No Arabic abstract
We demonstrate a neutron tomography technique with sub-micrometer spatial resolution. Our method consists of measuring neutron diffraction spectra using a double crystal diffractometer as a function of sample rotation and then using a phase retrieval algorithm followed by tomographic reconstruction to generate a density map of the sample. In this first demonstration, silicon phase-gratings are used as samples, the periodic structure of which allows the shape of the gratings to be imaged without the need of position sensitive detectors. Topological features found in the reconstructions also appear in scanning electron micrographs. The reconstructions have a resolution of about 300 nm, which is over an order of magnitude smaller than the resolution of radiographic, phase contrast, differential phase contrast, and dark field neutron tomography methods. Further optimization of the underlying phase recovery and tomographic reconstruction algorithm is also considered.
In this paper, we study a monitoring method for neutron flux for the spallation target used in an accelerator driven sub-critical (ADS) system, where a spallation target located vertically at the centre of a sub-critical core is bombarded vertically by high-energy protons from an accelerator. First, by considering the characteristics in the spatial variation of neutron flux from the spallation target, we propose a multi-point measurement technique, i.e. the spallation neutron flux should be measured at multiple vertical locations. To explain why the flux should be measured at multiple locations, we have studied neutron production from a tungsten target bombarded by a 250 MeV-proton beam with Geant4-based Monte Carlo simulations. The simulation results indicate that the neutron flux at the central location is up to three orders of magnitude higher than the flux at lower locations. Secondly, we have developed an effective technique in order to measure the spallation neutron flux with a fission chamber (FC), by establishing the relation between the fission rate measured by FC and the spallation neutron flux. Since this relation is linear for a FC, a constant calibration factor is used to derive the neutron flux from the measured fission rate. This calibration factor can be extracted from the energy spectra of spallation neutrons. Finally, we have evaluated the proposed calibration method for a FC in the environment of an ADS system. The results indicate that the proposed method functions very well.
Imaging and manipulating individual atoms with submicrometer separation can be instrumental for quantum simulation of condensed matter Hamiltonians and quantum computation with neutral atoms. Quantum gas microscope experiments in most cases rely on quite costly solutions. Here we present an open-source design of a microscope objective for atomic strontium consisting solely of off-the-shelf lenses that is diffraction-limited for 461${,}$nm light. A prototype built with a simple stacking design is measured to have a resolution of 0.63(4)${,mu}$m, which is in agreement with the predicted value. This performance, together with the near diffraction-limited performance for 532${,}$nm light makes this design useful for both quantum gas microscopes and optical tweezer experiments with strontium. Our microscope can easily be adapted to experiments with other atomic species such as erbium, ytterbium, and dysprosium, as well as Rydberg experiments with rubidium.
Cosmic ray muon has strong penetrating power and no ionizing radiation hazards, which make cosmic ray muon an ideal probe to detect the special nuclear materials (SNM). However, the existing muon tomography experiments have the disadvantages of long imaging time and poor imaging accuracy, due to the low event rate of muons and small interaction cross section between muons and material nucleus. To optimize the imaging quality and imaging time, high spatial resolution muon tomography facility should be investigated more deeply. Micromegas with its high spatial resolution and large detection area is one of the suitable detectors for the muon tomography facility. In this paper, a high spatial muon tomography prototype was presented. The Micromegas detector was based on thermal bonding technique, which was easy to manufacture and can achieve good performance. A novel multiplexing method base on position encoding was introduced in this research to reduce the channels in an order of magnitude. Then, this paper carried out the research of a general and scalable muon imaging readout system, which employed a discrete architecture of front-end and back-end electronics and can be adapted to different scales of muon tomography experiments. Finally, a tomography prototype system was designed and implemented, including eight Micromegas detectors, four front-end electronics cards and a data acquisition board. Test results showed that this prototype can image objects with 2cm size and distinguish different materials.
A semiconductor tracker for muon scattering tomography is presented. The tracker contains silicon strip sensors with an $80,mu$m pitch, precision mechanics and integrated cooling. The electronic readout of the sensors is performed by a scalable, inexpensive, flexible, FPGA-based system, which is demonstrated to achieve an event rate of $30,$kHz. The tracker performance is compared with a Geant4 simulation. A scattering angle resolution compatible with $1.5,$mrad at the $4,$GeV average cosmic ray muon energy is demonstrated. Images of plastic, iron and lead samples are obtained using an Angle Statistics Reconstruction algorithm. The images demonstrate good contrast between low and high atomic number materials.
There are worldwide efforts to search for physics beyond the Standard Model of particle physics. Precision experiments using ultracold neutrons (UCN) require very high intensities of UCN. Efficient transport of UCN from the production volume to the experiment is therefore of great importance. We have developed a method using prestored UCN in order to quantify UCN transmission in tubular guides. This method simulates the final installation at the Paul Scherrer Institutes UCN source where neutrons are stored in an intermediate storage vessel serving three experimental ports. This method allowed us to qualify UCN guides for their intended use and compare their properties.