2.1. Microbeam grazing-incidence small-angle X-ray scattering

Experiments were performed at the microfocus beamline (ID13) of the ESRF (Riekel, 2000). The undulator beam was monochromated by an Si-111 double crystal to λ = 0.9755 Å, focused to a size of 25 µm × 12 µm (horizontal × vertical) by a double mirror and further collimated to 5 µm. A guard aperture in front of the sample was used to reduce parasitic scattering, and the beam intensity was calibrated by an ionization chamber. The geometry of the µGISAXS experiment is shown schematically in Fig. 1(a). The direct beam was blocked by a 300 µm-diameter cylindrical lead beamstop, and the specular beam located at α_f = α_i (α_i is the incidence angle and α_f the exit angle) was blocked by a square lead beamstop of 4 mm edge length. The sample was mounted on an xyz-translation stage and a two-dimensional goniometer (α,ψ) allowed adjustment of the sample orientation [see Fig. 1(a) and Roth et al. (2003)]. Owing to the incident angle, α_i ≃ 1°, the beam footprint is enlarged in the x direction, leading to an actual beam size of ∼300 µm × 5 µm (x × y). The scattering data were recorded using a two-dimensional charge-coupled detector (MAR CCD) with 2048 × 2048 pixels of size 64.45 µm × 64.45 µm and 16 bit readout. The sample-to-detector distance, L_SD, was calibrated to be 945.7 mm by an Ag–behenate standard (Blanton et al., 1995).

Figure 1 (a) µGISAXS and hanging-drop setup. The current hanging-drop setup is used for `stop' experiments. Abbreviations: nanostructured protein template (n), substrate (S), protein solution droplet (D), precipitating agent (A). αi and αf denote the incident and exit angle; Sp is the specular reflected beam. The specular (Sp) and direct (Di) beams are shadowed by beamstops in order to avoid saturation of the detector. (b) Future setup for in situ experiments on nanocrystal growth with the hanging-drop technique. Thin X-ray transparent windows (W) allow entry and exit of X-rays.

A characteristic feature of a GISAXS pattern is the Yoneda (1963) peak (Y). This peak occurs at angles α_i, α_f = α_c, where α_c is the critical angle of the sample. The critical angle depends on the material via the real part of the refractive index and hence on the density and roughness of the layer. The relative intensities of the two Yoneda peaks can hence be interpreted in terms of a build up of layers, islands or holes.

Further analysis of the µGISAXS patterns is possible by two perpendicular cuts, which give access to the most prominent length scales. In so-called detector scans, the length scale vertical to the surface is probed. Here, basically at a fixed incidence angle α_i the exit angle α_f is varied at ψ = 0°. The scattering from the surface can be related to correlated or uncorrelated roughness. A surface showing correlated roughness leads to well pronounced fringes along α_f in the detector scan. This effect is called resonant diffuse scattering (Holy & Baumbach, 1994). In general, the thickness of the surfaces and thin films can be determined in this way.

2.2. Nanotemplate-based crystallization method

Protein samples to be studied were prepared on glass substrates of diameter 20 mm using the protein nanotemplate crystallization method (Pechkova & Nicolini, 2001, 2002a,b). In a typical experiment, a 10 µl drop containing lysozyme (20 mg ml⁻¹), 25 mM sodium acetate buffer (NaAc) with pH 4.5 and 0.45 M sodium chloride was placed on a siliconized glass slide covered with protein nanotemplate and stabilized over a reservoir of diameter 16 mm containing 0.9 M sodium chloride in sodium acetate buffer.

For these first methodological studies on protein nanotemplate crystallization, thin hen egg-white lysozyme film was used as nanotemplate, prepared on the water–air interface and compressed up to a surface pressure of 25 mN m⁻¹ by means of a Langmuir–Blodgett trough. Two protein monolayers were deposited on the glass slide by the Langmuir–Schaeffer method. The protein template thus obtained was analysed by atomic force microscopy (AFM) (see below) in order to estimate the regularity and uniformity of deposition. The highly ordered protein nanotemplate was then utilized in the modified hanging-drop protein crystallization method, as shown schematically in Fig. 1(a). The drop was placed on the glass slide covered by the thin-film nanotemplate. As in the classical hanging-drop method, the glass slide with the protein template was sealed using vacuum grease (Pechkova & Nicolini, 2001, 2002a,b). The same crystallization conditions as for the classical hanging-drop method were applied. A series of 24 experiments were started at the same time in order that they might be stopped one after another, opening the crystallization chamber for the µGISAXS measurements. In this way, the sequence of different stages of crystallization allowed us to reconstruct the crystallization process in time. A comparison of the results obtained by the classical and nanotemplate methods will be presented elsewhere (Pechkova & Nicolini, 2005).

2.3. Atomic force microscopy

AFM is a topography-sensitive method, which can be used in certain cases in wet environments (Pechkova & Nicolini, 2002b). In its `contact' mode, the tip at the end of the cantilever touches the sample. In the non-contact `tapping' mode, AFM derives topographic information from measurements of attractive forces. Images of the lysozyme template have been obtained in tapping mode with a cantilever I type NSC14/Cr-Au MikroMash in a dry atmosphere utilizing an instrument based on the SPMagic controller built by Elbatech Srl (Pechkova & Nicolini, 2002b). The freeware WSxM (https://www.nanotec.es ) was utilized for the processing of the acquired images. The typical resonance frequency of the cantilever tip is between 110 and 220 kHz, and the proper positioning of the cantilever on the AFM tip holder has been found at a frequency of 92 kHz, with intensity 0.6 V. The set point for loop control was at 0.2 V. The integral gain value during image grabbing has been set at 4.4 (I gain) and the proportional gain value during image acquisition has been set at 8.03 (P gain). Fig. 2 shows an AFM image of the superposed two layers of lysozyme acting as a nanostructured template for subsequent crystal growth.

Figure 2 Images of the lysozyme template, obtained in tapping mode in a dry atmosphere (AFM: cantilever I type NSC14/Cr-Au MikroMash).

2.4. Experimental protocol

The protein templates were freshly plated in the hanging-drop container during the three-day experiment. The glass substrate with the thin-film template and the droplet was removed from the container and the vacuum grease area was cleaned to ensure no contamination of the signal. The droplet existed for more than 60 min in air until complete evaporation. Hence an optimum timing had to be found concerning the preparation, adjustment in the beam and data acquisition time. The glass substrate was subsequently brought into the beam and α_i was adjusted to about 1°. This procedure was restricted to less than 20 min in order to avoid precipitation of salt or nanocrystals from the solution to the substrate, which would lead to a contamination of the µGISAXS signal.

The droplet diameter was about 2 mm. Hence, the footprint of the X-ray beam was fully within the droplet diameter. The small beam size allows avoidance of excessive liquid scattering and provides, therefore, a reasonable signal-to-background ratio. The position of the drop relative to the beam was determined by an absorption scan with a photodiode. Experiments were performed with the beam at the centre of the droplet at the droplet–protein template contact area in order to optimize the signal of the weakly scattering bio­poly­mer samples. Data collection times for individual droplets varied from 7 to 20 min. This interval is well below the minimum droplet evaporation time of about 60 min. This `stop' procedure described above interrupts, therefore, crystal growth at specific times and allows the study of freshly grown thin films (see Fig. 1a)