Frequently Answered Questions

If you have questions that are not covered below, please consult the on-line documentation.

Contact support staff for additional questions. During your beamtime, use the beamline cell phones.

Data collection

How can I convert from wavelength to energy?

In Blu-Ice, click on the units next to the energy input box to toggle between wavelength (Å) or energy (eV or keV).

What is the optimal beamstop to sample distance?

The backstop should be placed at a position where it allows collection of reflections in the 30-40 Å resolution range. At most wavelengths, it will be possible to collect even lower resolution, however, this will be at the expense of additional air scatter that may obscure weak reflections and reduce the diffraction signal over noise.

The Blu-Ice resolution predictor shows the low resolution limit at the given beamstop and energy values.

Sample mounting

What is the size of the white box on the Blu-Ice sample video?

The white box in the sample camera video displayed on Blu-Ice represents the approximate FWHM beam size at the sample position at all the zoom levels (unlike the box displayed in the monitors at the beamline, which does not change size with the camera zoom. With the on-axis camera, the box shows what parts of the sample to beam hits. With the orthogonal sample camera, the vertical dimension of the box shows the size of the beam at 90 degrees.

The automated loop centering leaves the camera near the medium zoom level. Is there anything wrong?

No, this is normal operation. The system uses the medium zoom level to do the alignment, in case large loops are used.

Also, during the crystal screening mode, maximum zoom is used for recording JPEG images of the crystal.

Detectors

Can I display the image header?

You can view the image header in ADXV.

How do I determine the direct beam position?

The default beam position, should usually be at the nominal centers of the detectors (within 1 pixel) listed below (in mm):

Pilatus 6M: 211.8, 217.3
Eiger 16M: 155.6 163.9

When a detector offset is selected in the Blu-Ice hutch tab, the data collection software writes the true beam center coordinates Cx,Cy to the image header. Note: For CCD detectors and the Pilatus 6M, The convention used at SSRL may not be the same as on other sites. If the detector is offset and you cannot process the data, try flipping the Cy coordinate as described below.

Pilatus and Eiger detectors

What is the optimal oscillation angle per image with the Pilatus and Eiger detectors

To get the best data, we recommend 0.1 or 0.2 degrees oscillations and short exposures per image. However, a larger oscillation (0.5 -1 degree) should be used for crystal screening or test shots. If in doubt, use the default parameters in Blu-Ice .

Important: Thin sliced images with the correct exposure time look very weak - this is to be expected, as all the reflections are partials, and you should refrain from increasing the exposure time until the pattern looks strong, since this may result in rapid radiation damage. Even if you do not exceed the maximum allowed dose with an increased exposure time, consider increasing the data multiplicity instead.

Small oscillation data can be processed at SSRL in a very straightforward manner either with XDS (see also the SSRL script autoxds) HKL3000 and the most recent version of MOSFLM can be also used, although we have found that XDS tend to give the best results for oscillations much smaller than the crystal mosaicity.

What is shutterless data collection? Can I turn it off?

Because both the Pilatus and Eiger detectors have a very short readout time compared with the typical exposure time, it is not necessary to stop the phi rotation or close the shutter while the detector reads out the image; this results in faster data collection and, for very short exposures, may reduce systematic errors. The default setting for data collection mode is to collect the entire data set without closing the shutter or stopping phi.

For MAD and SAD data collections the shutter will close and phi will stop at the end of each wedge to change the energy or the crystal orientation. For native data sets, entering a wedge value different than the default of 180 will also cause the shutter to close, dividing the data collection run into several shutterless intervals. This can be advisable to be able to pause the data collection at some point - for instance, in order to check the preliminary results of data processing (see following section)

Choosing a wedge equal to the oscillation range effectively turns off shutterless data collection. This is not recommended, with the possible exception of MAD or SAD experiments on crystals that suffer significant radiation damage after a single shot.

Why can't I pause data collection during shutterless data collection?

The ''Pause'' button in the Blu-Ice data collection tab is designed to wait until the shutter closes (so that the last image is not bad). This means that after pressing this button, data collection will continue until the end of the current wedge.

Similarly, if there is a SPEAR3 current dump in the middle of the data collection, the collection will not pause, but proceed to the end of the wedge. Multiple images will be blank. For this reason, it is important to always monitor data collection with the Pilatus or Eiger detector during shutterless data collection- or use wedges small enough that can be recollected without increasing dramatically the total dose absorbed by the crystal.

The Abort button can be used to stop the data collection, although a few images will be collected before the command takes effect. If you wish to resume the data collection after the pause, remember to recollect the last image written to disk.

The data collection takes a long time to start

The Pilatus detector is programmed to change the gain at an energy of 9000 eV. Setting the new gain for all the pixels can take about two minutes and this will happen every time you start a data collection run at an energy that crosses that threshold in either direction: eg. if you collect at 12000 eV on one run and 8000 eV in the next run or vice-versa. If you want to do a MAD experiment on an absorption edge below 9000eV and the remote energy is above 9000eV consider manually selecting a different remote energy. Ask the support person for advice.

While the Eiger detector takes a shorter time to reset the gain (about 20 seconds), it does this over a shorter energy change, and it will always take this extra time to change between the edge and remote energies during MAD experiments.

Can the Pilatus 6M detector resolve large unit cells?

Despite the Pilatus 6M relatively large pixel size compared to CCD detectors or the Eiger, in our experience it is possible to resolve closely spaced diffraction spots (see for example, the PDB structure 3M8C); note that, unlike the CCD, this type of detector has a zero point spread function, which contributes to limit the spot size.

How do I know if I am overloading the detector?

The Pilatus 6M and Eiger 16M have a large dynamic range: 1,048,576 counts. When the dynamic range is exceeded, the counter starts from zero again. The only indication for this is that holes may be observed in peaks. Blu-Ice marks in yellow pixels above 64,000 counts. These are not overloaded, but the coloring makes it easier to spot true overloads.

Unlike an integrating detector the pixel array detectors have a count-rate limit (the counts per unit of time rather than the total number of counts over the entire exposure). Pixels that exceed the maximum count rate (recorded in the image header) are flagged in red.

Determining data collection strategy

What is a reasonable exposure time for beamline X?

If in doubt, use the default values: in the Blu-Ice Collect tab, click the Default button; in the Screening Tab, click Reset defaults. If your crystals diffract very poorly or you are collecting the images at extra long or short wavelengths you may have to increase the time.

How long do I need to expose a crystal at SSRL for RIP phasing?

For radiation damage sensitive samples, the best strategy is to do a two-wavelength MAD or SAD experiment without exceeding the maximum recommended dose . Overdosing the crystal results in a unit cell expansion which most often prevents accurate measurement of any kind of phasing signal in the data. Radiation induced intensity difference are no easier to measure than anomalous or dispersive differences in this case.

For some derivatives (e.g., brominated DNA), the heavy atom may become cleaved at very low doses. The program SHARP has been reported to deal well with this particular case, using the loss of occupancy of the anomalous scatterer to enhance MAD or SAD phases, as long as the total dose is kept to a reasonable value .

Beamlines

BL12-1 and BL12-2

BL12-1 and BL12-2 are an undulator beamlines with microfocus capabilities and high flux. Here are the major characteristics:

Variable beam size : While other SSRL beamlines operate at a fixed focus, and the beam size is changed by opening or closing collimating slits upstream of the sample. On BL12-1, however, the beam can be focused down to 40x5 (h/v) microns and on BL12-2 down to 40x15 (h/v) microns continuously.

Important: Because the full beamline flux can be concentrated on a very small spot, it is important to avoid overexposing the samples.

In addition, on BL12-2 it is possible to use smaller beam sizes (eg, 15x15) by inserting a microcollimator in the beam. To use this feature, check the ''microbeam'' button of the required size in Blu-Ice.

As a rule, the microbeam should only be used to study very small crystals; for crystals larger than 10-20 microns it will be usually more advantageous to use the ''normal'' beam focused to match the crystal size.
High zoom on-axis camera: Besides the sample camera viewing the crystals from a below, a high zoom camera can be used to see the sample from the beam direction. The on-axis camera video feed can be accessed from the Blu-Ice video widget, by clicking the On-Axis button. The Back Light can be inserted in conjunction with the Light intensity bar to obtain the optimal sample visualization.
Automated beam optimizations using a special sample:The beamline software performs an automated sample optimization periodically, using a special metal sample mounted by the robot. This will take place between sample mounting and dismounting cycles - ie, the software will wait until the sample currently in used has been screened or collected from and dismounted before mounting the special sample. The optimization takes about 10 minutes. After it is completed, the new crystal sample will be mounted automatically. Since 2016, it is possible to stop the beam optimization at any time. Doing this is not recommended if you are using or planning to use the microcollimators, since they require a very precise degree of component alignment. If using the microcollimators, after skipping one or more optimizations, please check the ``Optimize beam'' button in the hutch tab. If the color has changed to green, use it to optimize the beam. Never use the ``Abort'' button to stop the optimization.
Fast energy changes. Beam optimizations are not required after a change of energy, so this only takes a few seconds. The only exception is when changing the energy below or above 9keV, because the gain of the Pixel Array Detector is energy-dependent and it needs to be changed at that value; this procedure is automatic, and it takes about 2 minutes.

BL9-2

BL9-2 is a wiggler beamline. The beam size can be continuously changed by collimating the beam by a pair of slits. The slit size is controlled by specifying the beam size in the Blu-Ice interface - note that making the beam size smaller or larger than the limits displayed in Blu-Ice will not change the beam size.

BL9-2 is equipped with a microspectrophotometer, useful to monitor photoreduction when working with samples with a metal center. See the Blu-Ice documentation for more information about this instrument.

Because beam optimizations are not required following a change of energy, this is a very fast procedure. The only exception is when changing the energy below or above 9keV, because the gain of the Pixel Array Detector is energy-dependent and it needs to be changed at that value; this procedure is automatic, and it takes about 2 minutes.

BL14-1

BL14-1 is a bending magnet beamline. The beam size can be changed by collimating the beam by a pair of slits. The slit size is controlled by specifying the beam size in the Blu-Ice interface.

SPEAR3 operation

How can I monitor the SPEAR3 beam?

The beamline status and current are displayed in the Blu-Ice status bar.

Additional information about SPEAR3 (including status of all beamlines and the 24-hour fill history) is displayed on a monitor at the beamline (top left corner of the console) and on the SSRL SPEAR3 Web page. See also ''Monitoring the SPEAR3 status remotely''

How often is the beam refilled?

SPEAR3 operates in frequent fill mode. The beam is topped up every 5 minutes. Data collection can continue normally during the injection in frequent fill mode. The normal variation of the beam intensity between fills is less than 1%. In this mode, the displayed current will always be close to the maximum injected current.

Does the frequent fill mode affect the diffraction images?

Under normal data collection conditions, we cannot detect any substantial differences between the quality of the data collected in frequent fill mode and with constant stored beam. It is also impossible to determine whether an injection took place during the collection of a diffraction image by examining the reflections in that image.

If a manual injection takes place, the data collection software will stop and restart when the temperature of the beamline optics has stabilized. If an image was being collected during manual injection, it will be recollected.

A message is displayed in the Blu-Ice status box while the beam is stabilizing following a manual injection.

How does the search and reset procedure work?

Completely search the hutch for persons before activating the search reset. The hutch door must be closed and locked before the search alarm stops ringing, otherwise the procedure must be repeated.

Problems during data collection

Is there beam in the hutch?

If the beamline is open and Blu-Ice repeatedly displays the message ''waiting for beam'', check that the beamline stoppers switch is open on the key panel in the control rack (all green LEDs should be lit). Remote users can see the stoppers LEDs by selecting the appropriate panel video preset in Blu-Ice. If this is the problem, on-site users should repeat the hutch search. Remote users must call staff or, outside normal working hours, the duty operator (650-926-4040).

If the stoppers are open, try reoptimizing the beam. If the beam optimization does not solve the problem, call support staff.

Why do I get blank diffraction images?

To determine the cause of blank diffraction images, follow these steps:

If there is no image displayed, try opening the image with a different program (e.g, ADXV) If the image looks only blank on Blu-Ice, the image server may have crashed. Contact support staff (please, send an e-mail during non-working hours, as this problem does not affect data collection).
Check the contrast in the image display: Images with no diffraction spots displayed at a high contrast level can hide diffraction features for thin-sliced images.
Verify that there is beam in the hutch (see the previous question). Try reoptimizing the beam.
Check the beam attenuation: The attenuation level depends on the beam energy, so a filter combination appropriate for data collection at a high energy can fully block the beam if you have changed to a lower energy.
Check that the detector cover is not on. Remote users can use the ``Overview'' preset in the hutch video in Blu-Ice.
If nothing is blocking the detector look at the shutter controller to determine if the shutter is opening. The switch on the controller should be on "auto" and a red LED light should light up when the shutter is open, as shown in shutter-controller. Remote users can use the Panel camera to view the shutter controller. In addition, when the shutter opens you should be able to see an increased reading for the I_beamstop beam monitor. The I_beamstop reading will be low at long wavelengths (low energies). Verify that there is beam on the beamstop by going to a shorter wavelength (higher energy).

Figure 41: Shutter controller showing open shutter status

$\includegraphics[width=0.5\textwidth]{images/shuttercontrol.ps}$
If there is diffuse diffraction but no spots, check the centering of the crystal. Open up the slits to increase the beam size and collect images at different crystal orientations. If you get diffraction with a large beam size or at some phi positions but not others, the phi axis may be misaligned. Contact support staff.
If there is no difference with large slits or at different phi positions, the crystal may not diffract (even if it was diffracting previously). Check the cryojet temperature (Blu-Ice will display an error in the status display if the temperature raises above 120 K); dismount the sample and try another sample. If you do not observe any diffraction or scatter from any sample, contact support staff.

Why can't I open Blu-Ice?

The first time you log in to Blu-Ice it will request your password. Make sure that it is typed correctly. If you cannot log in, contact the user support staff and let them know what Unix account you are using.

If you cannot start Blu-Ice from the icon in the XFCE menu:

Open a terminal on the local workstation or NX client.
Log in to a different beamline workstation. For example, if you are trying to open Blu-Ice from bl92a, log in to bl92b or bl92c. Use the command:
>ssh bl92a
>go
Note: The NX client tries to open Blu-Ice on the ''c'' workstation; if Blu-Ice fails to open, make sure that you use the ''a'' or ''b'' computer.

Why is Blu-Ice not responding?

Verify that the Blu-Ice window is active.
If you lose permission to connect to Blu-Ice (the DCSS server is off), contact support staff.
If some buttons are inactive (grayed out) move the mouse over the button. Blu-Ice will display a message explaining why the button is inactive. If the message tells that the control software for a hardware component is off-line (''DHS off-line'') contact support staff.
If the Blu-Ice status window displays the messages ''MOTOR STOP BUTTON LATCHED'', an emergency stop button may have been depressed accidentally. To reset the motors, press the green motor reset button. If collecting data remotely call support staff, or, after working hours, try contacting the duty operator at 650 926 4040.
If the entire Blu-Ice interface fails to respond, there might be a pop-up window showing an error hiding behind another window. If you cannot find it or cannot clear the error, try exiting the Blu-Ice client and starting a new one. If the fault persists, call support staff.
Sometimes, a computer crash or a network problem can hang the system. In this case, other programs and processes will also be affected. If the window manager program is hanging, log on to the host computer from another terminal and kill the processes. To list processes:
>ps -u "your_id"
and kill them with
>kill -9 "process_id"
If all the computers at the beamline are hanging or data collection will not proceed, the file system may have crashed. Contact support staff.

What does the message ''Detector error'' mean?

A detector error message in Blu-Ice can have many different causes; although often staff intervention is required in order to continue data collection, it is a good idea to retry the image collection before calling staff, as some errors (e.g., a transient network glitch) do not disable the detector permanently.

Important: Note that the ''Detector Error'' message will still be displayed after a problem with the detector has been fixed; the message will only disappear once an image has been collected without errors.

When should I optimize the beam?

It is advised to optimize:

After changing the wavelength from the Hutch tab. Automatic optimization is performed after wavelength changes during MAD data collection.
After changing the beam size, specially when going from the large to a smaller beam size, or on BL12-2, when using a microcollimator several hours after the last optimization.

Automatic optimization is also performed at regular intervals during data collection and therefore, manual optimization should not be necessary.

Data processing and graphics software

Why doesn't program X run?

Most crystallographic software packages are only installed on the data processing servers and not on the local beamline computers. Graphics programs are installed only on the local beamline workstations.

Why is iMosflm/HKL3000/other running slow?

Check the relative load of the data processing server as described in ''data processing environment''.

Why can't I autoindex my images?

The detector may have been offset from Blu-Ice: Check the detector positioner vertical and horizontal values in the Blu-Ice hutch tab. If they are not 0, look at the center coordinates in the image header.

The program LABELIT, and the mosflm and autoxds scripts provided at the SSRL can use the image header coordinates directly for autoindexing. However, if you use HKL3000, iMosflm or have your own scripts to run XDS, you must specifically provide the offset center as follows:

For HKL3000 or iMosflm:
y = Detector height (mm) - Cy (CCD detectors and Pilatus)
y = Cy (Eiger)
x = Cx (all detectors)
For XDS:
x = Cx/pixel size (all detectors)
y = Detector height (pixels) - Cy/pixel size (CCD detectors and Pilatus)
y = Cy/pixel size (Eiger)

Indexing may also fail if the diffraction is weak, if there are many ice rings or if there is a double lattice. Editing the spots manually often circumvents these problems.

Local users can mounting samples manually determine the accurate center position by following these steps:

Move the detector to the distance used for data collection.
If the resolution at the edge of the detector is 3Å or higher, use the Si sample, otherwise use the polyethylene sample. Both samples are located in the same compartment on the beamline tool board.
Collect a diffraction image. For the Si sample, use a delta phi of 15 degrees and 5 s exposure time. For the polyethylene sample, use a delta phi of 0.02 degrees and a 1 s exposure time. If the detector saturates, attenuate the beam.
Run the program center on one of the pxproc servers to calculate the direct beam position from the image.

Important: The beam center position in the image header should be accurate to within 0.1mm. In the extremely rare event that it is off my a larger amount, make sure to tell user support staff.

How do I display the JPEG snapshots of the crystal?

You can use the screening tab to display the crystal snapshots.

You may also use the program display (from a Linux or Unix shell).

Are the International Tables for Crystallography available?

On-line Space Group diagrams are available at
http://smb.slac.stanford.edu/facilities/software/spacegroups/. This site is for local access only; the NX Client can be used to view the tables remotely.

The full International Tables are available at
http://it.iucr.org/. The IUCr site is fully accessible from SSRL or the NX client (or off-site if your local institution has a license).

Is it OK to leave files on the /data disk?

Users are responsible for backing up by their data by the end of their beam time. Images stored on the /data disk can be deleted at any time. Special requests to keep files on /data should be made to support staff. The /home area can be used to store small files indefinitely.

Remote access

How can I monitor the SPEAR3 beam remotely?

The beamline status and current SPEAR3 intensity are displayed in Blu-Ice. The video tools in Blu-Ice can also be used to look at the beamline SPEAR monitor; in addition, the SPEAR3 status and fill history can also be accessed via the web.

For updates or inquiries about SPEAR3 you can call the duty operator 24/7 at 650 926-4040, or the beam information line at 650 926-BEAM (2326).

HKL3000 displays a screen size error

In order to run HKL3000, the NX client window must be at least 1100 x 900 pixels. If HKL3000 gives the error ''HKL2000 requires screen width larger then 1100 and screen height larger then 900 (sic)'', enlarge the NX client window as described in the remote desktop configuration (see section "Tuning the configuration" near the end of the page).

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