The surface data may be generated from a Gaussian checkpoint file or be read in from a cube file. Note that there are two steps involved in actually displaying a surface: Obtaining a cube by generating it or reading it in. Generating the actual surface for display.
- Read Checkpoint File Gaussian System
- Gaussian Read Checkpoint File
- Read Checkpoint File Gaussian Tool
- Read Checkpoint File Gaussian Pdf
- Read Checkpoint File Gaussian Tool
The newzmat utility was designed primarily for converting molecule specifications between a variety of standard formats. It can also perform many related functions, such as extracting molecule specifications from Gaussian checkpoint files. Its full set of capabilities includes the following:
newzmat can convert molecule specifications between a variety of data file formats. This includes generating a Z-matrix (and hence input for Gaussian) from the files produced by other programs and also converting between the file formats of any of these programs. newzmat can thus be used to produce Gaussian input from the data files of many popular graphics and mechanics packages, allowing them to act as graphical input front-ends to Gaussian. The resulting data files have the proper symmetry constraints for efficient computation (if applicable).
newzmat can also generate Gaussian 03 checkpoint files from other data files, and (more importantly) generate the data files from checkpoint files. This capability can be used to extract data for display with a visualization package.
newzmat can retrieve intermediate structures from a checkpoint file from (or during) a geometry optimization, for reuse or display.
Command Syntax
- 3) Request the density of the Nth state of interest to be recovered from the checkpoint file with the following route section: # TD(Read,Root=N) LOT Density=Current Guess=Read Geom=AllCheck. Replace N for the Nth state which caught your eye in step number 2) and LOT for the Level of Theory you've been using in the previous steps.
- Aug 14, 2016 Locating the Read-Write File for a Job. If you did not use%RWF in the original interrupted job to name a read-write file, then you may be able to find the read-write file in the Gaussian scratch directory (specified by the GAUSSSCRDIR environment variable). It will have the default name assigned by Gaussian, which is of the form Gau.
- In link101 the program reads in or retrieves from the checkpoint file the structure of the system together with other parameters and prints the structure (in a slightly modified format) together with overall charge and spin multiplicity and the comments supplied in the input file.
newzmat has the following general syntax:
newzmatoption(s) input-fileoutput-file
where option(s) is one or more options, specifying the desired operations, input-file is the file containing the structure to be converted (or retrieved), and output-file is the file in which to place the new molecule specification (or Gaussian input). Either filename may be replaced by a hyphen to denote standard input or standard output, as appropriate.
If the output filename is omitted, it is given the same base name as the input file, along with a conventional extension denoting its file type. In general, extensions can be omitted from file specifications provided that extension conventions are followed. The default extensions are listed in the following table:
| Extension | Description | OptionForm |
| .bgf | Biograf internal data file | bgf |
| .cac | CaChe molecule file | cache |
| .chk | Gaussian 03 checkpoint file | chk |
| .com | Gaussian input file (Z-matrix mol. spec.) | zmat |
| .com | Gaussian input file (Cart. coords. mol. spec.) | cart |
| .con | QUIPU system data file | con |
| .dat | Model/XModel/MM2 data file | model |
| .dat | MacroModel data file (may be formatted or unformatted) | mmodel, ummodel |
| .ent | Brookhaven data file (equiv. to PDB) | ent |
| .com | Fractional coords. for crystal structures (requires exactly 3 trans. ops.) | fract |
| .inp | MOPAC input file | mopac |
| .pdb | Protein Data Bank format (equiv. to Brookhaven) | pdb |
| .ppp | Some PPP program (output only) | ppp |
| .xyz | Unadorned Cartesian coordinates | xyz |
| .zin | Ancient version of ZINDO | zindo |
Input and Output Options
The options specifying the formats of the input and output molecule specifications are formed from the string -i or -o (respectively), followed immediately by the appropriate option form string from the preceding table corresponding to the desired molecule specification format (no spaces intervene). For example, -ipdb indicates that the input molecule specification is in PDB format and that the extension .pdb should be applied to the input filename if no extension is specified. Similarly, -oxyz specifies an output format of cartesian coordinates along with a default extension of .xyz for the output filename. The default input and output options are -izmat and -ozmat. Note that -izmat and -icart are synonyms, and either one of them can read a Gaussian input file containing any molecule specification format: Z-matrix, Cartesian coordinates, or mixed internal and Cartesian coordinates.
Other Options Related to Input and Output
The following options further specify the input for newzmat:
-stepN
Use the structure from step N of the geometry optimization data in a Gaussian 03 checkpoint file (valid only for the -ichk input option).
This option is not available for optimizations in redundant internal coordinates (the default coordinate system). Instead, retrieve the structure from the checkpoint file in a subsequent job by using a route section containing Geom=(Check,Step=N).
-ubohr
Input distances in input file are specified in Bohr (the default is Angstroms).
Read Checkpoint File Gaussian System
-urad
Input angles in input stream are specified in radians (the default is degrees).
The following options further specify the output file format:
-mof1
Use macromodel format 1 (only valid with -ommodel).
-mof2
Use macromodel format 2 (this is default if -ommodel is specified).
-optprompt
Prompt for which parameters should be optimized; used when setting up a molecule specification destined for a geometry optimization and -ozmat is specified (or no output option is included). By default, all parameters not fixed by symmetry are optimized.
-prompt
Prompt for route section and title section lines and for the charge and multiplicity when using -ozmat (or no output option is specified). Gaussian input files produced by newzmat set up HF/6-31G(d) single point energy calculations by default.
Examples
The following command reads the molecule specification from the PDB file water.pdb and writes a Gaussian input file, including the equivalent Z-matrix, to the file h2o.com:
newzmat prompts for the charge and multiplicity for the Z-matrix since these items cannot be determined from the PDB file.
The following command reads the molecule specification from the Gaussian 03 checkpoint file G98-11234.chk and writes the PDB file propell.pdb:
The following command reads the molecule specification from step 5 of the optimization from the checkpoint file newopt.chk and produces the Mopac file step5.inp:
The following command prints the molecule specification found in the checkpoint file mystery.chk and displays it in Gaussian input file format on the terminal screen (assuming the command is executed interactively):
The following command creates the checkpoint file quick.chk from the Gaussian input file that the user types in interactively:
Note that the input file must end with a blank line.
The following command reads the molecule specification from the Mopac file newsalt.inp and writes a Gaussian input file including the equivalent Z-matrix to the file newsalt.com, prompting for the route and title sections and the charge and spin multiplicity for the molecule:
Selecting an Output Format
In order to communicate with a non-supported visualization system, the first choice of format to try is the PDB file. This format includes the connectivity information and is widely supported. Note that some software packages use the .ent extension, rather than .pdb; the -ient and -oent options select the former, while -ipdb and -opdb select the latter. Another commonly used alternative is the Mopac file format.
Other newzmat Options
The other options to newzmat are concerned with generating connectivity information, with the use of standard geometrical parameters, and with the determination and use of molecular symmetry. A complete connectivity table can be used to generate Z-matrix specifications suitable for inclusion of symmetry constraints. Such a table is also required for output of the data files for the molecular mechanics programs. If one of the input formats which includes full connectivity is used (e.g., MacroModel data files), the connectivity that it provides is used.
However, when Z-matrix or MOPAC format input is provided, only the connectivity information which is implied by the internal coordinate specification is available. Thus if a new Z-matrix which incorporates the molecular symmetry is to be generated, the remaining connectivity information must be generated. When cartesian coordinates are read in, naturally, no connectivity information is provided, so the default is to generate the table using the internally stored atomic radii. In addition, when used to generate input structures, the mechanics programs may not generate suitable bond distances and often produce coordinates which are close to but not exactly symmetric. Options control how each of these cases is handled.
-allbonded
In generating new connectivity information, assume all atoms are bonded.
-bmodel
Use standard model B bond lengths along with internal values in determining bond distances.
-densityN
Generate natural orbitals for density number N. This option is only useful if you are generating a CaChe file. N should be set to 0 for HF, to 2 for MP2, to 6 for CI, and to 7 for QCISD or CCD.
-fudge
Fudge bond distances to make sure they are reasonable, using internal values. This is the default for model input and is not applicable elsewhere.
-gencon
Generate connectivity information using internal radii.
-getfile
Insist on filename specifications for all arguments, making standard input and output unacceptable.
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Gaussian Read Checkpoint File
-lsymm
Use loose cutoffs for determining symmetry. This option implies -symav.
-mdensityM
Subtract generalized density M from that specified with -density to make a difference density, which is then converted to natural orbitals.
-nofudge
Do not fudge bond distances. This is the default and only choice for all cases except model input.
-nogetfile
Cancels -getfile.
-noround
Turns off rounding of Z-matrix parameters.
-nosymav
Turns off averaging of input coordinates.
Read Checkpoint File Gaussian Tool
-nosymm
Turns off all use of symmetry.
-order
Keeps the order of atoms as close as possible to the input order.
-round
Rounds Z-matrix parameters to 0.01 Å and 1 degree.
-symav
Average input coordinates using approximate symmetry operations to achieve exact symmetry.
-symm
Assign molecular symmetry.
-tsymm
Use tight cutoffs for determining symmetry. The option is the default.
-rebuildzmat
Build a new Z-matrix rather than using the read-in one (as would be the default for Z-matrix or MOPAC input). This option implies -gencon, and the option may be abbreviated as -redoz.
Read Checkpoint File Gaussian Pdf
Known Difficulties with newzmat
Read Checkpoint File Gaussian Tool
The symmetry averaging process, which guesses the intended symmetry given coordinates which are only approximately symmetric, does not always achieve the intended symmetry. It will take coordinates printed in a Gaussian output file to 6 digits and restore symmetry, and it will usually work given coordinates from molecular mechanics provided that the mechanics optimization was converged reasonably far. In generating coordinates with MacroModel, for example, it is sometimes necessary to do a final full Newton-Raphson step after the normal minimization.
newzmat computes the nuclear repulsion energy of the initial read-in structure and of the final structure as a consistency check. If these disagree, a warning is printed. Substantial disagreement indicates a failure of the program.
