Advances in Patterson-function direct methods and recent applications
Institut de Cienca de Materials de Barcelona [ ICMAB ]
Mardi 08/04/2014, 14:30
LLB - Bât 563 p15 (Grande Salle), CEA-Saclay
Advances in Patterson-function direct methods and recent applications
for Powder & Single-Crystal Diffraction
Mardi 08 Avril 2014 à
Part I: 14h30 Séminaire
Part II : 16h30 Démonstration / Tutoriel de logiciels libres écrits par J.R.
Salle de conférence 15 – Bâtiment 563
Conventional direct methods are the simplest way of exploring the observed Patterson function in terms of
the phases. However, the close connection between direct methods and Patterson function had remained
hidden for many years probably due to the fact that individual phase relationships were used as starting point
in the development of direct methods. However, this connection became evident when it was demonstrated
that the incidence of the wrong uranium-atom solution in direct methods disappeared when the origin-peak
of the observed Patterson-type function was removed1. Further progress in Patterson-function direct methods
was later achieved by replacing the individual phase relationships by Fourier transforms, since the resulting
S-FFT algorithm was more accurate and less time consuming for large structures2. In 2011, it was shown
that S-FFT is especially well-suited for handling powder diffraction data according to a conceptually new
strategy called “Cluster-based Direct Methods” which allows the active use of high resolution powder
diffraction data during the phase refinement process3. A necessary preliminary step is the accurate
decomposition of the observed pattern in intensity clusters. In this way a number of new complex inorganic,
hybrid and even organic crystal structures have been routinely solved. More recently, further progress in
Patterson-function direct methods has been achieved by introducing the so called delta-recycling phase
refinement algorithm4. As the name indicates it is based on the properties of the delta function which allow
expressing the (electron) density function in an uncorrelated alternate manner and hence establishing a
phasing residual which can be minimized by means of the iterative delta-recycling algorithm4. This simple
procedure was worked out using single-crystal X-ray diffraction data. To test its phasing power when
intensity data are not ideal, delta recycling has been applied to electron diffraction data from nanovolumes
of some selected inorganic compounds5. The data used had been collected with the Automated Diffraction
Technique at the Univ. Mainz by Prof. Kolb’s group. Besides confirming the suitability of the delta
recycling algorithm, other important aspects like the accuracy of the intensity data and the effect of missing
reflections are also analyzed.
1 Acta Cryst (1993) A49, 406-409.
2 Acta Cryst (2007) A63, 131-134.
3 Acta Cryst (2011) A67, 63-67.
4 Acta Cryst (2012) A68, 77-81.
5 Acta Cryst (2013) A69, 396-407.