association of PT with a superior 5-year OS rate compared to three-dimensional conformal radiotherapy (p < 0.001). In the studies used in the meta-analysis, the major adverse event of grade 2 or higher was temporal lobe necrosis (incidence 1-18%, median 7%). Conclusion: PT for skull base chondrosarcoma had a good outcome and may be a valuable option among radiotherapy modalities. However, high-dose postoperative irradiation of skull base chondrosarcoma can cause adverse events such as temporal lobe necrosis. [ABSTRACT FROM AUTHOR]

Published

2024