From b519f4abd67bacef3f040132be22f30a82700703 Mon Sep 17 00:00:00 2001 From: caes Date: Fri, 14 Apr 2017 13:23:07 -0400 Subject: [PATCH] update --- adv_lab.bib | 4 ++++ xrd/report/report.tex | 17 ++++++++++++++++- 2 files changed, 20 insertions(+), 1 deletion(-) diff --git a/adv_lab.bib b/adv_lab.bib index 9a9910f..eb88860 100644 --- a/adv_lab.bib +++ b/adv_lab.bib @@ -1,3 +1,7 @@ +@online{fundcrystal, + author = {Cook, Joseph}, + } + @Misc{highscore, author = {PANalytical}, title = {HighScore Plus Version 4.5}, diff --git a/xrd/report/report.tex b/xrd/report/report.tex index 47c5773..6c629b8 100644 --- a/xrd/report/report.tex +++ b/xrd/report/report.tex @@ -101,7 +101,22 @@ Western Michigan University's new X-ray Diffractometer is used to probe four mat \end{tabular} \end{table} - The modern approach to analyzing materials by Bragg diffraction is to interpret the output as the reciprocal space representation of the lattice positions. An inverse Fourier transform then gives the the position distributions of the lattice. The HighScore Plus software, associated with the Empyrean XRD, is used to perform these operations. It generates a spacing constant in angstroms, which can be interpretted as the lattice constant for the cubic lattice. \cite{highscore} + The modern approach to analyzing materials by Bragg diffraction is to interpret the output as the reciprocal space representation of the lattice positions. An inverse Fourier transform then gives the positions that make the lattice. The HighScore Plus software, associated with the Empyrean XRD, is used to perform these operations. \cite{highscore} It computes a spacing constant in angstroms, which can be interpretted as the cubic lattice constant, and other quantities. + + + + + +\section{Computational Details} + \label{sec:compdets} + The phase of the X-rays are not known, so the program determines the phase by fitting predicted profiles. A background is determined using the minimum 2nd derivative method with ``bending factor'' = 5, ``granularity'' = 20, and using smoothed input data. Peaks are located with ``minimum significant'' = 10.00, ``minimum tip width'' = 0.01, ``maximum tip width'' = 1.00, and ``peak base width'' = 2.00. The program was able to identify the copper Bragg diffraction pattern, which was very prominent, seen in Figure~\ref{fig:cudiff}. + + + \begin{figure} + \centering + \includegraphics[width=4in]{} + \end{figure} + %─────────────