# Basis sets

## Overview

NWChem currently supports basis sets consisting of generally contracted
Cartesian Gaussian functions up to a maximum angular momentum of six (*h*
functions), and also *sp* (or L) functions. The BASIS directive is used to
define these, and also to specify use of an [Effective Core
Potential](ECP) that is associated with a
basis set.

The basis functions to be used for a given calculation can be drawn from
a standard set in the [Basis set
library](#basis-set-library) that is included in the release
of NWChem. Alternatively, the user can specify particular functions
explicitly in the input, to define a particular basis set.

## BASIS directive

The general form of the BASIS directive is as follows:
```
 BASIS [<string name default "ao basis">] \  
       [(spherical || cartesian) default cartesian] \  
       [(print || noprint) default print]  \
       [rel] [bse] 
    <string tag> library [<string tag_in_lib>] \  
                 <string standard_set> [file <filename>] \  
                 [except <string tag list>] [rel]  
       ...  
    <string tag> <string shell_type> [rel]  
       <real exponent> <real list_of_coefficients>  
       ...  
 END
```
The following sections examine the keywords on the first line of the `BASIS` directive:

### Basis set NAME
 `NAME` :    
    By default, the basis set is stored in the database with the name
    "ao basis". Another name may be specified in the BASIS directive,
    thus, multiple basis sets may be stored simultaneously in the
    database. Also, the
    [DFT](Density-Functional-Theory-for-Molecules)
    and [RI-MP2](MP2) modules and the
    [Dyall-modified-Dirac](Relativistic-All-electron-Approximations#dyalls-modified-dirac-hamitonian-approximation)
    relativistic method require multiple basis sets with specific names.
    The user can associate the "ao basis" with another named basis using
    the SET directive (see [SET](Top-level#SET)).

### SPHERICAL or CARTESIAN
  `SPHERICAL` || `CARTESIAN` :   
    The keywords `spherical` and `cartesian` offer the option of using
    either spherical-harmonic (5 *d*, 7 *f*, 9 *g*, ...) or Cartesian (6 *d*, 10
    *f*, 15 *g*, ...) angular functions. The default is Cartesian. Note that
    the correlation-consistent basis sets were designed using spherical
    harmonics and to use these, the `spherical` keyword should be present
    in the `BASIS` directive. The use of spherical functions also helps
    eliminate problems with linear dependence.

|    | Cartesian       | Spherical                                             |
|----|-----------------|-------------------------------------------------------|
| 1  | s               | s                                                     |
| 1  | p<sub>x</sub>   | p<sub>x</sub>                                         |
| 2  | p<sub>y</sub>   | p<sub>y</sub>                                         |
| 3  | p<sub>z</sub>   | p<sub>z</sub>                                         |
| 1  | d<sub>xx</sub>  | d<sub>xy</sub>                                        |
| 2  | d<sub>xy</sub>  | d<sub>yz</sub>                                        |
| 3  | d<sub>xz</sub>  | d<sub>z<sup>2</sup>-x<sup>2</sup>-y<sup>2</sup></sub> |
| 4  | d<sub>yy</sub>  | d<sub>xz</sub>                                        |
| 5  | d<sub>yz</sub>  | d<sub>x<sup>2</sup>-y<sup>2</sup></sub>               |
| 6  | d<sub>zz</sub>  |                                                       |
| 1  | f<sub>xxx</sub> | f<sub>xxy-yyy</sub>                                   |
| 2  | f<sub>xxy</sub> | f<sub>xyz</sub>                                       |
| 3  | f<sub>xxz</sub> | f<sub>yzz-xxy-yyy</sub>                               |
| 4  | f<sub>xyy</sub> | f<sub>zzz-xxz-yyz</sub>                               |
| 5  | f<sub>xyz</sub> | f<sub>-xzz+xxx+xyy</sub>                              |
| 6  | f<sub>xzz</sub> | f<sub>xxz-yyz</sub>                                   |
| 7  | f<sub>yyy</sub> | f<sub>xyy-xxx</sub>                                   |
| 8  | f<sub>yyz</sub> |                                                       |
| 9  | f<sub>yzz</sub> |                                                       |
| 10 | f<sub>zzz</sub> |                                                       |
 
Order of functions.  
<br>
  
### PRINT keyword
  `PRINT` or `NOPRINT` :  
    The default is for the input module to print all basis sets
    encountered. Specifying the keyword noprint allows the user to
    suppress this output.

### REL keyword
  `REL` :  
    This keyword marks the entire basis as a relativistic basis for the
    purposes of the Dyall-modified-Dirac relativistic integral code. The
    marking of the basis set is necessary for the code to make the
    proper association between the relativistic shells in the ao basis
    and the shells in the large and/or small component basis. This is
    only necessary for basis sets which are to be used as the ao basis.
    The user is referred to the section on [Dyall's modified
    Dirac-Hamiltonian
    approximation](Relativistic-All-electron-Approximations#dyalls-modified-dirac-hamitonian-approximation)
    for more details.

### BSE keyword
  `BSE` **_New in NWChem 7.2.0_**:  
    This keyword loads the basis set [library](#basis-set-library) using data in `$NWCHEM_TOP/src/basis/libraries.bse`
    from [basisetexchanger.org](#how-to-use-basis-files-from-httpswwwbasissetexchangeorg-new-in-2019).
    CAVEAT: use of this keyword will also use the
    [spherical/cartesian](#spherical-or-cartesian)
    keywords from the basis library files.

## Basis sets tags

Basis sets are associated with centers by using the tag of a center in a
[geometry](Geometry) that has either been input by
the user or is available elsewhere. Each atom or center with the same
tag will have the same basis set. All atoms must have basis functions
assigned to them -- only dummy centers (`X` or `Bq`) may have no basis
functions. To facilitate the specification of the geometry and the basis
set for any chemical system, the matching process of a basis set tag to
a geometry tag first looks for an exact match. If no match is found,
NWChem will attempt to match, ignoring case, the name or symbol of the
element. E.g., all hydrogen atoms in a system could be labeled "`H1`",
"`H2`", ..., in the geometry but only one basis set specification for "`H`"
or "`hydrogen`" is necessary. If desired, a special basis may be added to
one or more centers (e.g., "`H1`") by providing a basis for that tag. If
the matching mechanism fails then NWChem stops with an appropriate error
message.

A special set of tags, "`*`" and tags ending with a "`*`" (E.g. "`H*`") can
be used in combination with the keyword
[library](#basis-set-library). These tags facilitate the
definition of a certain type of basis set of all atoms, or a group of
atoms, in a geometry using only a single or very few basis set entries.
The "`*`" tag will not place basis sets on dummy atoms, `Bq*` can be used
for that if necessary.

Examined next is how to reference standard basis sets in the basis set
library, and finally, how to define a basis set using exponents and
coefficients.

## Basis set library

The keyword `library` associated with each specific tag entry specifies
that the calculation will use the standard basis set in NWChem for that
center. The string `<standard_set>` is the name that identifies the
functions in the library. The names of standard basis sets are not case
sensitive. For a complete list of basis sets and associated ECPs in the
NWChem library see the [available basis
sets](AvailableBasisSets) or the [Basis Set
Exchange](https://www.basissetexchange.org/) for naming conventions and
their specifications.

The general form of the input line requesting basis sets from the NWChem
basis set library is:
```
    <string tag> library [<string tag_in_lib>] \  
                 <string standard set> [file < filename> \  
                 [except <string tag list>] [rel] 
       ...
```
For example, the NWChem basis set library contains the Dunning cc-pvdz
basis set. These may be used as follows
```
 basis  
   oxygen library cc-pvdz  
   hydrogen library cc-pvdz  
 end
```
A default path of the NWChem basis set libraries is provided on
installation of the code, but a different path can be defined by
specifying the keyword file, and one can explicitly name the file to be
accessed for the basis functions. For example,
```
 basis 
   o  library 3-21g file /usr/d3g681/nwchem/library 
   si library 6-31g file /usr/d3g681/nwchem/libraries/  
 end
```
This directive tells the code to use the basis set 3-21g in the file
/usr/d3g681/nwchem/library for atom o and to use the basis set 6-31g in
the directory /usr/d3g681/nwchem/libraries/ for atom si, rather than
look for them in the default libraries. When a directory is defined the
code will search for the basis set in a file with the name 6-31g.

The "`*`" tag can be used to efficiently define basis set input
directives for large numbers of atoms. An example is:
```
 basis  
   *  library 3-21g 
 end
```
This directive tells the code to assign the basis sets 3-21g to all the
atom tags defined in the geometry. If one wants to place a different
basis set on one of the atoms defined in the geometry, the following
directive can be used:
```
 basis  
   *  library 3-21g except H 
 end
```
This directive tells the code to assign the basis sets 3-21g to all the
atoms in the geometry, except the hydrogen atoms. Remember that the user
will have to explicitly define the hydrogen basis set in this
directive! One may also define tags that end with a "`*`":
```
 basis  
   oxy*  library 3-21g   
 end
```
This directive tells the code to assign the basis sets 3-21g to all atom
tags in the geometry that start with "`oxy`".

If standard basis sets are to be placed upon a dummy center, the
variable `<tag_in_lib>` must also be entered on this line, to identify the
correct atom type to use from the basis function library (see the ghost
atom example in [SET](Top-level#SET) and below).
For example: To specify the cc-pvdz basis for a calculation on the water
monomer in the dimer basis, where the dummy oxygen and dummy hydrogen
centers have been identified as `bqo` and `bqh` respectively, the `BASIS`
directive is as follows:
```
 basis  
   o   library cc-pvdz  
   h   library cc-pvdz  
   bqo library o cc-pvdz  
   bqh library h cc-pvdz  
 end
```
A special dummy center tag is `bq*`, which will assign the same basis set
to all bq centers in the geometry. Just as with the `*` tag, the except
list can be used to assign basis sets to unique dummy centers.

The library basis sets can also be marked as relativistic by adding the
`rel` keyword to the tag line. See the section on [relativistic
all-electron
approximations](Relativistic-All-electron-Approximations)
 for more details. The correlation consistent basis sets have been
contracted for relativistic effects and are included in the standard
library.

There are also contractions in the standard library for both a point
nucleus and a finite nucleus of Gaussian shape. These are usually
distinguished by the suffix `_pt` and `_fi`. It is the user's
responsibility to ensure that the contraction matches the nuclear type
specified in the geometry object. The specification of a finite nucleus
basis set does NOT automatically set the nuclear type for that atom to
be finite. See [Geometries](Geometry) for
information.
## How to use basis files from https://www.basissetexchange.org (NEW in 2019)

In order to ensure compatibility with the existing basis libraries available in NWChem, we suggest the user  to 
select the "Advanced Options" menu and tick the boxes "Optimize General Contractions" and "Uncontract General",
as in the image below,
when downloading basis files from [www.basissetexchange.org](https://www.basissetexchange.org)  
![How to download](BSE_NWChem_selection.png)

As an alternative,  basis set files downloaded from the basissetexchange.org website are available in
the NWChem source code (after release 7.0.0). In order to switch from the default basis libraries to the library formed by files downloaded from [www.basissetexchange.org](https://www.basissetexchange.org),
the following environment variable setting is required
```
NWCHEM_BASIS_LIBRARY=$NWCHEM_TOP/src/basis/libraries.bse/
```
## Explicit basis set definition

If the basis sets in the library or available in other external files
are not suitable for a given calculation, the basis set may be
explicitly defined. A generally contracted Gaussian basis function is
associated with a center using an input line of the following form:
```
    <string tag> <string shell_type> [rel]  
       <real exponent> <real list_of_coefficients>  
       ...
```
The variable <shell_type> identifies the angular momentum of the shell,
*s*, *p*, *d*, .... NWChem is configured to handle up to *h* shells. The
keyword `rel` marks the shell as relativistic -- see the Section  on [relativistic
all-electron
approximations](Relativistic-All-electron-Approximations) for more
details. Subsequent lines define the primitive function exponents and
contraction coefficients. General contractions are specified by
including multiple columns of coefficients.

The following example defines basis sets for the water molecule:
```
 basis spherical   
   oxygen s  
     11720.0000    0.000710  -0.000160  
      1759.0000    0.005470  -0.001263  
       400.8000    0.027837  -0.006267  
       113.7000    0.104800  -0.025716  
        37.0300    0.283062  -0.070924  
        13.2700    0.448719  -0.165411  
         5.0250    0.270952  -0.116955  
         1.0130    0.015458   0.557368  
         0.3023   -0.002585   0.572759  
   oxygen s                  
         0.3023    1.000000  
   oxygen p                  
        17.7000    0.043018  
         3.8540    0.228913  
         1.0460    0.508728  
         0.2753    0.460531  
   oxygen p                  
         0.2753    1.000000  
   oxygen d  
         1.1850    1.000000  
   hydrogen s  
        13.0100    0.019685  
         1.9620    0.137977  
         0.4446    0.478148  
         0.1220    0.501240  
   hydrogen s    
         0.1220    1.000000  
   hydrogen p    
         0.7270    1.000000  
   oxygen s  
         0.01      1.0  
   hydrogen s  
         0.02974   1.0  
   hydrogen p  
         0.141      1.0  
 end
```
Explicit basis set specifications are available from the [basis set
exchange](https://www.basissetexchange.org/). 

## Combinations of library and explicit basis set input

The user can use a mixture of library basis and explicit basis set input
to define the basis sets used on the various atoms.

For example, the following `BASIS` directive augments the Dunning cc-pvdz
basis set for the water molecule with a diffuse s-shell on oxygen and
adds the aug-cc-pVDZ diffuse functions onto the hydrogen.
```
 basis spherical   
   oxygen library cc-pvdz  
   hydrogen library cc-pvdz  
   oxygen s  
     0.01 1.0  
   hydrogen library "aug-cc-pVDZ Diffuse"  
 end
```
The resulting basis set defined is identical to the one defined above in
the explicit basis set input.