7.10 Coupled-Cluster Excited-State and Open-Shell Methods 7.10.24 Active-Space EOM-CC(2,3): Tricks of the Trade (CCMAN only)7.10.26 Non-Iterative Triples Corrections to EOM-CCSD and CCSD

7.10.25 Job Control for EOM-CC(2,3)

(September 1, 2024)

EOM-CC(2,3) is invoked by METHOD=EOM-CC(2,3). The following options are available:

EOM_PRECONV_SD

EOM_PRECONV_SD
       Solves the EOM-CCSD equations, prints energies, then uses EOM-CCSD vectors as initial vectors in EOM-CC(2,3). Very convenient for calculations using energy additivity schemes.
TYPE:
       INTEGER
DEFAULT:
       0
OPTIONS:
       $n$ Do $n$ SD iterations
RECOMMENDATION:
       Turning this option on is recommended

CC_REST_AMPL

CC_REST_AMPL
       Forces the integrals, $T$ , and $R$ amplitudes to be determined in the full space even though the CC_REST_OCC and CC_REST_VIR keywords are used.
TYPE:
       LOGICAL
DEFAULT:
       TRUE
OPTIONS:
       FALSE Do apply restrictions TRUE Do not apply restrictions
RECOMMENDATION:
       None

CC_REST_TRIPLES

CC_REST_TRIPLES
       Restricts $R_{3}$ amplitudes to the active space, i.e., one electron should be removed from the active occupied orbital and one electron should be added to the active virtual orbital.
TYPE:
       INTEGER
DEFAULT:
       1
OPTIONS:
       1 Applies the restrictions
RECOMMENDATION:
       None

CC_REST_OCC

CC_REST_OCC
       Sets the number of restricted occupied orbitals including frozen occupied orbitals.
TYPE:
       INTEGER
DEFAULT:
       0
OPTIONS:
       $n$ Restrict $n$ occupied orbitals.
RECOMMENDATION:
       None

CC_REST_VIR

CC_REST_VIR
       Sets the number of restricted virtual orbitals including frozen virtual orbitals.
TYPE:
       INTEGER
DEFAULT:
       0
OPTIONS:
       $n$ Restrict $n$ virtual orbitals.
RECOMMENDATION:
       None

To select the active space, orbitals can be reordered by specifying the new order in the $reorder_mosection. The section consists of two rows of numbers ( $\alpha$ and $\beta$ sets), starting from $1$ , and ending with $n$ , where $n$ is the number of the last orbital specified.

The following example $reorder_mo section shows orbitals 16 and 17 swapped for both $\alpha$ and $\beta$ electrons:

$reorder_mo
   1 2 3 4 5 6 7 8 9 10 11 12 13 14 15   17  16
   1 2 3 4 5 6 7 8 9 10 11 12 13 14 15   17  16
$end

7.10.25.1 Examples

Example 7.134 EOM-SF(2,3) calculations of methylene.

$molecule
   0 3
   C
   H 1 CH
   H 1 CH 2 HCH

   CH  = 1.07
   HCH = 111.0
$end

$rem
   METHOD             eom-cc(2,3)
   BASIS              6-31G
   SF_STATES          [2,0,0,2]
   N_FROZEN_CORE      1
   N_FROZEN_VIRTUAL   1
   EOM_PRECONV_SD     20 Get EOM-CCSD energies first (max_iter=20).
$end

Example 7.135 This is active-space EOM-SF(2,3) calculations for methane with an elongated CC bond. HF MOs should be reordered as specified in the $reorder_mosection such that active space for triples consists of sigma and sigma* orbitals.

$molecule
   0 3
   C
   H  1  CH
   H  1  CHX  2  HCH
   H  1  CH   2  HCH  3  A120
   H  1  CH   2  HCH  4  A120

   CH   = 1.086
   HCH  = 109.4712206
   A120 = 120.
   CHX  = 1.8
$end

$rem
   METHOD            eom-cc(2,3)
   BASIS             6-31G*
   SF_STATES         [1,0]
   N_FROZEN_CORE     1
   EOM_PRECONV_SD    20   does eom-ccsd first, max_iter=20
   CC_REST_TRIPLES   1   triples are restricted to the active space only
   CC_REST_AMPL      0   ccsd and eom singles and doubles are full-space
   CC_REST_OCC       4   specifies active space
   CC_REST_VIR       17  specifies active space
   PRINT_ORBITALS    10  (number of virtuals to print)
$end

$reorder_mo
   1 2 5 4 3
   1 2 3 4 5
$end

Example 7.136 EOM-IP-CC(2,3) calculation of three lowest electronic states of water cation.

$molecule
0 1
   H   0.774767     0.000000     0.458565
   O   0.000000     0.000000    -0.114641
   H  -0.774767     0.000000     0.458565
$end

$rem
   METHOD       eom-cc(2,3)
   BASIS        6-311G
   IP_STATES    [1,0,1,1]
$end

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7.10.25 Job Control for EOM-CC(2,3)

7.10.25.1 Examples