J.P. Sephton

Progress towards an alanine/ESR therapy level reference dosimetry service at NPL

This paper describes work being carried out at the National Physical Laboratory towards the establishment of an alanine reference dosimetry service for radiotherapy applications. A precision fused quartz holder has been constructed to allow precise positioning of alanine dosimeters in the ESR cavity. A novel method of signal analysis based on spectrum fitting has been developed to minimize the effect of baseline distortions. Data are also presented on the relative response of alanine to 60Co gamma rays and high energy photons (4-12 MeV).

An automated system for the measurement of alanine/EPR dosimeters

NPL for several years has offered mailed reference dosimetry services based on alanine/EPR dosimeters, both at industrial and therapy dose levels. Compared to other methods of reference dosimetry, operator involvement in alanine/EPR has been found to be relatively high, and contributes significantly to the overall economics of the process. Commercially available sample changers are not suitable for high accuracy applications, and it has proved necessary to develop a dedicated automation system to handle NPL alanine dosimeter pellets. In this paper we describe an automatic sample changer for placing and retrieving alanine pellets into and out of the cavity of a standard research grade EPR spectrometer. Up to 32 pellets can be held in each removable sample tray. The sample changer software has been interfaced into the spectrometer control software to enable complete automation of the measurement process, including the optimization of spectrometer settings and rotation of the sample within the cavity.

Validation of a new TDCR system at NPL

A new triple to double coincidence ratio (TDCR) system has been established at NPL. The system incorporates a spherical optical chamber, a manual sample changing facility and an integral light-tight housing. A 6 in diameter NaI(Tl) detector has been incorporated to allow 4pibeta-gamma coincidence measurements to be performed in parallel. Details of the detectors, the electronics and the overall TDCR system are given. Validation measurements using suitable low-energy beta and electron capture nuclides, i.e. (3)H and (55)Fe have been performed. The highest efficiency achieved with a (3)H solution in Ultima Gold AB in a glass vial was 53% and in a high-efficiency LS cocktail 65%. This indicates that the optical chamber is performing well. After varying the efficiency by de-focusing the PM tubes, the activity of the sources was determined. The activity concentration determined with TDCR agreed with certified values within the range of uncertainties. Further results from validation measurements and the corresponding uncertainty budgets are presented.

Standardisation of 85Kr.

As part of a BIPM key-comparison of (85)Kr, a primary standardisation using internal gas proportional counting was performed. The supplied activity for the comparison was approximately 40 MBq and a two-stage dilution was required to reduce the activity concentration to a level suitable for gas counting. A new gas-handling rig was constructed for performing the dilutions. The dilutions, however, introduced significant uncertainties in the final result, so that additional methods suitable for measurement at higher activity levels were also used. A series of dilution ampoules with activities of 6 and 1 MBq were prepared in the new NPL gas-handling rig using inactive krypton as a diluent. Internal gas proportional counting was performed on each of the 1 MBq dilution ampoules. The proportion of the activity transferred to the counting system was estimated using pressure and volume data and the total ampoule activity calculated. Counting losses below the threshold were assumed to be 2%. The effect of changing the composition of the counting gas by inclusion of krypton was evaluated and found to not significantly change the gas gain, i.e. losses below the noise threshold (approximately 120 eV) remained essentially constant. The proportional counters were assumed to be 100% efficient with an uncertainty of 0.5% (k=1). Both 1 and 6 MBq ampoules were assayed by gamma-spectrometry using HPGe and NaI(Tl) detectors. This method resulted in an activity value with a smaller uncertainty than the primary method. Activity values for the three methods employed were consistent within the uncertainty of measurement.

A miniature TDCR system dedicated to in-situ activity assay.

In the framework of the European Metrology Research Programme (EMRP), the Joint Research Project MetroFission has a dedicated work package for the development of a portable Triple-to-Double-Coincidence-Ratio (TDCR) system dedicated to in-situ activity measurements of low-energy beta emitters arising from the operation of the next generation of nuclear power plants. In the design phase of the NPL version of the mini-TDCR, a wide range of metrological aspects and detector types was considered. This paper summarizes these aspects of design, in the light of previous experience with the primary TDCR system at NPL. For example, in this miniature version of the TDCR, the optical chamber was simplified and cylindrical geometry was deemed sufficient. The reflectivity of the surface was increased by painted layers of Spectraflect(®), a specially formulated barium sulphate coating with high reflectivity across a wide range of wave lengths including UV. This option was chosen rather than the high performing and more expensive Spectralon(®) material used for the primary NPL TDCR. The miniature TDCR system is intended for on-site monitoring and will not require as high a performance as the primary system. Other factors that were considered included sample changing, light tightness, type of photo detector, method for varying the detection efficiency, shielding and the possible addition of an internal gamma-ray source for determination of the quench parameter of the source. In this version, the sample changing is performed using a piston and an automatic shutter. Significant design effort has been applied to ensure minimal ingress of light from the piston. Efficiency variation is accomplished by increasing the vertical displacement of the vial. Provision has been made to automate this at a later stage. Maximum light transmission to the photo-multiplier tubes is obtained at the zero reference height. Validation measurements were successfully performed using four different radionuclides: (3)H, (241)Pu, (63)Ni, and (99)Tc.

Standardisation of positron-emitters in gas with the NPL primary gas counting system

A primary standard for positron-emitters in gas has been developed. The method involves internal gas proportional counting and the use of the PENELOPE Monte Carlo code to determine corrections for counting losses. The development work was carried out using (11)C, although the method can be applied to other positron emitters. The results were compared with measurements of (11)C (in solution) carried out using a secondary standard re-entrant ionisation chamber previously calibrated with reference to absolute counting techniques.

A low-noise current-sensitive amplifier-discriminator system for beta particle counting

NPL has developed a low-noise current amplifier/discriminator system for radionuclides that emit low-energy electrons and X-rays. The new beta amplifier is based on the low-noise Amptek A-250 operational amplifier. The design has been configured for optimum signal to noise ratio. The new amplifier is described and results obtained using primarily electron-capture decaying radionuclides are presented. The new amplifier gives rise to higher particle detection efficiency than the previously used Atomic Energy of Canada Limited-designed amplifier. This is shown by measurements of (54)Mn and (65)Zn. The counting plateaux are significantly longer and have reduced gradients.

A preliminary investigation into a simple method for the determination of the mean ionisation energy of gas mixtures used in the NPL primary gas counting system.

The activity concentration of gaseous beta-emitting radionuclides such as (3)H, (85)Kr and, more recently, (11)C, is measured at NPL using a set of length-compensated proportional counters. The active gas is mixed with argon-methane (P-10) and passed to the counters. Adding gases to P-10 changes the mean ionisation energy, W, of the gas mixture. Estimation of the counting losses using the Monte Carlo model requires a knowledge of W. Unfortunately, only a limited amount of published data is available. This paper describes the initial experimental studies performed to enable the extension of the MC model based loss correction method to gases other than carbon dioxide in P-10. Preliminary measurements have been made to determine the W value for a gas mixture containing (85)Kr in nitrogen and P-10. The DC current through the counters is measured; the counters are also operated in the normal way with pulse amplifiers, discriminators and scalers. The value of W is derived from a knowledge of activity, counter current and mean beta energy.

A low noise preamplifier with optoelectronic overload protection for radioactivity measurement.

Pulses from detectors used for radioactivity measurement can vary in size by several orders of magnitude. Large pulses will lead to saturation at the preamplifier output and extension of the pulse length. As a consequence, the dead time of the system increases and pulses may be lost. Electronic design techniques employed to protect against overloading tend to increase the amplifier noise level. However, an optoelectronic method of overload protection has been devised which has only a negligible effect on noise. An infrared light emitting diode interfaced to the output of the preamplifier is linked by fibre optic cable to an ultra-low leakage photodiode at the input. The conduction of the photodiode increases with the amplitude of the preamplifier output signal. Excess current is thereby prevented from entering the preamplifier and causing saturation. The preamplifier has been tested on 4π beta-gamma and gas counting systems and found to give good protection against overloading.