2.1. Double-crystal monochromator

The EMG-T5 Kohzu DCM has the rotational axis coupled to a translational cam assembly system, thus ensuring a fixed exit for the X-ray beam. The first crystal was predicted to receive a heat load of 120 W and was therefore liquid-nitrogen cryo-cooled, with the second crystal cooled via braided link. Initial instabilities were reduced with the installation of a Compton scattering shield for the second crystal and improved thermal isolation of the mechanical support from the monochromator crystal mounting. However, these measures were still insufficient. In addition, a Queensgate Instruments (Torquay, UK) controlled piezo feedback system was installed on the second crystal. Here, the intensity after the monochromator was monitored on the quadrant photodiode monitor and maximized by continuously adjusting a piezo actuator on the second crystal. This proved to be the single most important device that allowed ID14-4 to routinely operate. Later, cryo-cooling of the second crystal was tested and found to reduce the thermal beam drifts. An unfortunate side effect was some unwanted X-ray beam instabilities owing to the flexible cryo-pipes between the first and second crystals (Lesourd et al., 2002).

Studies of the vibrational spectra of the X-ray beam revealed that the flexible cryo-pipes could resonate at certain cryo-pump speeds (Fig. 3a). Furthermore, parasitic vibrations propagated through the experimental floor could cause the whole monochromator housing to resonate (Lesourd et al., 2002). Many studies were undertaken to identify and subsequently remove or dampen the source of these parasitic vibrations, which originated from pumps, fans and water-cooling devices in the vicinity and not necessarily on ID14-4. Further reductions in some vibrational frequencies were obtained by installing vibrational dampers on the monochromator support. Despite these efforts, the piezo feedback system was still necessary to compensate for both residual short-term vibrations and persistent long-term (> minutes) drifts. Some newer laminar-flow flexible pipes with internal braids from Witzenmann (Thorigny sur Marne, France) were tested in 2005. These significantly reduced the vibrational effects on the X-ray beam but their increased rigidity hindered the alignment of the second crystal. Subsequently, the installation of stronger motors (Phytron VSH 65-200-5-UH) acting on the mechanical support of the second crystal and their use for alignments helped to overcome this problem but the energy scans were unacceptably slow.

Figure 3 Time–frequency plots of the vibrational analysis on (a) the Kohzu monochromator and (b) the channel-cut monochromator. The horizontal axis represents time (proportional to the cryo-pump frequency) while the vertical axis is the frequency of the measured vibration signals.

2.2. Toroidal mirror

The original mirror on ID14-4 was fabricated in 1997 with a slope error of 6.8 µrad and significant non-uniformity, where local defects could reach 60 µrad. These defects were estimated to reduce the reflectivity at the focus position by an estimated 20–25% and to create a significantly non-uniform X-ray beam. The mirror was mounted in an ultra-high-vacuum vessel and bent using an air-pressure solenoid valve. The vessel was subsequently mounted on a metal frame. The mirror movements were controlled via five motors (three vertical and two horizontal) acting directly on the mirror through bellows. Small movements of the X-ray beam correlating to floor vibrations were also observed on the mirror, and suggested their transmission via the metal frame. However, the biggest problem turned out to be the erratic vertical movements of the mirror which made it difficult to reproducibly align. Originally, there was no X-ray beam visualization possible directly after the mirror to monitor this. External encoders were therefore installed to provide a long-term verification of the mirror motor positions and a beam viewing device was later installed just after the mirror. From these devices it was evident that while the motors moved correctly the mirror often did not move to the expected position and that there was an inherent mechanical problem with the coupling between the mirror and the three legs acting on it. Fortunately, the cumbersome alignment of the mirror was usually only carried out during start-ups since optical interventions were not frequently necessary owing to the fixed-exit DCM. It should also be noted that from time to time we experienced problems with the compressed-air bending mechanism. Although these were minor and mainly involved a repair of the solenoid valve, they could persist for weeks, as their effect could remain unnoticeable for the users and most local contacts. More rigorous quality-control protocols, such as the systematic checking of historical databases logging beamline parameters, are now implemented to try to prevent similar occurrences.

3.1. Monochromator system

The new monochromator on ID14-4 is a vertical offset liquid-nitrogen-cooled channel-cut monochromator. The vessel is large enough to accommodate two monolithic Si crystals (Fig. 5) and either can be used by simply translating the whole vessel horizontally. At present there are two Si[111] crystals installed and it takes approximately one hour to change between them and realign the beamline. A standardized channel-cut monochromator vessel and crystal support was designed at the ESRF and manufactured under contract by Ateliers-Peyronnard (Champ sur Drac, France). The high-quality Si[111] crystals were cut and polished at the ESRF. The centre of rotation of the first crystal was aligned with respect to the X-ray beam path with the help of the ESRF Alignment Group by using the external motors that move the whole vessel vertically and horizontally. The crystal design and cooling scheme is an evolution of that used on ID23-1, ID29 and other beamlines at the ESRF. The channel-cut Si[111] crystals contain a `weak link' between the larger diffracting face and the smaller second diffracting face. In order to adjust the pitch of the second diffracting surface a thin metal blade is used to deform the weak link integrated in the monolithic silicon crystal (Fig. 5). This allows scanning of the rocking curves and the rejection of higher harmonics. The crystals are side-cooled using liquid nitrogen by means of copper exchanger plates. The plates are attached to the sides of the crystal using invar bolts that traverse the silicon. A 0.1 mm indium foil is inserted between the copper and silicon to improve thermal contact. A Compton scattering shield was also added to reduce any undesired thermal drifts. It is also possible to monitor the temperature of the crystals and their support via thermocouples that are read through WAGO devices (Table 1). Both crystals are similar in quality, allowing us to easily replace either for testing other channel-cut designs or Si diffraction planes, such as the Si[311]. We are currently using the outer (furthest from the feed-through axis) Si[111] crystal because it gives a slightly higher flux (∼15%) than the inner crystal. The origin of this difference is not known as the rocking curves for the two crystals are identical.

Figure 5 (a) Technical drawing of the channel-cut crystal mounted on ID14-4. The crystals are coloured in brown, the cooling plates in blue, the Compton scattering shield in yellow, the pusher blade in yellow and the ceramic thermal isolation elements in red. (b) The monolithic Si[111] crystals as currently mounted in the ID14-4 monochromator.

The Bragg angle is driven with a stepper motor through a recently installed IcePAP control electronic system that was developed at the ESRF (Table 1). This system has an active feedback on a high-resolution RON886 incremental encoder coupled to an IBV650 interface (Heidenhain, Traunreut, Germany). This set-up allows a 0.05 mdeg minimum step size, corresponding to around 0.1 eV at 12.67 keV. The encoder for the monochromator is rigidly connected to a differentially pumped feed-through shaft and thus directly measures the Bragg angle. The main disadvantage of a channel-cut monochromator is of course the intrinsic vertical movement of the beam when changing energy. However, this can be readily compensated for by adjusting the mirror and/or the experimental table height. The beam movement is calculated using a simple formula [Δh = 2gcos(θ_new) − 2gcos(θ_old)], where Δh is the height change, g is the gap between the crystals (5 mm) and θ is the Bragg angle. This displacement is then applied to the mirror and experimental table. The experimental table is then scanned vertically to ensure that the optimum intensity is achieved. An additional absolute encoder (Baumer GM400) with a resolution of 21 mdeg is mounted directly on the monochromator stepper motor and is read through a WAGO device (Table 1). The zero position for this encoder was set to correspond to an energy of 11.56 keV (near the Pt L_III absorption edge) during the commissioning. This external encoder allows the monochromator Bragg angle to be verified and can also be used as a reference during monochromator interventions or if the IcePAP controller fails. In such a situation the monochromator angle can be driven close to the reference energy and reset. The monochromator is then recalibrated as described below.

A Bremsstrahlung beamstop was inserted directly after the monochromator. It is composed of 80 mm-thick tungsten that contains a 4 mm × 4 mm hole for the monochromatic beam. The position of the hole can only be adjusted manually as a safety precaution and this was done during the commissioning stages with the help of the ESRF Alignment Group. Four blades that are coupled in pairs by software act as horizontal and vertical slits directly after the beamstop. This set-up is similar to ID23-1 and ID29 and facilitates the alignment of toroidal mirrors. An actuator holding a beam intensity monitor, a series of metal foils and monochromatic beam viewer was installed after these slits (Mairs et al., 2005). The beam intensity monitor is composed of a kapton foil mounted at 45° to the X-ray beam and an associated pin diode (Hamamatsu). The diode is then read through a Novolec amplifier and a WAGO device (Table 1). It is also possible to leave the diode in the X-ray beam to monitor the monochromatic beam intensity during user experiments. The metal foils are inserted into the X-ray beam in order to record an XANES (X-ray absorption near-edge structure) spectrum around their respective absorption edges (iron K-edge 7.111 keV; copper K-edge 8.980 keV; platinum L_III, L_II and L_I 11.563 keV, 13.272 keV and 13.881 keV, respectively). The most useful metal foil for ID14-4 is platinum with an L_III absorption edge which is close to the external encoder reference position of the monochromator. The XANES spectrum is recorded by inserting a retractable pneumatic activated pin diode just after the metal foil, which is read through a Novolec amplifier and a WAGO device (Table 1). An identical scan with the platinum foil removed is also performed to normalize for intensity fluctuations in the platinum foil absorption scan. A customized Python program developed on ID23-1 (Nurizzo et al., 2006) then automatically calculates the inflection point and is used to calibrate the monochromator with a typical error of 0.3 eV. Just before the mirror there is an XBPM based on a four-pin diode that is read using a YMCS0012 current amplifier (FMB Oxford, Oxford, UK) and converted into an X-ray beam position and intensity by a linux-based device server.

3.2. Focusing mirror

The new mirror mounting system is similar to that of ID23-1 (Nurizzo et al., 2006). The mirror and vessel are independently fixed on a granite block as in Fig. 6 to ensure no detrimental vibrations are transmitted through the vessel to the mirror. The mirror can be aligned as a single unit using an ESRF designed motorized system from Cinel (Padova, Italy) that consists of five external motors acting on the granite block. The nominal angle of incidence of the mirror is 2.75 µrad. The large distance between the source and mirror means that the X-ray beam is very sensitive to any parasitic vibrational effects; however, testing of the new mirror mount system revealed a much improved vibrational stability, where a reduction from 2.8 to 1.3 in the amplification ratio for lateral vibrations transmitted from the floor to the mirror vessel could be achieved.

Figure 6 (a) Technical drawing of the toroidal mirror as mounted on ID14-4. The arrows indicate how the mirror is rigidly attached to the granite table. (b) A picture of the ID14-4 toroidal mirror taken in the metrology laboratory of the ESRF (courtesy of A. Rommeveaux, ESRF Metrology Group).

A state-of-the-art X-ray mirror and mechanical bending mechanism was fabricated and assembled by SESO (Aix-ex-Provence, France) to specifications that were validated by the ESRF Metrology Group. Tests on the unbent mirror showed that the longitudinal slope error was <1.2 µrad and that it had a surface roughness of 4.1 Å r.m.s.d. (root-mean-square deviation). The X-ray mirror is constructed from silicon and coated with palladium. The mirror is 900 mm long with a sagittal radius of 77.2 mm ± 1 mm and a nominal meridional radius of 9 km. The metrology results show that the radius of curvature repeatability at 9 km is better than 1.1% with a bending stability (ΔRc) of 18 m at 9 km.

During the initial installation of the mirror the ESRF Alignment Group ensured the precise positioning of the mirror in a flat orientation along the incident X-ray beam. The absolute external encoders mounted on the five mirror motors were then zeroed at this position and are now used as a reference in case of problems. To enable the automatic mirror alignment procedures developed at the ESRF we installed two HR50 Sony cameras cabled to a MATROX PCI card and controlled through a TACO device server. An actuator holding a diode and YAG screen was installed immediately after the mirror. The first camera is positioned to look at the YAG screen and is used for a pre-alignment procedure. This procedure is a slight modification to that described by Nurizzo et al. (2006) and ensures that the incident monochromatic beam hits the middle of an unbent mirror. In the first step, the camera region of interest (ROI) is set to continuously monitor the reflected beam on a slightly inclined mirror while it is vertically translated. By automatically capturing the mirror heights at the appearance and disappearance of the reflected beam the appropriate vertical height to centre the X-ray beam on the mirror can be determined. In the second step, the camera ROI is set to monitor a direct pencil-shaped beam that is typically defined as 0.1 mm × 0.1 mm by the slits before the mirror. The mirror is then scanned vertically at different horizontal positions. The correct horizontal position is calculated as the minimum of a regression parabola fitted on the different vertical heights. Although the mirror can be properly aligned using these measurements, the final focusing adjustment must be done at the sample position.

To complete the mirror alignment an X-ray scintillator based on a P43 phosphor screen Gd₂O₂S:Tb is mounted on a Sony HR50 camera. This camera is fixed to the X-ray diffraction detector and is driven close to the sample position. The BeamFocus software developed at the ESRF (R. Pieritz, personal communication, and Table 1) is then used to optimize the incident angle, yaw and longitudinal radius for the smallest possible beam displacements and corresponding to the smallest possible beam size. We are currently able to obtain a FWHM beam size of 90 µm vertically and 280 µm horizontally. This is much better than that previously achievable (250 µm and 320 µm) and is very close to the theoretically predicted size. This can be attributed to a much better mirror and more accurate control over the mirror's position in space. These procedures allow the beamline staff to check the optimal focusing of the mirror during each machine restart (typically five times per year). This software can also be used to focus the X-ray beam on the detector if required for more complex experiments. Refocusing on the detector is not recommended on ID14-4 as the beamline is located on a high-β section with a very low divergence source (∼10 µrad horizontally and ∼3 µrad vertically). However, the mirror has often been unbent to increase the vertical size of the beam for the complete illumination of larger crystals.

4.1. Experimental hutch equipment

The X-ray beam enters the hutch and first passes through a series of vacuum Al filters that can be inserted to provide variable X-ray attenuation. These are followed by a vacuum slit-box containing four (two vertical and two horizontal) high-precision beam-defining/cleaning slits (JJ-XRAY, Lyngby, Denmark). Immediately after the beam-definition slits there is a scattering foil diode which can be read through a Novolec amplifier and WAGO device (Table 1). This diode is used for beamline alignments and is also calibrated to produce photon flux values. After the slit box there is a fast and robust piezo millisecond shutter (CEDRAT, Meylan, France) with strain gauge followed by another scattering foil diode that is read as above. These diodes, the φ-encoder signal and the millisecond shutter control are all connected to a MUSST (multipurpose unit for synchronization, sequencing and triggering) electronic card designed by the ESRF (Table 1). This configuration allows for a simple diagnosis of shutter/φ synchronization problems, often associated with poor data quality on an undulator-based beamline (Flot et al., 2006). We also use this configuration to provide continuous integrated intensity measurements during data collections.

The sample environment is composed of a high-precision MD2M diffractometer equipped with on-axis microscope to avoid parallax error (MAATEL, Voreppe, France) (Perrakis et al., 1999) and a MK3 goniometer head for crystal realignment (Fig. 7). The sample position is kept at 100 K by a Cryo-stream 700 series (Oxford Cryosystems, Witney, UK) mounted on a pneumatic actuator. A remotely controlled cryoshutter is installed on the cryo-stream and can be remotely controlled to anneal a frozen crystal sample as needed (Giraud et al., 2009). Samples, mounted on SPINE standard cryopins, can be either mounted manually or more commonly with a Grenoble sample changer (SC3) (Cipriani et al., 2006). The current X-ray detector installed on ID14-4 is the large-surface high-quality ADSC Q315r mosaic CCD detector (ADSC, Poway, CA, USA) with a fast parallel readout time of ∼150 ms.

It is often necessary to collect data at the peak of the absorption edge for a successful experimental phasing experiment. As this peak can vary, it is advisable to perform an energy scan near to the absorption edge to determine its exact position. ID14-4 has a high-dynamic-range energy-dispersive Xflash 1000 X-ray fluorescence detector (Bruker AXS, Madison, WI, USA) for such measurements. The ROI for a particular element is programmed on the MultiMax signal processing unit of the Xflash detector through a serial line connection. This selected region is then read back using a TTL (transistor–transistor logic) signal by the MUSST card, which is also connected to the monochromator encoder. This set-up enables the fluorescence signal to be read during a continuous motion of the monochromator and allows for XANES scans in the 20–30 s timescale. All of the energy scans performed on the public tunable MX-beamlines (ID14-4, ID23-1 and ID29) at the ESRF now use this configuration.

The MD2M has also been upgraded since its installation and commissioning in July 2005. One improvement is the use of a modified beamstop and cleaning aperture. The beamstop of the MD2 (Perrakis et al., 1999) is situated 10 mm from the sample position and this has been exchanged for a longer one that is now 15 mm from the sample position. The cleaning aperture just before the sample and the small size of the beamstop (0.4 mm) at a longer distance results in the routine measurement of diffraction spots down to 50 Å resolution. A `virus bath' has also been added to retrieve any potentially hazardous biological samples dropped during the loading and unloading of samples by the SC3. The original sample backlight illumination has been upgraded to a more homogeneous and robust LCD lighting device with a front lighting option for continuous visualization during a data collection. Another improvement was the replacement of an analogue video camera in the MD2M with a new Prosilica GC655C gigabit camera. This camera is now plugged directly into an Intel gigabit card on the linux-based control computer. This allows the display of uncompressed images and results in a video quality and frame refresh rate that is far superior to what was previously achieved.

4.2. Control software

Most of the beamline stepper motors are controlled via the standard VPAP/DPAP electronics system used at the ESRF. There is, however, a migration occurring at the ESRF to the newly developed IcePAP system (Table 1). For example, the recently installed primary slits are now controlled using this system. These and other control electronics, such as the Galil motion card (Galil, Rocklin, CA, USA) used to control the MD2M spindle axis, are all embedded in a SPEC environment and driven through device server software (Table 1). Two separate SPEC sessions are used to control the optics hutch (OH2) and experimental hutch (EH4) motors. All the beamline diodes, with the exception of the XBPM, are connected to SPEC through WAGO modules (Table 1). Other essential beamline devices, such as the Xflash fluorescence detector, can be controlled in SPEC via TACO/TANGO device servers. The very top layer allows all of the beamline components to be controlled through easy and user-friendly Python-based graphical user interfaces (GUIs) developed at the ESRF. A simple MXControl panel GUI is used to control the optics and experimental hutch motors, insert filters, beam viewers and diodes and also to display the diode values for general diagnostic purposes. The more complicated MxCuBE GUI (J. Gabadinho, manuscript in preparation) has been developed to control the complete MX experiment, from mounting and centring samples through to data collection and analysis. This interface communicates to SPEC through a dedicated port and through TACO/TANGO device servers to other essential beamline components such as the SC3. In addition, it allows the implementation of simple buttons for automatic beamline procedures, such as aligning the beamline and carrying out automatic edge scans. This software is continually evolving and includes some new features such as the ability to analyse a full X-ray fluorescence (Leonard et al., 2009) using the PyMCA software (Solé et al., 2007) developed at the ESRF. This software may also be used for diagnostic purposes and was recently used to identify a faulty detector on ID14-4. Here, a much larger energy resolution (350 eV) than specified in the technical documents (<150 eV) was observed. A closer examination showed that this was due to a fault in the Peltier cooling of the silicon diode. The detector was replaced and the faulty unit was sent back for repair. In fact, MxCuBE is now mature and robust enough to routinely allow remote data collection experiments (Gabadinho et al., 2008), similar to those at the SSRL (Soltis et al., 2008).

In addition to the software for operating the beamline there are many database developments. Two particularly important databases for all of the ESRF MX beamlines are the beamline historical database (HDB) and the ISPyB user database (Beteva et al., 2006). The beamline HDB allows motor positions, beam intensity values and both optical device temperatures and vacuum values to be polled and recorded at regular intervals. The database can be interrogated to identify the source of problems and may even aid in flagging potential problems that require regular maintenance interventions, such as the refurbishment of vacuum pumps. The user database ISpyB allows the users to plan, track and log their experiments. This database will become more important as many users are now remotely controlling the beamlines from their home laboratories.