Official websites use .gov
A .gov website belongs to an official government organization in the United States.

Secure .gov websites use HTTPS
A lock ( ) or https:// means you’ve safely connected to the .gov website. Share sensitive information only on official, secure websites.

Engineering Laboratory

Materials and Structural Systems Division

GSAS Tutorial - Files

Leslie Struble (University of Illinois) and Paul Stutzman (National Institute of Standards and Technology)

Version 1 (March 2015)

Files

GSAS produces or uses a large number of files. All are stored in the folder in which you read or created the exp file. The more important files when using GSAS are described here. Most of this information is derived from the GSAS manual [4].

Experiment file—This is the main data and control file and has the extension .EXP. It includes the input and output of the refinement. A new file is generated for each refinement. That is, when the experiment file is opened by one of the routines in GSAS that is able to modify its contents, a new version is usually produced, and the next routine in GSAS to access the experiment file opens this new version. Earlier .EXP files are then renamed as .On, where n is a number that increases incrementally.
Powder or histogram file—This is the raw data for the refinement and has the extension .gsas. Routines such as CMPR are available to convert common XRD file formats (such as .gsa, .raw, or .fxye) into .gsas files.
Instrument parameter file—This is the set of instrument-dependent peak profile parameters and has the extension .PRM. It is possible to begin with generic parameters and then refine them using powder data for material with a well-defined crystal structure.
List or line printer output file—This is the output of the refinement and has the extension .lst. This file is updated during each refinement cycle. It includes the figure of merit (Χ²), the computed mass fraction of each phase, and the density of each phase. It is recommended that you view this output throughout the refinement process. You can open and view this using the Lstview tab in Expgui. The Lstview tab also provides a file trim option (file, trim *.lst) to retain only the most recent portions of the file, which will otherwise get quite long as a refinement proceeds.

Structure Data

The base file name key for phase groups and individual phases is provided in Table 1. The ZIP file, Cements_Data, should be unzipped in the PC C-drive for easy access. GSAS prefers folder names without spaces. The data (Table 1) are divided into phase groups in /Structures by format (.EXP, .CIF, .TBL). Within /EXP_1 folder are collections of phases grouped by type (alite, belite, aluminate, ferrite, oxides, alkali sulfates) as noted in Table 1. The file names for specific structures are provided in the fourth column, where the .TBL and .CIF files may be used to view the structure data for manual entry to gain experience in that process. Later, you may wish to read the data directly from the .EXP or .CIF files.

Table 1. GSAS experiment files for selected phase groups and individual structures.

Phase Groups	Phase	Reference	Filename
Alite.EXP	Triclinic	N. Golovastikov, R. Matveeva, N. Belov Kristallografiya, (1975) Vol. 20, pp. 721-729	TC3S1
	Monoclinic	F. Nishi, Y. Takeuchi, and I. Maki, Zeit. Krist., (1985)Vol. 172, No. 3-4, pp. 297-314	MC3S1
	Monoclinic (M1)	M.-N de Noirfontaine F. Dunstetter, M. Courtial, G. Gasecki, and M Signes-Frehel, Cem. Conc. Res., (2006) 36 54-64	ALITE_M1
	Monoclinic (M3)	M.-N de Noirfontaine F. Dunstetter, M. Courtial, G. Gasecki, and M Signes-Frehel, Cem. Conc. Res. (2006) 36 54-64	ALITE_M3
	Monoclinic	A.G. De La Torre, S. Bruque, J. Campo, and M.A.G. Aranda, Cem. & Conc. Res. (2002) 32, 1347-1356	MC3S3
	Monoclinic	W.G. Mumme, N. Jb. Miner. Mh., (1995) No. 4, pp. 145-160	MC3S4
	Rhombohedral	F. Nishi and Y. Takéuchi, Z>eit. Krist., (1984) 168, 197-212	RC3S1

Belite.EXP	Beta	K.H. Jost, B. Ziemer, and R. Seydel, Acta Cryst. (1977) B33, 1696-1700	BC2S3
	Beta	W.G. Mumme, R.J. Hill, G. Bushnell-Wye, and E.R. Segnit, Neues Jarb. Mineral. Abh. 169 (1995) 35-68	BC2S2
	Alpha	W. Eysel and T. Hahn, Zeit. Krist.,(1970) 131,322-341	AC2S3
	Alpha Prime, high	W.G. Mumme, R.J. Hill, G. Bushnell-Wye, and E.R. Segnit, Neues Jarb. Mineral. Abh. 169 (1995) 35-68	APHC2S
	Alpha Prime, low	A.M. Il'inets and M.Ya. Bikbau, Kristallografiya (1990) 35, 91-93	APLC2S1
	Gamma	S. Udagawa, K. Urabe, M Natsume, and T. Yano, Cem. and Conc. Res., (1980) Vol.10, No. 2, 139-144	GC2S2
	Gamma	D.K. Smith, A. Majumdar, and F. Ordway, Acta Cryst. (1965) Vol. 18, 787-795	GC2S3

Aluminate.EXP	Cubic	P.Mondal & J.W.Jeffery, Acta Cryst. (1975) B31, 689-697	CUBC3A1
	Cubic	Y. Takeuchi, F. Nishi and I Maki, Zeit. Krist. (1980) 152, 259-307	CUBC3A3
	Cubic	R. Berliner, C. Ball, and P.B. West, Cem. Conc. Res., (1997) Vol. 27, No. 4, pp. 551-575	CUBC3A2
	Orthorhombic	R. Berliner, C. Ball, and P.B. West, Cem. Conc. Res., (1997) Vol. 27, No. 4, pp. 551-575	C3AORT1
	Orthorhombic	Y. Takeuchi, F. Nishi and I Maki, Zeit. Krist. (1980) 152, 259-307	ORTC3A1
	Orthorhombic	F.Nishi and Y. Takéuchi, A>cta Cryst. (1975) B31, 1169-1173	ORTC3A2
	Orthorhombic	V.Kahlenberg R.X. Fischer, and C.S.J. Shaw, Am. Miner. (2000) Vol. 85, 1492	C4A3-1
	Monoclinic	Y. Takéuchi, F>. Nishi, and I. Maki, Zeit. Krist. (1980) 152, 259-307	MC3A1
	Monoclinic	Y. Takéuchi, F>. Nishi, and I. Maki, Zeit. Krist. (1980) 152, 259-307	MC3A2

Ferrite.EXP	Orthorhombic	A.A. Colville and S. Geller, Acta Cryst. (1972) B28, 3196-3200	C4AF4
Ferrite.EXP	Orthorhombic	R. Berliner, C. Ball, and P.B. West, Cem. Conc. Res., (1997) Vol. 27, No. 4, pp. 551-575	C4AF

AlkaliSulfate.EXP	Arcanite, beta	J.A. McGinnety, Acta Cryst. B28, (1972) 2845 -2852	K2SO4B1
	Arcanite, beta	M.T. Robinson, J. Phys. Chem., (1958) 62, 925-928	K2SO4B2
	Arcanite, beta	R.W.G. Wyckoff, Crystal Structures, Wiley, 1963	K2SO4B3
	Arcanite, alpha	A.J. van den Berg and F. Tunistra, Acta Cryst. (1978) B34, 3177-3181	K2SO4A1
	Aphthitalite	K. Okada and J. Ossaka, Acta Cryst. (1980) B36, 919-921	APHTHI1
	Aphthitalite	K. Okada and J. Ossaka, Acta Cryst. (1980) B36, 919-921	APHTHI2
	Langbeinite	R.W.G. Wyckoff, Crystal Structures, Wiley, 1963	LANG1
	Metathenardite	W.Eysel, H.H. Höfer, K>.L. Keester, and Th. Hahn, Acta Cryst. (1985) B41, 5-11	METATH1

CalciumSulfate.EXP	Gypsum	M. Atoji and R.E. Rundle, J. Chem. Phys. (1958) Vol. 29, No. 6, 1306	GYPSUM1
	Gypsum	B.F. Pedersen and D. Semmingsen, Acta Cryst. (1982) B38, 1074-1077	GYPSUM2
	Gypsum	W.F. Cole and C.J. Lancucki, Acta Cryst. (1974) B30, 921-929	GYPSUM3
	Anhydrite	A. Kirfel and G. Will, Acta Cryst. (1980), B36, 2881-2890	ANH1
	Anhydrite	F.C. Hawthrone and R.B. Ferguson, Canadian Miner. (1975), V.13, 289-292	ANH2
	Anhydrite	H. Morikawa, I. Minato, T. Tomita, and S. Iwai, Acta Cryst. B31, (1975), 2164-2165	ANH4
	Soluble Anhydrite	C. Bezou, A. Nonat, and J. –C. Mutin, Journal Solid State Chem. (1995), 117, 165-176	ANH3
	Bassanite	P. Ballirano, A. Maras, S. Meloni, and R. Caminiti, Eur. Jour. Min. (2001), Vol 13, No. 5, 985-993	Bassanite1
	Bassanite	W. Abriel, R. Nesper, Zeit. Krist. (1993), 205, 99-113	Bassanite2

Ox_Si_Car.EXP	Periclase	R.W.G. Wyckoff, Crystal Structures, Wiley, 1963	Periclase
	Free Lime	R.W.G. Wyckoff, Crystal Structures, Wiley, 1963	Lime
	Quartz	G. Smith, L.E. Alexander, Acta Cryst, 16 (1963) p. 462-471	Quartz
	Calcite	S.A. Markgraf, R.J. Reeder, Am. Min. (1985) Vol. 70, pp. 590-600	Calcite
	Mg Calcite	P.L. Althoff, Am. Min. (1977) Vol. 62, pp. 772-83	MgCalcite
	Dolomite	P.L. Althoff, (1977) Am. Min. Vol. 62, pp. 772-83	OxCarSil (phase 5)

InternalStandard.EXP	Corundum	J. Lewis, D. Schwarzenbach,and H.D. Flack, Acta Cryst. (1982), (A38), 733-739	Corundum
	Rutile	E.P. Meagher and G.A. Lager, Can. Min., (1979), V. 17, pp. 77-85	Rutile
	Zincite	R.W.G. Wyckoff, Crystal Structures, Wiley, 1963	Zincite

Building materials and Building materials

Created May 16, 2014, Updated August 25, 2016