小角中性子回折計KWS-2でのナノおよびマイクロメータサイズからワイド長さスケール上でソフトマターと生物学的システムを学びます

Representative results of a successful experiment that was carried out with the KWS-2 in different working modes on the structure and morphology of two representative types of soft matter systems are given in Figures 8-11. These results are from the investigation of a series of polystyrene standard-size particles in D2O/H2O solutions, with a D2O content of 90%, and of the fully-protonated diblock copolymer C28H57-PEO5 in D2O at a high polymer volume fraction (12%). The polystyrene standard-size particles, with radii of R = 150, 350, 500, and 1,000 Å were used to test the conventional pinhole mode using different combinations of detection distances LD and wavelengths λ. Larger-sized particles (R = 4,000 Å) were used to test and commission the extended Q-range mode. The diblock copolymer that yields an ordered micellar structure at high concentrations of D2O was used to test and commission the tunable resolution mode. Figure 8 presents the results of the two-dimensional scattering patterns measured in pinhole mode using the main detector (the old scintillation detector) and in the extended Q-range mode using the focusing lenses and the high-resolution secondary detector. Figure 8A represents the scattering pattern from polystyrene particles with R = 500 Å measured at LD = 8 m by using λ=5 Å. Figure 8B shows the scattering pattern from polystyrene particles with R = 1,000 Å, collected at LD = 20 m by using λ= 20 Å. For the measurements performed with λ = 5 Å, the direct beam was collected on the central beam-stop installed in front of the detector, and the transmitted beam could be monitored with a small 3He counter that was installed in the middle of the beam-stop. This is the so called Monitor 3 (Supplementary Figure 8). The instrument has two additional 3He counters, which are installed in front of the velocity selector (Monitor 1) to monitor the polychromatic beam, and behind the velocity selector (Monitor 2) to monitor the monochromatic beam. Due to technical limitations, the measurements with λ = 20 Å were performed with the direct beam on the detector, which was the typical setup used with the old KWS-2 detector. The weaker, direct beam intensity at long wavelengths, which drops down due to gravity, could be detected without damage caused to the detector. The transmitted beam in this case was monitored with Monitor 3 at a short detection distance LD = 2 m. In this case, the gravity effects are weak and the direct beam falls on the beam-stop (like in the Figure 8A). The data collected two-dimensionally on the detector for a pixel size of 5.25 mm x 5.25 mm were further corrected for the detector sensitivity, and the contributions from the empty cell, instrument background, and solvent were absolutely calibrated using the scattering from the Plexiglas secondary standard4. Finally, the scattering patterns that were isotropically distributed around the position Q→0 were averaged radially, which delivered the dΣ/dΩ for each polystyrene particle system. The two-dimensional scattering pattern from the large polystyrene particles (R = 4,000 Å) is shown in Figure 8C, as it was measured with the high resolution detector for a pixel size of 0.5 mm x 0.5 mm. The small direct beam is focused by the lens system on the detection plan and is captured by a small beam-stop (4 mm x 4 mm) installed on the detector face. The shadow from the quadratic beam-stop can be observed in Figure 8C in the upper-left side of the active detector area. The gravity effects induce a wide vertical distribution of neutrons of different wavelengths on the detector. Additionally, because the lenses are focused perfectly, only the neutrons characterized by the central wavelength λ of the triangular distribution are delivered by the velocity selector2,5; the neutrons of different wavelengths around the central one arrive on the detector slightly out of focus. These two effects yield the weak direct beam traces that can be observed just above and below the beam-stop. In the static extended Q-range mode using lenses and the high-resolution detector, the data are collected continuously. In order to diminish the contribution of gravity effects, the scattered data are analyzed in a narrow angular sector that starts from the beam-stop and stretches horizontally to its right, as depicted in Figure 8C. The data are processed further using the typical approach for achieving the dΣ/dΩ. Figure 8D presents the intensity versus the position from the beam-stop towards the rim of the detector, as it was collected in a narrow horizontal slice with a width of 1 pixel (0.5 mm) on the high resolution detector. Data from the sample solution and the reference (solvent) are shown as they were collected in a short test measurement of 5 min. The drop of intensity at short positions is due to the beam-stop. From the ratio of the intensities at the shortest positions, the sample transmission (87%) could be estimated. The corrected and calibrated results obtained in terms of dΣ/dΩ on the solution of the polystyrene particles with R = 500 Å are shown in Figure 9, together with those from the solvent. These results illustrate the Q range that can be covered with the KWS-2 in conventional pinhole mode through the variation of the detection position LD and the use of one or more wavelengths. The form factor features8,9 of the spherical particles are also revealed: the Guinier region at low Q and the oscillations due to the spherical Bessel function in the intermediate Q range. In the high Q range, the scattering profile is dominated by the scattering from the solvent, and therefore it shows a flat behavior, like that from the solvent itself. The form factor minima are affected by the instrument resolution5 on the one hand, and by the particle size polydispersity on the other hand. The instrument resolution in the case of the KWS-2 is mostly determined by the wavelength spread of Δλ/λ= 20%. The size polydispersity for all types of particles was about σR = 8%. Figure 10 shows the results obtained in the SANS investigation of all types of polystyrene particles expressed as dΣ/dΩ after the correction for the solvent contribution was applied. The Guinier regions are clearly evidenced for all particles towards low Q values, while in the high Q ranges, the slope of -4 is revealed, which is typical for the form factor of the spherical objects. The structural parameters of the standard-size particles were confirmed by the fit of the data with the form-factor of polydisperse spheres8,9 convoluted with the resolution function of the instrument10-12. Figure 11 presents the two-dimensional and the radially-averaged one-dimensional scattering patterns from the ordering structure of C28H57-PEO5 polymer micelles that occurs in D2O at a polymer volume fraction of 12%. The results were collected at different detection distances LD, with both conventional pinhole and tunable resolution modes combined in the same measurement session. When the system is investigated in the conventional pinhole mode using the wavelength spread of Δλ/λ= 20%, as provided by the velocity selector, and continuous (static) data acquisition, three broad peaks are observed in the scattering patterns at LD = 4 m. In the tunable resolution mode, by using the chopper and the TOF data acquisition in combination with the velocity selector, the wavelength spread can be improved so that it can be checked whether these features are real or if a fine structure of them will eventually appear. The first and second peaks observed at Δλ/λ= 20% reveal a splitting when they are measured with Δλ/λ= 5%, which enabled the clear identification of the ordering of micelles into face-centered cubic (fcc) crystals5,13. These are two typical examples of how the versatility and performance of the KWS-2 SANS diffractometer can be used in an easy and user-friendly way by following the provided protocol for conducting detailed investigations on soft matter and biophysical systems that show complex structural features in terms of length scale and ordering. Figure 1: Layout of the KWS-2 SANS instrument, including all upgrades done between 2010 and 2015. (A) The general view of the instrument. (B) The secondary high-resolution detector and its tower on the top of the vacuum tank. (C) The MgF2 focusing lenses, grouped into three packages, and their cooling system (cold head). (D) The old main detector (scintillation) with its 8 x 8 array of photomultipliers. (E) The new main detector (3He tubes) with a larger detection area. Please click here to view a larger version of this figure. Figure 2: Schematic view of three working modes offered on the KWS-2. (A) The conventional pinhole mode. For LC = LD, where LC and LD are the collimation and the detection length, respectively, and optimal pinhole condition AC =2AS, where AC and AS are the collimation entrance aperture and the sample aperture, respectively, the beam profile I'P at the detector is approximately triangular with a base width equal to 2AC. (B) The high-intensity focusing mode. By using lenses, larger samples can be measured with the same resolution as in the conventional pinhole mode (the beam profile I'P at the detector is rectangular in this case). (C) The extended Q-range focusing mode. By using lenses and a small entrance aperture AC (typically 4 mm x 4 mm) that is placed on one focal point of the lens system, a small beam is transmitted onto the detector, which is placed on the other focal point of the lenses. Hence, a lower value for the minimum wave vector transfer Qm than in conventional pinhole mode can be achieved. Please click here to view a larger version of this figure. Figure 3: View of the samples mounted in the Al-cartridge of the sample holder for measurements at ambient temperature. In the cavities provided in the Al-cartridge. (A) quartz cells (B) filled with samples and covered with their stoppers (C) can be placed. The positions on the Al-cartridge were occupied with samples as follows: in positions No. 1 to No. 5, the polystyrene particles with sizes of R = 150, 350, 500, 1,000, and 4,000 Å in D2O/H2O solvent; in position No. 6, the C28H57-PEO5 diblock copolymer in D2O; in positions No. 7 and No. 8, the solvents D2O/H2O and D2O; in position No. 9, the empty quartz cell (reference); in position No. 10, the Plexiglas (standard); in position No. 11, nothing (for the measurement of the empty beam); in position No. 12, the B4C plate (taped on the back side; for the measurement of the instrument background with the blocked beam). The Al cover plate (D), coated with Cd mask on the outer face, is fixed on the top of the cartridge with the screws (E) in order to secure the sample cells and to define the neutron window (F). Please click here to view a larger version of this figure. Figure 4: View of one of the multilevel and multi-position cell-holders used on the KWS-2 for measurements at ambient conditions. The samples for the current experimental session were installed in the middle level. The three levels can be equipped with cartridges (A) designed for different cell geometries that are closed with Al-cover plates coated with Cd masks on the outer face (towards the neutrons). The installation of the cartridges on the holder is done using the screws (B). The holder has a base support (C) which allows its installation in a predetermined position on the sample stage. Please click here to view a larger version of this figure. Figure 5: Schematic top view of the sample area of KWS-2. (A) Presentation of two extreme configurations of the collimation nose, showing the available space for the installation of various sample environments in beam (the neutrons are coming from the bottom, as indicated by the yellow arrows). (B) The control panel of the lead door, with the opening and closing keys (1 and 2, respectively). The door motor works only as long as the keys are continuously pressed. The door is equipped on its edges with sensors that induce the shutdown of the motor when an obstacle is sensed. After removing the obstacle, the motor blocking can be canceled with the upper key (3) and the opening or closing action can be resumed. (C) The control panel of the collimation nose. From the nose panel, an appropriate configuration can be selected using the key (4). The nose is moved by keeping the key (5) continuously activated until the selected positioning is reached and the movement stops by itself. Please click here to view a larger version of this figure. Figure 6: Installation of the multilevel and multi-position sample holder on the sample stage for SANS measurements at ambient temperature (Photo credits: Wenzel Schürmann, Technische Universität München, Germany). The main components at the sample position are the collimation nose with the sample aperture at its end (A), the sample stage that provides the horizontal and vertical positioning of the samples in the beam (B), the entrance window of the detector vacuum tank (C), the lead door with sensors on its edge (D), and the base support of the cell holder (E), which provides for the installation of the holder on the optical breadboard (F) of the sample stage. Please click here to view a larger version of this figure. Figure 7: The dynamic range for different instrumental setups on the KWS-2. I0 represents the neutron flux at the sample position. The defined areas indicate the available Q range that can be covered when the wavelength is varied between 4.5 Å and 20 Å for particular collimation-detection configurations. Please click here to view a larger version of this figure. Figure 8: Examples of two-dimensional scattering patterns collected during the experimental session according to the current protocol. (A) The scattering pattern collected at LD = 8 m from polystyrene particles with a radius of R = 500 Å in D2O/H2O, as measured with λ= 5 Å. The scattering pattern is isotropically distributed around the beam-stop, which is blocking the direct beam in the middle of the detector. (B) The scattering pattern collected at LD = 20 m from polystyrene particles with a radius of R = 1,000 Å in D2O/H2O, as measured with λ= 20 Å. The scattering pattern is isotropically distributed around the position of the transmitted beam, which for this wavelength falls under the beam-stop and is masked together with the beam-stop using the functions of the visualization software. (C) The scattering pattern collected with the high resolution detector at LD = 17 m from polystyrene particles with a size of R = 4,000 Å in D2O/H2O, as measured with λ= 7 Å in the extended Q range, with lenses and the high resolution detector. The scattering pattern is isotropically distributed around the small beam-stop (4 mm x 4 mm), which blocks the focused direct beam. The angular sector in which the data are further analyzed is indicated on the right side of the beam-stop. (D) The intensity versus the position from the beam-stop as it was collected in a short test measurement in a narrow horizontal slice, with the width of 1 pixel (0.5 mm), on the high resolution detector. The data are shown from the sample solution and the reference (solvent). Please click here to view a larger version of this figure. Figure 9: The scattering patterns from the polystyrene particles in D2O/H2O solution (symbols) and from the solvent (lines). The data were collected in the conventional pinhole mode at different instrument configurations that are indicated by different colors. Please click here to view a larger version of this figure. Figure 10: The scattering patterns from polystyrene particles of different sizes in D2O/H2O after the correction for the scattering from solvent was applied. The red lines represent fits with the spherical form-factor9, including the instrument resolution10, 11 and the size polydispersity. The typical Q-4 asymptotic behavior for the spherical form factor is indicated by the straight line in the high Q range. The low limit of the Q range covered with different wavelengths or setups is specifically marked. Please click here to view a larger version of this figure. Figure 11: The two-dimensional and the radially averaged one-dimensional scattering patterns from the C28H57-PEO5k polymer micelles in D2O (at a polymer volume fraction of 12%), measured in the conventional pinhole mode with Δλ/λ= 20% (top) and in the tunable resolution mode, with Δλ/λ= 5% at LD = 4m (left side) and LD = 8m (right side). In the conventional mode, three broad peaks could be observed. A fine structure of the first two peaks is revealed5, 13 with improved Δλ/λ resolution. Please click here to view a larger version of this figure. Figure 12: The scattering pattern from fully-protonated PHO10k-PEO10k diblock copolymer micelles in D2O (after the correction for the scattering from solvent was applied), as measured by combining the conventional pinhole and the extended Q-range modes. A core-shell cylindrical morphology is indicated by the Q-1 dependence of scattered intensity at intermediate Q and the Q-5/3 dependence (blob scattering) observed at high Q. The intensity plateau at low Q and the bending at intermediate Q reveal the length and the thickness of the cylinders, respectively. The red curve represents the fit of the experimental data with a core-shell cylinder model9, with the instrumental resolution included10-12. Please click here to view a larger version of this figure. Figure 13: The scattering patterns from polystyrene particles (R = 150 Å) in D2O/H2O, as measured in the conventional pinhole and high-intensity (lens) modes. (A) The one-dimensional scattering patterns measured with λ = 7 Å at LD = 8 m in the conventional mode and at LD = 20 m in the high-intensity mode with lenses. In the high-intensity mode, different beam sizes on the sample were used in order to increase the intensity. Up to 12 times the gain in intensity was achieved when 26 lenses were used compared to the conventional pinhole mode. A large sample was placed in the beam by using a round quartz cell with a diameter of 5 cm. (B) The two-dimensional scattering pattern collected on the detector in pinhole mode for a beam-size of 10 mm x 10 mm. (C) The two-dimensional scattering pattern collected on the detector in high-intensity mode by using 27 lenses and a beam size of 30 mm x 30 mm. The size (resolution) of the direct beam focused on the detector is the same as in the pinhole mode. Please click here to view a larger version of this figure. Figure 14: The scattering pattern from the buffer solution and from the beta amyloid protein monomers (Aβ 1-42, molecular weight MW = 4.5 kDa) in deuterated hexafluoroisopropanol dHFIP buffer at a concentration of 5.6 mg/ml after three weeks of incubation. The full dots represent the scattering curve from the protein solution while the full triangle shows the scattering curve from the buffer solution. The blue dots denote the scattering cross-section (on the right vertical scale) from monomers after the correction for the buffer contribution was applied. The error bars represent the standard deviations derived from the neutron counts. The red solid line shows the fitted Beaucage function with fixed dimensionality d=214. Please click here to view a larger version of this figure. Figure 15: The scattering patterns from lysozyme 50 mg/ml in 50 mM acetate buffer in D2O and from buffer solution measured at different pressures, from ambient to 5,000 bar. The symbols represent data from the protein solution while the lines show the data from the buffer. The data was collected at two detection distances, LD = 4 m (open symbols) and LD = 1 m (full symbols). The inset shows the behavior of the forward scattered intensity I(Q→0) from the protein solution, the buffer, and the protein itself (after the correction for the buffer contribution was applied) as a function of pressure. Please click here to view a larger version of this figure. Parameter / Function Ancillary equipment Range of use Accuracy Technical Details Positioning Sample stage max. load 600 kg X 0 – 360 mm 0.05 mm Y 0 – 330 mm 0.05 mm Z (beam axis) manually, 600 mm θr (rotation) 0° – 360° 0.002° θt (cradle) ± 30° 0.002° Ambient temperature three-level multi-position Al holder (Cd masks) 3×9=27 wide quartz cells 3×12=36 narrow quartz cells three positions 3 large quartz cells (diameter Φ = 5 cm) Al holder (B4C mask) Temperature thermostat (oil bath) + from -25 °C to 200 °C ± 0.5 °C 4 positions small copper block in air or in vacuum chamber (with sealed cuvettes) thermostat (water bath) + two-level multi-position from 5 °C to 85 °C ± 0.2 °C 2×9=18 wide quartz cells; 2×12=24 narrow quartz cells Al block  thermostat + high precision oven from 10 °C to 120 °C < 0.1 °C 1 position, wide quartz cell Peltier-thermostated cuvette-holder from -20 °C to 140 °C ± 0.2 °C 8 positions (all types of quartz or bras sandwich type cells cells); controlled atmosphere below 5 °C (B4C mask) Pressure HP cell SANS + thermostat (water bath) up to 5,000 bar Temperature in the range from 5 °C to 85 °C Low-temperature Cryostat with sapphire windows down to 50 K Rheometry Rheometer; steady state and oscillatory modes Humidity Humidity Cell 5% to 95% Temperature in the range from 15 °C to 60 °C In-situ FT-IR20 FT-IR spectrometer Sample cells with ZnSe windows Table 1: The list of ancillary equipment available for the KWS-2 SANS diffractometer, including the range of use, the accuracy, and the details of each device. Measurement Mode Experimental setup Resolution beam/sample size max. intensity [n/s] Q-range [Å-1] Δλ/λ Conventional pinhole λ = 7 Å  20% 10 x 10 mm2 1.3 x 108 0.002 .. 0.3 LC = 2 m – 20 m LD = 1 m – 20 m λ = 4.5 Å, LC = 2 m, LD = 1 m 20% 10 x 10 mm2 2 x 108 0.01 .. 0.5 λ = 10 Å, LC = 20 m, LD = 20 m 20% 10 x 10 mm2 7.5 x 105 0.001 .. 0.02 λ = 20 Å, LC = 20 m, LD = 20 m 20% 10 x 10 mm2 4 x 104 7×10-4 .. 1.5×10-2 Focusing high-intensity λ = 7 Å, LC = 20 m, LD = 17 m 20% Φ = 50 mm 3 x 107 ≈ 0.002  .. 0.03 Focusing high-resolution (extended Q-range)  λ = 7 Å, LC = 20 m, LD = 17 m, AC = 4 x 4 mm2 20% 10 x 10 mm2 1.6 x 104 ≈ 2×10-4 .. 0.02 Tunable resolution λ = 4.5 Å,  5% 10 x 10 mm2 ca. 7% from conventional mode 0.002 .. 0.5 LC = 20 m, LD = 1 m .. 20 m Table 2: The experimental configurations available on the KWS-2 SANS diffractometer. Supplementary Figure 1: The absolute neutron flux at the sample position of the KWS-2 as a function of wavelength λ at different collimation lengths LC and for optimal filling of the reactor cold source. Please click here to download this figure. Supplementary Figure 2: Schematic view of the double disc chopper with a variable slit opening. The slit opening Δφ can be adjusted between 0° and 90° so that, depending on the chopper frequency fchopper, the opening time τw of the guide (the red rectangle on the right vertical series of pictures) can be varied. Please click here to download this figure. Supplementary Figure 3: The main user interface of the measurement control and visualization software of the KWS-2. The left-side functions (A) can be used by experimentalists, while the right-side functions and indicators (B) are used by the instrument responsible. A server or process shown in the right-side menu is operational and works normally when it is marked in green. The components marked in yellow are not activated. Any malfunction is indicated with red. Please click here to download this figure. Supplementary Figure 4: View of the kws2-Configuration menu and Sample configuration functions. The users must fill in information in the UserData fields first and then do the configuration of samples. The fields that must be filled and the actions that must be taken are marked in red. Please click here to download this figure. Supplementary Figure 5: View of the kws2 Definition menu and Select Sample functions. The actions that must be taken by the user are described in step 4.3. Please click here to download this figure. Supplementary Figure 6: View of the kws2 Definition menu and Definition of Measurements functions. The actions that must be taken by the user are described in step 4.3. Please click here to download this figure. Supplementary Figure 7: The measurement program generated by combining the defined samples and the defined experimental conditions. The actions that must be taken by the user are described in step 4.3. Please click here to download this figure. Supplementary Figure 8: The kws2-Measurement control menu and the Current Values option. The fixed parameters (positions, names, wavelength, etc.) and the variables (time, intensities, count rate, etc.) that characterize the running measurement are displayed. The actions that must be taken by the user are described in step 4.4. Please click here to download this figure. Supplementary Figure 9: The Live-Display option with the KWSlive_MainWindow menu and different data visualization options. The Surface visualization mode is selected. When the Radial average mode is selected (right-side image), the setting of parameters can be found under the Options menu Please click here to download this figure. Supplementary Figure 10: The main interface of the data reduction software qtiKWS with the options for the selection of the instrument and the location of the experimental and processed data. Please click here to download this figure. Supplementary Figure 11: The functions for defining the log-book for the set of data to be treated (info-table). The actions that must be taken by the user are described in step 5.3. Please click here to download this figure. Supplementary Figure 12: The functions for defining the detector mask for which the data will be processed. The actions that must be taken by the user are described in step 5.4. Please click here to download this figure. Supplementary Figure 13: The functions for defining the detector sensitivity maps. The actions that must be taken by the user are described in step 5.5. Please click here to download this figure. Supplementary Figure 14: The functions for generating the script table for the correction, calibration, and radial averaging of data. The actions that must be taken by the user are described in step 5.6. Please click here to download this figure. Supplementary Figure 15: The functions for plotting the processed data. The actions that must be taken by the user are described in step 5.6.5. Please click here to download this figure. Supplementary Figure 16: The functions for the preparation and splitting of the data measured in the tunable-resolution mode. The data from the two pulses delivered by the chopper and collected initially in 64 TOF channels are merged into one pulse. Several channels are grouped together so that the resulting time channels that are characterized by the Δλ/λaimed can be saved as separate files. Please click here to download this figure. Supplementary Figure 17: The main interface of the data reduction software qtiKWS with the selected option for processing the data measured with the high-resolution detector. Please click here to download this figure. Supplementary Figure 18: The functions for defining the high-resolution detector masks for which the data will be processed. The actions that must be taken by the user are described in step 5.8. Please click here to download this figure. Supplementary Figure 19: Overview of all types of sample cells typically used on the KWS-2 for the investigation of soft matter and biological samples at ambient or variable temperature. (A) View of the large quartz cells available for the high-intensity mode with lenses and a large beam size. The cell holder, which is equipped with borated plastic masks (1), permits the planning and conducting of three measurements in one session. (B) View of the quartz or brass cells that are used as sample containers and of a temperature controlled holder (Peltier-type) equipped with 8-position cartridges appropriate for each type cell. The holder is shielded with borated plastic masks (1) on both faces. (C) View of the pressure cell in operation on the KWS-2. The cell can provide pressure on the sample between the ambient and 5,000 bar in an automatic mode, controlled by the measurement program. The round Cd mask (1) with a small aperture in the middle determines the beam-size on the sample. Please click here to download this figure.