This lecture is intended for people who want to become independent self-user of the small or wide angle X-ray scattering (SAXS) instrument in the MRL X-Ray Lab. SAXS describes the analysis of any sample that has nanostructured (1-100nm) electron density fluctuations -- i.e., nanoparticles in solution, block co-polymers, ionic liquids, soft matter, etc. Typically nanoscale electron density variations arise as structured (nanoscale object in a lattice), unstructured (in solution), or oriented (fiber or affixed to substrate) therefore treatment of each type of sample is on a case by case basis.
Students must also attend SAXSLAB instrument specific training course to learn how to put the knowledge obtained in the lecture to practice.
This lecture will survey the fundamentals of small angle X-ray scattering (SAXS), focusing on the bare essentials required to productively collect and analyze SAXS data. In addition to theory, this lecture will cover practical considerations such as common sources of error and a guide to structural interpretation and justification using SAXS patterns.
CHARACTERIZATION.nano
This lecture is intended for people who want to become independent self-user of the small or wide angle X-ray scattering (SAXS) instrument in the MRL X-Ray Lab. SAXS describes the analysis of any sample that has nanostructured (1-100nm) electron density fluctuations -- i.e., nanoparticles in solution, block co-polymers, ionic liquids, soft matter, etc. Typically nanoscale electron density variations arise as structured (nanoscale object in a lattice), unstructured (in solution), or oriented (fiber or affixed to substrate) therefore treatment of each type of sample is on a case by case basis.
Students must also attend SAXSLAB instrument specific training course to learn how to put the knowledge obtained in the lecture to practice.
This lecture will survey the fundamentals of small angle X-ray scattering (SAXS), focusing on the bare essentials required to productively collect and analyze SAXS data. In addition to theory, this lecture will cover practical considerations such as common sources of error and a guide to structural interpretation and justification using SAXS patterns.
This instrument training will teach users how to use the Multiwire Back-Reflection Laue Diffractometer to determine the orientation of single crystals and to determine if single crystals are possibly twinned.
This instrument training will teach users how to use the Multiwire Back-Reflection Laue Diffractometer to determine the orientation of single crystals and to determine if single crystals are possibly twinned.
This instrument training will teach users how to use the Multiwire Back-Reflection Laue Diffractometer to determine the orientation of single crystals and to determine if single crystals are possibly twinned.
This course will consist of a lecture teaching the basic principals of XRF analysis and hands-on training how to use the handheld XRF spectrometer and data analysis software to determine the elemental composition of samples.
This course will consist of a lecture teaching the basic principals of XRF analysis and hands-on training how to use the handheld XRF spectrometer and data analysis software to determine the elemental composition of samples.
This course will consist of a lecture teaching the basic principals of XRF analysis and hands-on training how to use the handheld XRF spectrometer and data analysis software to determine the elemental composition of samples.
This course is intended to provide users with practical examples of fitting SAXS data with SASview software.
Since most SAXS profiles do not exhibit well defined peaks like crystalline diffraction but instead characteristic "slopes," it is a heavily model-dependent method. After proper data reduction of a SAXS patterns, the data interpretation methods include extracting structural information from standardized plots such as Guinier, Porod, Kratky and Zimm plots. Elements of SAXS data modeling include calculations of the radius of gyration, of the single-particle form factor, inter-particle structure factors and the modeling effects of polydispersity.
This course is intended to provide users with practical examples of fitting SAXS data with SASview software.
Since most SAXS profiles do not exhibit well defined peaks like crystalline diffraction but instead characteristic "slopes," it is a heavily model-dependent method. After proper data reduction of a SAXS patterns, the data interpretation methods include extracting structural information from standardized plots such as Guinier, Porod, Kratky and Zimm plots. Elements of SAXS data modeling include calculations of the radius of gyration, of the single-particle form factor, inter-particle structure factors and the modeling effects of polydispersity.