2.1. PBPM design considerations

Fig. 1 shows schematic diagrams of the PBPM structure. Two blades (A), each with a thickness of 0.5 mm, were used as the photoemissive elements. Aluminium was chosen as the blade material due to its low atomic number and high thermal conductivity. These two blades were separated by ∼8 cm and were able to be electrically biased in order to reduce the cross-talk effect or to increase the sensitivity. No deformation or melting was observed on the blades after the irradiation of undulator light.

Figure 1 Schematic diagrams of the PBPM structure. A, blade; B and C, mask plate; D, photoelectron collector; E, aluminium block; F, ceramic insulator; G, cooling channel.

In order to reduce contamination from the scattered photoelectrons, two mask plates (B and C) were added to form entrance and exit windows of the PBPM. A biased photoelectron-collector (D), located at one side of the PBPM, was used to collect the scattered photoelectrons.

The aluminium blades were fixed to a cooled aluminium block (E) with ceramic insulators (F) for electrical insulation. The aluminium block was mounted on an XY stage driven by stepping motors. The whole PBPM unit was installed in a chamber which could be adjusted in the yaw direction for alignment purposes.

2.2. Experimental system

Three PBPMs were installed in the front-end of the U-10 undulator beamline. These three PBPMs were located at about 7.5 m, 9.0 m and 10.3 m from the middle of the undulator. An aluminium plate with a slit opening of 1 mm (H) × 20 mm (W) was mounted on a motor-driven unit, which was installed in the PBPM1 chamber and located right in front of PBPM1. The slit was used to provide a defined photon beam of height 1 mm for in situ photoemission sensitivity measurements of the blades. In order to have a softer radiation irradiated on the blades during the measurement, the slit was installed about 3 mm above the central plane.

3.1. Calibration

The photon beam position, y, was calculated from the blade currents by using the formula

where K_y is the proportional constant, I_U and I_L are the photoemission currents of the upper (U) blade and the lower (L) blade, α and β are the photoemission sensitivities of the upper and the lower blades, and γ = β/α. By changing the vertical position of the PBPM, the K_y value could be derived from the relationship of the blade currents (I_U and I_L) and the PBPM position (y).

The sensitivity test result was obtained by scanning the upper and lower blades of the PBPM across the photon beam (1 mm in height) which penetrated through the slit. Fig. 2 shows a typical result of the sensitivity measurements. The ratio, γ, was defined as the ratio of the area under the two peaks. In Fig. 2 it was about 0.7.

Figure 2 Result of the sensitivity measurement scan.

3.2. Effects of bias voltages on K_y and γ

It was observed from the results that the effects of the bias voltages (of the blade and the collector) on K_y and γ were small if suitable bias voltages were chosen. It was also noted that the K_y value with a blade bias at 0 V is almost the same as the `saturation' value as long as the collector bias voltage is large enough (e.g. ≥200 V). In this work, however, −24 V and +200 V were chosen as the bias voltages for the blade and the collector, respectively, due to a higher stability of K_y and γ at these voltages.

3.3. Effects of the horizontal position and the angular misalignment on K_y and γ

An experiment was carried out to study the effects of the misalignment in the yaw direction on the K_y and γ values. The results showed that the variation of both values was ≤1% within an angular (yaw) range of ±0.5°.

Fig. 3 shows the effect of the PBPM horizontal position on the K_y value. It is shown that the K_y value increased as the horizontal position moved outwards from the storage ring. The increase of K_y might be due to the increase of the vertical beam size of the photon beam. The decrease in photon beam brilliance (increase beam size) could decrease the conversion sensitivity of the blade currents to the PBPM position (increase the proportional constant K_y). As the horizontal position moved outwards from the storage ring, the contamination from the upstream bending-magnet light increased. This effect could increase the total beam size. The variation of the effect of the horizontal position on the γ factor was about ±8%. Although this value is not large, it is still significant. The variations in the γ value might be due to the variations of the photon energy, the photon spatial distribution or some other factors.

Figure 3 Curves of Ky versus PBPM horizontal position at different undulator gaps. Positive values are for the PBPM moving outwards from the ring.

From the experimental results it was observed that both the K_y and γ values were sensitive to the horizontal position of the PBPM. It seemed that there was a systematic factor governing this phenomenon.

3.4. Effect of the undulator gap on K_y and γ

It is shown in Fig. 3 that the K_y value increased as the undulator gap increased except for the case at a full open gap of 220 mm. The increase of K_y might be attributed to the larger beam size or other unknown reasons.

Fig. 4 shows the relationship of γ versus the undulator gap. The γ value increased from 0.67 at 25 mm gap to 0.81 at 220 mm full open gap. The increase of γ might be due to a systematic changing of the photon beam parameters, or some other unknown reasons.

Figure 4 Results of the relationship between γ and the undulator gap.

3.5. Index of uncertainty of the measurement

There are many factors contributing to the uncertainty of the PBPM measurement results. In order to study the confidence level and to find out the factors that cause the uncertainty, three sets of PBPMs were used in this work.

Fig. 5 shows the results of measurements with three PBPMs. In Fig. 5(a) there are three curves corresponding to beam positions measured by the related PBPMs. It can be seen that the values of the three curves are in good coincidence in both the trend and the microfluctuation. This implies good reliability of the measurement system. In Fig. 5(b) the three curves show the angles derived from the beam positions of the three PBPMs. Since there was no optical element in the PBPM region, the three measured angles should in principle be exactly the same. In our measurements, although the trends of the three angle curves were similar, the values of these three angle curves were different from each other. The variations in the PBPM structure, the K_y factor, the γ factor, the electron beam quality or other factors might induce the differences in the values of these three angle curves.

Figure 5 Position (a) and angle (b) results of the measurements with three PBPMs. The number of data sets taken, shown on the horizontal axis, is about two sets per second. (a) Top curve: BPM1; middle: BPM2; bottom: BPM3. (b) Top: BPM1 − BPM2; middle: BPM2 − BPM3; bottom: BPM − BPM3.

Although there were discrepancies among the values of the three angles, the differences were not large (e.g. ≤4 µrad in Fig. 5). Furthermore, it was observed that the drifts in the angle curves were small. A result of ≤±1 µrad h⁻¹ drift was obtained (this value depended on the stability of the electron beam orbit).

The results of this work showed that the position resolution of the PBPM was better than ±1 µm and the drift was better than ±1 µm h⁻¹. The index of uncertainty, evaluated from the deviations of the three angles, was estimated to be <±3 µrad without changing the undulator gap. The index of uncertainty increased to about ±70 µrad as the undulator gap changed from 25 mm to 65 mm. More studies are necessary for further improvements.