Simple beam models for Monte Carlo photon beam dose calculations in radiotherapy

Monte Carlo (code GEANT) produced 6 and 15 MV phase space (PS) data were used to define several simple photon beam models. For creating the PS data the energy of starting electrons hitting the target was tuned to get correct depth dose data compared to measurements. The modeling process used the full PS information within the geometrical boundaries of the beam including all scattered radiation of the accelerator head. Scattered radiation outside the boundaries was neglected. Photons and electrons were assumed to be radiated from point sources. Four different models were investigated which involved different ways to determine the energies and locations of beam particles in the output plane. Depth dose curves, profiles, and relative output factors were calculated with these models for six field sizes from 5x5 to 40x40cm2 and compared to measurements. Model 1 uses a photon energy spectrum independent of location in the PS plane and a constant photon fluence in this plane. Model 2 takes into account the spatial particle fluence distribution in the PS plane. A constant fluence is used again in model 3, but the photon energy spectrum depends upon the off axis position. Model 4, finally uses the spatial particle fluence distribution and off axis dependent photon energy spectra in the PS plane. Depth dose curves and profiles for field sizes up to 10x10cm2 were not model sensitive. Good agreement between measured and calculated depth dose curves and profiles for all field sizes was reached for model 4. However, increasing deviations were found for increasing field sizes for models 1-3. Large deviations resulted for the profiles of models 2 and 3. This is due to the fact that these models overestimate and underestimate the energy fluence at large off axis distances. Relative output factors consistent with measurements resulted only for model 4.

Calibration of a portal imaging device for high-precision dosimetry: a Monte Carlo study

Today electronic portal imaging devices (EPID's) are used primarily to verify patient positioning. They have, however, also the potential as 2D-dosimeters and could be used as such for transit dosimetry or dose reconstruction. It has been proven that such devices, especially liquid filled ionization chambers, have a stable dose response relationship which can be described in terms of the physical properties of the EPID and the pulsed linac radiation. For absolute dosimetry however, an accurate method of calibration to an absolute dose is needed. In this work, we concentrate on calibration against dose in a homogeneous water phantom. Using a Monte Carlo model of the detector we calculated dose spread kernels in units of absolute dose per incident energy fluence and compared them to calculated dose spread kernels in water at different depths. The energy of the incident pencil beams varied between 0.5 and 18 MeV. At the depth of dose maximum in water for a 6 MV beam (1.5 cm) and for a 18 MV beam (3.0 cm) we observed large absolute differences between water and detector dose above an incident energy of 4 MeV but only small relative differences in the most frequent energy range of the beam energy spectra. It is shown that for a 6 MV beam the absolute reference dose measured at 1.5 cm water depth differs from the absolute detector dose by 3.8%. At depth 1.2 cm in water, however, the relative dose differences are almost constant between 2 and 6 MeV. The effects of changes in the energy spectrum of the beam on the dose responses in water and in the detector are also investigated. We show that differences larger than 2% can occur for different beam qualities of the incident photon beam behind water slabs of different thicknesses. It is therefore concluded that for high-precision dosimetry such effects have to be taken into account. Nevertheless, the precise information about the dose response of the detector provided in this Monte Carlo study forms the basis of extracting directly the basic radiometric quantities photon fluence and photon energy fluence from the detector's signal using a deconvolution algorithm. The results are therefore promising for future application in absolute transit dosimetry and absolute dose reconstruction.

The Bison: 1952

This digital object was funded in part through a grant from the Andrew W. Mellon Foundation. The digitalization of this object was part of a collaborative effort with the Washington Research Library Consortium and George Washington University.

Neue Einblicke in die Praxis der frühen Wiedergutmachung in Bayern: Die Auerbach-Korrespondenz im Bayerischen Hauptstaatsarchiv und die Akten des Strafprozesses gegen die Führung des Landesentschädigungsamtes von 1952

Wie kaum ein anderer hat Philipp Auerbach die Anfänge der Wiedergutmachung in Westdeutschland nach 1945 geprägt. Durch seine zahlreichen Funktionen im Staatsdienst und in Organisationen ehemaliger Verfolgter gelang es ihm, 'Wiedergutmachung' an den Opfern des Nationalsozialismus in einem sehr weiten Sinn zu betreiben. Seine eigenwillige Vorstellung davon, wie Rückerstattung, Entschädigung, Entnazifizierung und öffentliches Gedenken miteinander verbunden werden sollten, trug ihm jedoch heftige Gegnerschaft ein. 1952 wurde er in einem hochpolitischen Prozess verurteilt und nahm sich unmittelbar danach das Leben. Auerbachs Korrespondenz und weitere persönliche Unterlagen aus den Jahren 1946-1951 sind jetzt im Bayerischen Hauptstaatsarchiv zugänglich. Ergänzend können seit kurzem im Staatsarchiv München die Verfahrensakten zum Strafprozess von 1952 eingesehen werden. Beide Archivalienkomplexe zusammen bieten ausgezeichnete Einblicke in die frühe Wiedergutmachungspraxis in Bayern. Sichtbar werden vor allem die vielfältigen Interessenkonflikte, die bei der Entschädigung, der Rückerstattung und der Sühne von NS-Verbrechen auftraten.

Konstruktion und Concetto. Die römischen Katafalke für Kardinal Alessandro Farnese (1589), Papst Sixtus V. (1591) und Principe Carlo Barberini (1630)

In Rom entstand im ausgehenden 16. Jahrhundert die Gattung des „Tempietto-Katafalks“, eines Trauergerüsts in Form eines überkuppelten Zentralbaus, der anlässlich der feierlichen Exequien eines hochrangigen Verstorbenen die symbolische Totenbahre als anspruchsvolle ephemere Kleinarchitektur überfängt. Anhand dreier herausragender Beispiele, der Katafalke für Kardinal Alessandro Farnese, Papst Sixtus V. und Principe Carlo Barberini, sollen die architektonische Gestalt der Funeraltempietti und ihre symbolische Aussage näher beleuchtet werden. Dabei soll weniger die Ikonographie der figürlichen Ausstattung im Mittelpunkt stehen als vielmehr die “Sprachfähigkeit” der gewählten architektonischen Formen, die bei den hier vorgestellten römischen Katafalken ein zentraler Teil der Gesamtkonzepts ist. Dabei sind sowohl der Festanlass – die Memoria des verstorbenen Würdenträgers – als auch die Architektur selbst zum Thema gemacht.