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Industrial Liaison Group:
Tel: +44 (0) 1235 778797
E-mail: [email protected]
It's day 6 of the Diamond Industrial Liaison advent calendar and today we are taking the next step on our tour through the techniques available here at Diamond to researchers both in academia and Industry. Today we are going to introduce you to X-ray diffraction.
Diffraction is a natural phenomenon and an important tool that helps scientists unravel the atomic structure of our world. You will encounter diffraction every day; in the murmur of background noise or the levels of heat or light in a room – all of these are related to diffraction. Think of waves on the ocean; they behave in the same way as light and sound. When water waves hit an object like a rock or a boat, their trajectory is changed and they disperse in a different pattern. The same is true of light and sound waves.
It is possible to have a covert chat in the workplace because the sound from your conversation bounces off walls and is spread out as it hits surrounding objects. This causes the waves to become distorted so that they reach others as a murmur of blurred sound. It’s not just sound; light and heat are also affected by diffraction.
If you shine a bright light at an object, it produces a diffraction pattern as it leaves the sample. This is because the light bounces off each atom inside the object, creating a unique arrangement of light and dark spots. This pattern can then be used to identify the atomic structure of the object itself.
Diffraction patterns provide the atomic structure of molecules such as powders, small molecules or larger ordered molecules like protein crystals. It can be used to measure strains in materials under load, by monitoring changes in the spacing of atomic planes.
Some samples can be tricky to study using diffraction. That’s why scientists use a technique called crystallography to freeze their samples into ice-like crystals. If it’s crystallised first, then almost anything – from virus structures to ancient fossils – can be studied using diffraction.
The main diffraction techniques employed at Diamond are:
Single crystal diffraction is the most widely used technique for obtaining full three-dimensional structural information of solid-state crystalline materials. This allows characterisation of, for example, molecular packing, guests in a framework structure, the nature of intra- and intermolecular interactions, molecular conformation and static and dynamic disorder. Environmental cells can be used to probe materials under a range of non-ambient conditions.
The ability of the synchrotron to obtain time-resolved data allows the investigation of short-lived excited states, rapid structural changes in solid-state reactions and order/disorder phenomena that can be observed as they occur. Because the wavelength of the X-rays is tunable, it is also possible to examine complex materials using anomalous dispersion.
Useful for
Applications of this technique range from detailed analyses of new catalytic and 'smart' electronic materials to the design of new pharmaceutical products and as the starting point for computational studies and molecular modelling. Technological areas studied include catalysis, energy storage, magnetic recording, structural biology and pharmaceuticals.
Powder diffraction is used to examine small, weakly interacting crystals in random orientations. Many materials exist as powders or in polycrystalline form, including ceramics, metals, allooys, superconductor oxides, pharmaceuticals, geochemicals, zeolites and related porous solids, all of which can be studied with powder diffraction.
High quality, high resolution powder patterns can be recorded with short scan times via multi-element analyser stages while fast, wide-angle position sensitive detectors allow the rapid collection of powder patterns in time-resolved studies in non-ambient conditions.
The high resolution opens the possibility of novel studies of phase transitions in large macromolecules as a function of temperature, leading to improved methods for the preparation of large single crystals. The high intensity X-rays can probe more deeply into the sample than laboratory techniques, and the use of resonant diffraction allows complex structures with low "normal" electron contrasts to be studied.
Useful for
Refinement of the structures of organic molecular pharmaceutical solids; determination of the effect of competing effects in highly correlated oxides and chalcogenides; the study of structural changes in polymer lithium ion conductors; the structure of porous materials and of nanoscale systems formed by inclusion within the pores and the time dependence of the intersite cation ordering in mineral phases. Technological areas studied with this technique include catalysis, energy storage, radioactive waste treatment, magnetic recording, structural biology and pharmaceuticals.
I11 - High Resolution Powder Diffraction
I12 - JEEP
I15 - Extreme Conditions
Instead of using X-rays of single energy, which is like using light of a single wavelength or colour, energy-dispersive diffraction uses a multi-wavelength "white beam" of X-rays. This polychromatic white beam can only be produced at a synchrotron and is not possible using laboratory X-ray sources. The white beam is diffracted by the sample, producing a spectrum with characteristic intensity peaks at specific photon energies. The position of these peaks provides information about the crystal structure of the sample.
Shifts in peak position are used to measure internal strains. By scanning the sample through the beam, a 2D or 3D map of strains in the sample can be produced.
The high energy of X-rays from a synchrotron allows the technique to be used on thick samples, such as real engineering components. The high intensity reduces data collection times, so larger samples can be scanned to map internal strains. The great strength of this technique is that it allows for non-destructive testing of materials.
Useful for
Strain-scanning of engineering components, for example measuring residual strains in a weld that could cause cracking in service. The high energy and high intensity X-rays can be used to "see" inside chemical processing equipment or high pressure cells. This opens up the possibility of studying chemical reactions and processes in bulk materials under realistic processing conditions.
Surfaces and interfaces determine many of the properties of materials, including electronic, magnetic and chemical behaviour. Grazing Incidence X-ray Diffraction (GIXD) is an ideal tool for determining the morphology of novel materials in realistic operating conditions.
The penetration of synchrotron X-rays through matter and the provision of environmental chambers means that a wide range of systems and environments can be studied, including; gas-solid, liquid-solid and solid-solid interfaces. Combining synchrotron techniques including X-ray diffraction in a grazing incidence geometry, measurement of diffuse scattering, grazing incidence small angle x-ray scattering (GISAXS) and X-ray reflectivity make it possible to accurately establish the structure of a material, which can be correlated with the function of the interface in realistic operating conditions.
Useful for
Surface and interface diffraction is an ideal tool for examining the atomic structure of materials, and establishing links to their behaviour. The measurement of strain at interfaces, for example, can inform on whether a component will be able to function in realistic operating conditions. The use of interchangeable environmental stages (ultrahigh vacuum, electrochemical and high gas pressure) means that a great range of technically demanding systems can be investigated, including complex alloy semiconductor and oxide surfaces, quasi crystals, polymers and biological films.
I07 - Surface and Interface Diffraction
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