Paolo Saracco

Interrelationships between "Candidatus Phytoplasma asteris" and its leafhopper vectors (Homoptera: Cicadellidae).

Abstract The titer of chrysanthemum yellows phytoplasma (CYP, “Candidatus Phytoplasma asteris”) in the three vector species Euscelis incisus Kirschbaum, Euscelidius variegatus Kirschbaum, and Macrosteles quadripunctulatus Kirschbaum (Homoptera: Cicadellidae) was measured after controlled acquisition from infected Chrysanthemum carinatum (Schousboe) (daisy) plants. Phytoplasma DNA was quantified in relation to insect DNA (genome units [GU] of phytoplasma DNA per ng of insect DNA) by using a quantitative real-time polymerase chain reaction (PCR) procedure. The increase in phytoplasma titer recorded in hoppers after they were transferred to plants that were nonhosts for CYP provides definitive evidence for phytoplasma multiplication in leafhoppers. CYP multiplication over time in M. quadripunctulatus was much faster than in E. incisus and E. variegatus. CYP titer was also highest in M. quadripunctulatus, and this was reflected in the latent period in the insect. The mean latent period of CYP in M. quadripunctulatus was 18 d versus 30 d in E. variegatus. M. quadripunctulatus was the most efficient vector, giving 100% transmission for single insects compared with 75–82% for E. incisus or E. variegatus, respectively. By sequential transmission, we analyzed the time course of transmission: E. variegatus were persistently infective for life or until shortly before death. Occasionally, leafhoppers failed to maintain continuity of infectivity even after completion of the latent period. PCR analysis of transmitter and nontransmitter E. variegatus adults showed that some nontransmitters were CYP positive, whereas others were CYP negative. These findings suggest that both midgut and salivary gland barriers play a role in transmission efficiency.

PIXE Simulation With Geant4

Particle induced X-ray emission (PIXE) is an important physical effect that is not yet adequately modelled in Geant4. This paper provides a critical analysis of the problem domain associated with PIXE simulation; it evaluates the conceptual approach, design and implementations of PIXE modelling so far available in Geant4, and describes a set of software developments to improve PIXE simulation with Geant4. The capabilities of the developed software prototype are illustrated and applied to a study of the passive shielding of the X-ray detectors of the German eROSITA telescope on the upcoming Russian Spectrum-X-Gamma space mission.

Photon Elastic Scattering Simulation: Validation and Improvements to Geant4

Several models for the simulation of photon elastic scattering are quantitatively evaluated with respect to a large collection of experimental data retrieved from the literature. They include models based on the form factor approximation, on S-matrix calculations and on analytical parameterizations; they exploit publicly available data libraries and tabulations of theoretical calculations. Some of these models are currently implemented in general purpose Monte Carlo systems; some have been implemented and evaluated for the first time in this paper for possible use in Monte Carlo particle transport. The analysis mainly concerns the energy range between 5 keV and a few MeV. The validation process identifies the newly implemented model based on second order S-matrix calculations as the one best reproducing experimental measurements. The validation results show that, along with Rayleigh scattering, additional processes, not yet implemented in Geant4 nor in other major Monte Carlo systems, should be taken into account to realistically describe photon elastic scattering with matter above 1 MeV. Evaluations of the computational performance of the various simulation algorithms are reported along with the analysis of their physics capabilities.

Evaluation of a class of diagrams useful in many-body calculations

Abstract A recent functional approach to the many-body theory has put in evidence the relevance of the diagrams containing one fermion loop only. We shall prove here a relevant theorem which shows that all (but one) of the γ-functions are irrelevant, the contained information being transferred to analyticity properties. The simplest diagrams are explicitly evaluated and some useful limits are discussed. However, some of these diagrams have been considered also in different approaches to the many-body problem, so their evaluation is of general interest. The low-density behaviour is also considered.

Validation of

A systematic and quantitative validation of the K and L shell X-ray transition probability calculations according to different theoretical methods has been performed against experimental data. This study is relevant to the optimization of data libraries used by software systems, namely Monte Carlo codes, dealing with X-ray fluorescence. The results support the adoption of transition probabilities calculated according to the Hartree-Fock approach, which manifest better agreement with experimental measurements than calculations based on the Hartree-Slater method.A systematic and quantitative validation of the K and L shell X-ray transition probability calculations according to different theoretical methods has been performed against experimental data. This study is relevant to the optimization of data libraries used by software systems, namely Monte Carlo codes, dealing with X-ray fluorescence. The results support the adoption of transition probabilities calculated according to the Hartree-Fock approach, which manifest better agreement with experimental measurements than calculations based on the Hartree-Slater method.

{\rm K}

Phytoplasmas are plant‐pathogenic Mollicutes transmitted by leafhoppers, planthoppers, and psyllids in a persistent propagative manner. Chrysanthemum yellows phytoplasma (CY) is a member of ‘Candidatus Phytoplasma asteris’, 16Sr‐IB, and is transmitted by at least three leafhopper species, Macrosteles quadripunctulatus Kirschbaum, Euscelidius variegatus Kirschbaum, and Euscelis incisus Kirschbaum (all Homoptera: Cicadellidae: Deltocephalinae). Although M. quadripunctulatus transmits CY with very high efficiency (near 100%), 25% of E. variegatus repeatedly fail to transmit CY. The aims of this work were to correlate vector ability with different pathogen distribution in the insect body and to investigate the role of midgut and salivary glands as barriers to CY transmission. Euscelidius variegatus individuals acquired CY by feeding on infected plants or by abdominal microinjection of a phytoplasma‐enriched suspension. Insects were individually tested for transmission on daisy seedlings [Chrysanthemum carinatum Schousboe (Asteraceae)], and thereafter analysed by real‐time polymerase chain reaction (PCR) for CY concentration on whole insects or separately on heads and the rest of the body. Hoppers were classified as early and late transmitters or non‐transmitters, according to the time inoculated plants required for expression of CY symptoms. Similar transmission efficiencies were achieved following feeding or abdominal microinjection, suggesting that salivary glands may be a major barrier to transmission. Following acquisition from infected plants, all transmitters tested positive by PCR, and 60% of non‐transmitters also tested positive although with a significantly lower CY concentration. This indicates that a minimum number of phytoplasma cells may be required for successful transmission. The midgut may have prevented phytoplasma entry into the haemocoel of PCR‐negative non‐transmitters. Results suggest that both midgut and salivary glands may act as barriers. To assess the effect on CY transmission of a specific parasitic bacterium of E. variegatus, tentatively named BEV (Bacterium Euscelidius variegatus), we established a BEV‐infected population by abdominal microinjection of BEV bacteria. The presence of BEV did not significantly alter the efficiency of CY transmission.

and

Abstract Two alternative formulations of the meson exchange currents (MEC) and of the associated response to an electromagnetic field are derived in the path integral framework for a system of nucleons and pion with either a pseudoscalar or a pseudovector interaction. In the first approach, by integrating out the pionic and the electromagnetic fields configurations, we deduce a fermionic effective action SeffF leading, in conventional perturbation theory, to the standard expression for the MEC. In the second one, instead, by integrating out the fermions and electromagnetic fields configuration, we obtain a bosonic effective action SeffB. We evaluate the functional generator ZC associated to the latter in the stationary phase approximation (mean field) plus leading order quantum fluctuations. The corresponding response, most suited to deal with the physics at high energies and densities, includes RPA dressed pion propagators, the exchange interaction between the particle and the hole, the full variety of the two particles-two holes diagrams as well as the so-called bubbles into bubble (to leading order) and the nucleon self-energy (to infinite order). Thus the functional expansion, closely related to the loop expansion of the field theory, yields an unambiguous prescription for the diagrams to be kept in order to achieve a consistent many-body description of the response of a system of pions and nucleons to an electromagnetic field.

{\rm L}

Geant4-based simulations of the energy deposited by electrons in various materials are quantitatively compared to high-precision calorimetric measurements taken at Sandia Laboratories. The experimental data concern electron beams of energy between a few tens of kilolectron volt and 1 MeV at various incidence angles. Two experimental scenarios are evaluated: the longitudinal energy deposition pattern in a finely segmented detector, and the total energy deposited in a larger size calorimeter. The simulations are produced with Geant4 versions from 9.1 to 9.6; they involve models of electron-photon interactions in the standard and low energy electromagnetic packages, and various implementations of electron multiple scattering. Significant differences in compatibility with experimental data are observed in the longitudinal energy deposition patterns produced by the examined Geant4 versions, while the total deposited energy exhibits smaller variations across the various Geant4 versions, with the exception Geant4 9.4. The validation analysis, based on statistical methods, shows that the best compatibility between simulation and experimental energy deposition profiles is achieved using electromagnetic models based on the EEDL and EPDL evaluated data libraries with Geant4 9.1. The results document the accuracy achievable in the simulation of the energy deposited by low energy electrons with Geant4; they provide guidance for application in similar experimental scenarios and for improving Geant4.

Shell Radiative Transition Probability Calculations

A survey of atomic binding energies used by general purpose Monte Carlo systems is reported. Various compilations of these parameters have been evaluated; their accuracy is estimated with respect to experimental data. Their effects on physical quantities relevant to Monte Carlo particle transport are highlighted: X-ray fluorescence emission, electron and proton ionization cross sections, and Doppler broadening in Compton scattering. The effects due to different binding energies are quantified with respect to experimental data. Among the examined compilations, EADL is found in general a less suitable option to optimize simulation accuracy; other compilations exhibit distinctive capabilities in specific applications, although in general their effects on simulation accuracy are rather similar. The results of the analysis provide quantitative ground for the selection of binding energies to optimize the accuracy of Monte Carlo simulation in experimental use cases. Recommendations on software design dealing with these parameters and on the improvement of data libraries for Monte Carlo simulation are discussed.

Variation in vector competency depends on chrysanthemum yellows phytoplasma distribution within Euscelidius variegatus.

A set of physics models and parameters pertaining to the simulation of proton energy deposition in matter are evaluated in the energy range up to approximately 65 MeV, based on their implementations in the Geant4 toolkit. The analysis assesses several features of the models and the impact of their associated epistemic uncertainties, i.e., uncertainties due to lack of knowledge, on the simulation results. Possible systematic effects deriving from uncertainties of this kind are highlighted; their relevance in relation to the application environment and different experimental requirements are discussed, with emphasis on the simulation of radiotherapy set-ups. By documenting quantitatively the features of a wide set of simulation models and the related intrinsic uncertainties affecting the simulation results, this analysis provides guidance regarding the use of the concerned simulation tools in experimental applications; it also provides indications for further experimental measurements addressing the sources of such uncertainties.