Charge breeders: Development of diagnostic tools to probe the underlying physics.

Charge breeders were developed more than 20 years ago in the context of radioactive ion beam (RIB) production. The main goal is to boost the charge state of a singly charged RIB to a higher value matching the A/Q of a post-accelerator. In that way, the RIB produced at some tens of keV can efficiently be accelerated to energies in a range of few MeV/u up to several tens of MeV/u, which is of interest for nuclear structure and nuclear astrophysics experiments. Two families of charge breeders have been developed: one based on Electron Cyclotron Resonance Ion Sources (ECRISs) suitable for Continuous Wave (CW) operation and another built around Electron Beam Ion Sources (EBISs) used for pulsed post-accelerators. For many years, experimental studies have been carried out to enhance the charge breeding process and improve the extracted beam quality, i.e., purity, intensity, emittance, and time structure. The evolution of the charge breeders is also closely related to the emergence of new facilities delivering even more exotic beams. Diagnostic tools, such as Faraday cups, beam profile monitors, and emittance scanners, are mandatory to tune the machines and evaluate their performances. However, to go beyond that, a better understanding of plasma physics (in ECRIS) and electron-ion interactions (in EBIS), as well as the 1+ beam characteristics, for instance, energy spread transverse emittance, is needed. Therefore, simulation codes modeling the physics phenomena in both type of charge breeders were developed to support the understanding of experimental outputs and to gain insights into non-observable parameters. Nevertheless, more sophisticated diagnostic tools are required to improve the charge breeding performance and to extend the potential applications toward new RIB facilities. This Review will present the two kinds of charge breeders and their technical evolutions. It will review the diagnostic tools and simulation codes employed for operation and evaluation of the internal physics processes.

Water content in an engineered dermal replacement during permeation of Me2SO solutions using rapid MR imaging.

The successful cryopreservation of cell and tissues typically requires the use of specialized solutions containing cryoprotective agents. At room temperature, the introduction of a cryopreservation solution can result in cell damage/death resulting from osmotic stresses and/or biochemical toxicity of the solution. For tissues, the permeation and equilibration of a cryoprotective solution throughout the tissue is important in enhancing the uniformity and consistency of the postthaw viability of the tissue. Magnetic resonance (MR) is a common nondestructive technique that can be used to quantitate the temporal and spatial composition of water and cryoprotective agents in a three-dimensional system. We have applied a recently developed rapid NMR imaging technique to quantify the transport of water in an artificial dermal replacement upon permeation of dimethyl sulfoxide (Me2SO) solutions. Results indicate that the rate of water transport is slower in the presence of Me2SO molecules. Furthermore, the transport is concentration-dependent, suggesting that Me2SO tends to retain bound water molecules in the tissue. Moreover, water transport decreases with decreasing temperature, and the presence of cells tends to increase water transport.

Rapid MR imaging of cryoprotectant permeation in an engineered dermal replacement.

Magnetic resonance (MR) imaging is a powerful technique for monitoring the permeation of cryoprotective agents (CPAs) inside tissues. However, the techniques published until now suffer from inherently long imaging times, limiting the application of these techniques to slow diffusion processes and large CPA concentrations. In this study, we present a rapid MR imaging technique based on a CHESS-FLASH scheme combined with Keyhole image acquisition. This technique can image the fast permeation of Me(2)SO solutions into freeze-dried artificial dermal replacements for concentrations down to 10% v/v. Special attention is given to evaluating the technique for quantitative analysis.