teaching » Chemical Crystallography

Chem. Cryst. at the Big Bang Fair

Mar 122013

The Big Bang Fair is a free educational event open to visiting school groups that happens in March every year moving round the country. It works with partner organisations across business and industry, government and academia to try and give a flavour of the real scale of engineering and science in the UK, aimed at showing young people (primarily aged 7-19) just how many exciting and rewarding opportunities there are out there for them with the right experience and qualifications.

This year the Big Bang Fair is being held in the London, ExCeL Arena, 14^th-17^th March. Since 2013 is the Bragg centenary, STFC have very kindly funded a stand at this year’s fair, which will be totally dedicated to crystallography. The BCA, Diamond Light Source, ISIS and STFC have worked together to develop the stand designed to tell everyone how great crystallography is through the medium of hands on activities, lasers, and sweets. The fair is expecting 75,000 people (mostly children) through the doors over the course of four days, so Andrew Cairns, Josh Hill, Nick Funnell, Mike Glazer, George Pidgeon, Karim Sutton and Amber Thompson are all going along from Oxford to help out. Here are some photos of the first day.

Two crystallographers check the interlocks on the Lego Beamline

You are never too young to learn about packing…

…especially when there’s sweets involved!

Teaching physicists chemistry

George demonstrates the Lego Beamline

Smelly molecules

Demonstrating Fourier transforms takes concentration

Growing a crystal, one marble at a time

Protein crystals are beautiful

The Crystallography stand at the Big Bang

An Engagement with X-rays

Mar 302011

Not content with showing off the eye-catching brilliance of her new diamond engagement ring, final year Inorganic Chemistry student Rowena Scott wanted to reveal the beautiful symmetry of its atomic structure. She recorded an X-ray diffraction pattern from the diamond using one of the Chemistry Department’s new state of the art, SuperNova dual source X‑ray diffractometers.

Rowena’s current research project with Dr Simon Clarke involves the synthesis of iron chalcogenide superconductors. The structures of these materials are then determined using single crystal X-ray diffraction techniques.

Chemical Crystallography Service manager, Dr Amber Thompson said “We see a wide range of materials of varying crystallinity from many research groups in the Department of Chemistry, usually grown at the bottom of glass schlenks or flasks; it’s not often that such a lovely crystal turns up mounted in a band of gold”.

$Diffraction pattern of the diamond$ The diffracted X-rays were measured while rotating the diamond in an X-ray beam. The resulting diffraction pattern shows the position and intensity of the beams diffracted by the organised structure of carbon atoms in the crystal. The white rings overlaid on the image indicate the angles at which diamond peaks are expected to occur, which agree with the collected data.

Diamond diffracts X-rays so efficiently that the X-ray generator had to be run at 10% of its usual power in order to avoid overloading the X-ray detector.

Teaching Award

Nov 162010

Congratulations to Dr David Watkin who received an award under the Oxford Teaching Awards scheme for excellence in teaching as attested by student feedback and with the support of the department. He received a certificate presented by Professor Andrew Hamilton, the Vice-Chancellor of Oxford at Rhodes House.
The Oxford Teaching Awards scheme, co-ordinated by the Oxford University Learning Institute, recognises outstanding contributions award winners have made to teaching and learning at Oxford.

Chemical Crystallography – Science, Technology or a Black Art

Jul 132010

Cryst. Rev. (2010), 16(3), 197-230. [ doi:10.1080/08893110903483246 ]

X-ray single crystal structure analysis has become a gold standard for the determination of molecular geometry. The reliability of the technique is a triumph for science and technology working together. The uniqueness of well-crystalline material intrigued early natural philosophers, and their examinations, followed by the discovery of the diffraction of X-rays by crystals, led to the powerful technology that we now enjoy. For about three quarters of a century molecular structure determination has been a driving force for crystallographic research, but now that the science has matured into a technology, interest is returning in trying to understand the nature of crystals themselves.

Fankuchen Award 2010

Jun 152010

Dr David Watkin, an Honorary Member of the BCA, has been awarded the 2010 Fankuchen Award by the American Crystallographic Association. The award recognizes contributions to crystallographic research by one who is known to be an effective teacher of crystallography.

The Award will be presented at the ACA Annual Meeting in New Orleans 2011 at which David will also be delivering a Plenary Lecture.

Handling Cell Errors in Crystallographic Data

Apr 152010

Cryst. Rev. (2010), 16(2), 133-144. [ doi:10.1080/08893110903483238 ]

Recent developments in crystallographic error analysis are described. This report provides an introduction to more-formal work, originally published in Ref. (Haestier, J., J. Appl. Cryst. 2009, 42, 798). Prior to the main discussion, a brief overview of the normal distribution and error-propagation is provided, with some simplified examples to demonstrate the effects of covariance terms on error calculations. A new method is described for absorbing the cell-parameter errors into the variance-covariance matrix of the refined parameters. Problems occur for monoclinic and triclinic cell settings as the crystallographer must ‘choose’ how errors on the cell angles affect the coordinates. The choice has no effect on error-calculations on the internal geometry (bond-lengths, angles and torsion angles) of the structure, but may introduce a bias if the errors are used as weights.

David Watkin gives the Kathleen Lonsdale Lecture

Apr 012009

David Watkin gives the Lonsdale Lecture

Every two years, the Young Crystallographers Group of the British Crystallographic Association nominate a speaker to give the prestigious Kathleen Lonsdale Lecture. Traditionally, they invite well respected scientist who has a good rapport with students. This year the Lonsdale Lecturer was David Watkin who is well known within the community, principally as a result of his involvement with the highly respected refinement software CRYSTALS, developed in Oxford and through the BCA biannual teaching school which he co-founded twenty-five years ago.

Structure Refinement: Some Background Theory and Practical Strategies

May 152008

J. Appl. Cryst. (2008), 41, 491-522. [ doi:10.1107/S0021889808007279 ]

Most modern small-molecule refinement programs are based on similar algorithms. Details of these methods are scattered through the literature, sometimes in books that are no longer in print and usually in mathematical detail that makes them unattractive to nonprogrammers. This paper aims to discuss these well established algorithms in nonmathematical language, with the intention of enabling crystallographers to use their favourite programs effectively.

Didcot Girls School Science Club

Oct 222004

$Andrew Cowley demonstrates the Nonius Kccd diffractometer to the Science Club. There is a second diffractometer behind the group.$

Figure 1: Andrew Cowley demonstrates the Nonius Kccd diffractometer to the Science Club. There is a second diffractometer behind the group

In October, Lynn Nickerson (Science Club Coordinator at Didcot Girls School) arranged for a small group to visit Chemical Crystallography in Oxford University’s new Chemistry Research Laboratory (Figure 1). The group was invited to bring some samples of common crystalline materials with them. The samples brought included cane sugar and citric acid (Figure 2). The girls used a polarising microscope to examine the crystals, and in the end selected an excellent crystal of citric acid for X-ray crystal structure determination. The crystal measured about 0.2 x 0.2 x 0.2 mm, and had to be ‘picked up’ on a fine nylon filament loop using a film of perfluoropolyether to hold it in place (Figure 3). The sample was put onto the Nonius kCCD automated diffractometer, cooled to -120°C and an X-ray diffraction image recorded (Figure 4). Dr Andrew Cowley collected a full data set in 40 minutes, which was processed by the Oxford crystallographic software CRYSTALS to reveal the structure of the acid (Figure 5 & 6). The hydrogen bonding network which holds the crystal together includes water of crystallisation, and is shown in Figure 7.