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@ -32,20 +32,20 @@ Description
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"""""""""""
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The *bop* pair style computes Bond-Order Potentials (BOP) based on
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quantum mechanical theory incorporating both :math:`\sigma` and :math:`\pi` bonding.
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By analytically deriving the BOP from quantum mechanical theory its
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transferability to different phases can approach that of quantum
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mechanical methods. This potential is similar to the original BOP
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developed by Pettifor (:ref:`Pettifor_1 <Pettifor_1>`,
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:ref:`Pettifor_2 <Pettifor_2>`, :ref:`Pettifor_3 <Pettifor_3>`) and later updated
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by Murdick, Zhou, and Ward (:ref:`Murdick <Murdick>`, :ref:`Ward <Ward>`).
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Currently, BOP potential files for these systems are provided with
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LAMMPS: AlCu, CCu, CdTe, CdTeSe, CdZnTe, CuH, GaAs. A system with
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only a subset of these elements, including a single element (e.g. C or
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Cu or Al or Ga or Zn or CdZn), can also be modeled by using the
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appropriate alloy file and assigning all atom types to the
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single element or subset of elements via the pair_coeff command, as
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discussed below.
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quantum mechanical theory incorporating both :math:`\sigma` and
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:math:`\pi` bonding. By analytically deriving the BOP from quantum
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mechanical theory its transferability to different phases can approach
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that of quantum mechanical methods. This potential is similar to the
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original BOP developed by Pettifor (:ref:`Pettifor_1 <Pettifor_1>`,
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:ref:`Pettifor_2 <Pettifor_2>`, :ref:`Pettifor_3 <Pettifor_3>`) and
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later updated by Murdick, Zhou, and Ward (:ref:`Murdick <Murdick>`,
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:ref:`Ward <Ward>`). Currently, BOP potential files for these systems
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are provided with LAMMPS: AlCu, CCu, CdTe, CdTeSe, CdZnTe, CuH, GaAs. A
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system with only a subset of these elements, including a single element
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(e.g. C or Cu or Al or Ga or Zn or CdZn), can also be modeled by using
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the appropriate alloy file and assigning all atom types to the single
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element or subset of elements via the :doc:`pair_coeff command
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<pair_coeff>`, as discussed below.
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The BOP potential consists of three terms:
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@ -58,7 +58,7 @@ representing the repulsion between a pair of ion cores,
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:math:`\beta_{\sigma,ij}(r_{ij})` and :math:`\beta_{\sigma,ij}(r_{ij})`
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are respectively sigma and :math:`\pi` bond integrals, :math:`\Theta_{\sigma,ij}`
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and :math:`\Theta_{\pi,ij}` are :math:`\sigma` and :math:`\pi`
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bond-orders, and U_prom is the promotion energy for sp-valent systems.
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bond-orders, and U\_prom is the promotion energy for sp-valent systems.
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The detailed formulas for this potential are given in Ward
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(:ref:`Ward <Ward>`); here we provide only a brief description.
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@ -96,7 +96,7 @@ length 4. This enables the incorporation of dihedral angles effects.
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.. note::
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Note that unlike for other potentials, cutoffs for BOP
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potentials are not set in the pair_style or pair_coeff command; they
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potentials are not set in the pair\_style or pair\_coeff command; they
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are specified in the BOP potential files themselves. Likewise, the
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BOP potential files list atomic masses; thus you do not need to use
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the :doc:`mass <mass>` command to specify them. Note that for BOP
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@ -106,7 +106,7 @@ length 4. This enables the incorporation of dihedral angles effects.
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:doc:`pair_coeff <pair_coeff>` command to read the BOP potential
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file.
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One option can be specified as a keyword with the pair_style command.
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One option can be specified as a keyword with the pair\_style command.
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The *save* keyword gives you the option to calculate in advance and
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store a set of distances, angles, and derivatives of angles. The
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@ -118,10 +118,10 @@ system configuration.
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----------
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Only a single pair_coeff command is used with the *bop* style which
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Only a single pair\_coeff command is used with the *bop* style which
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specifies a BOP potential file, with parameters for all needed
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elements. These are mapped to LAMMPS atom types by specifying
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N additional arguments after the filename in the pair_coeff command,
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N additional arguments after the filename in the pair\_coeff command,
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where N is the number of LAMMPS atom types:
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* filename
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@ -130,7 +130,7 @@ where N is the number of LAMMPS atom types:
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As an example, imagine the CdTe.bop file has BOP values for Cd
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and Te. If your LAMMPS simulation has 4 atoms types and you want the
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first 3 to be Cd, and the fourth to be Te, you would use the following
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pair_coeff command:
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pair\_coeff command:
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.. code-block:: LAMMPS
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@ -143,8 +143,8 @@ element in the BOP file. The final Te argument maps LAMMPS atom type
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BOP files in the *potentials* directory of the LAMMPS distribution
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have a ".bop" suffix. The potentials are in tabulated form containing
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pre-tabulated pair functions for phi_ij(r_ij), beta_(sigma,ij)(r_ij),
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and beta_pi,ij)(r_ij).
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pre-tabulated pair functions for phi\_ij(r\_ij), beta\_(sigma,ij)(r\_ij),
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and beta\_pi,ij)(r\_ij).
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The parameters/coefficients format for the different kinds of BOP
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files are given below with variables matching the formulation of Ward
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@ -170,89 +170,89 @@ the tabulated functions are given.
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* Line 1: nr, nBOt (nr is the number of divisions the radius is broken
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into for function tables and MUST be a factor of 5; nBOt is the number
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of divisions for the tabulated values of THETA_(S,ij)
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* Line 2: delta_1-delta_7 (if all are not used in the particular
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of divisions for the tabulated values of THETA\_(S,ij)
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* Line 2: delta\_1-delta\_7 (if all are not used in the particular
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* formulation, set unused values to 0.0)
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Following this N lines for e_1-e_N containing p_pi.
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Following this N lines for e\_1-e\_N containing p\_pi.
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* Line 3: p_pi (for e_1)
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* Line 4: p_pi (for e_2 and continues to e_N)
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* Line 3: p\_pi (for e\_1)
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* Line 4: p\_pi (for e\_2 and continues to e\_N)
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The next section contains several pair constants for the number of
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interaction types e_i-e_j, with i=1->N, j=i->N
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interaction types e\_i-e\_j, with i=1->N, j=i->N
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* Line 1: r_cut (for e_1-e_1 interactions)
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* Line 2: c_sigma, a_sigma, c_pi, a_pi
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* Line 3: delta_sigma, delta_pi
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* Line 4: f_sigma, k_sigma, delta_3 (This delta_3 is similar to that of
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* Line 1: r\_cut (for e\_1-e\_1 interactions)
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* Line 2: c\_sigma, a\_sigma, c\_pi, a\_pi
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* Line 3: delta\_sigma, delta\_pi
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* Line 4: f\_sigma, k\_sigma, delta\_3 (This delta\_3 is similar to that of
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the previous section but is interaction type dependent)
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The next section contains a line for each three body interaction type
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e_j-e_i-e_k with i=0->N, j=0->N, k=j->N
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e\_j-e\_i-e\_k with i=0->N, j=0->N, k=j->N
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* Line 1: g_(sigma0), g_(sigma1), g_(sigma2) (These are coefficients for
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g_(sigma,jik)(THETA_ijk) for e_1-e_1-e_1 interaction. :ref:`Ward <Ward>`
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* Line 1: g\_(sigma0), g\_(sigma1), g\_(sigma2) (These are coefficients for
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g\_(sigma,jik)(THETA\_ijk) for e\_1-e\_1-e\_1 interaction. :ref:`Ward <Ward>`
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contains the full expressions for the constants as functions of
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b_(sigma,ijk), p_(sigma,ijk), u_(sigma,ijk))
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* Line 2: g_(sigma0), g_(sigma1), g_(sigma2) (for e_1-e_1-e_2)
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b\_(sigma,ijk), p\_(sigma,ijk), u\_(sigma,ijk))
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* Line 2: g\_(sigma0), g\_(sigma1), g\_(sigma2) (for e\_1-e\_1-e\_2)
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The next section contains a block for each interaction type for the
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phi_ij(r_ij). Each block has nr entries with 5 entries per line.
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phi\_ij(r\_ij). Each block has nr entries with 5 entries per line.
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* Line 1: phi(r1), phi(r2), phi(r3), phi(r4), phi(r5) (for the e_1-e_1
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* Line 1: phi(r1), phi(r2), phi(r3), phi(r4), phi(r5) (for the e\_1-e\_1
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interaction type)
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* Line 2: phi(r6), phi(r7), phi(r8), phi(r9), phi(r10) (this continues
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until nr)
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* ...
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* Line nr/5_1: phi(r1), phi(r2), phi(r3), phi(r4), phi(r5), (for the
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e_1-e_1 interaction type)
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* Line nr/5\_1: phi(r1), phi(r2), phi(r3), phi(r4), phi(r5), (for the
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e\_1-e\_1 interaction type)
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The next section contains a block for each interaction type for the
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beta_(sigma,ij)(r_ij). Each block has nr entries with 5 entries per
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beta\_(sigma,ij)(r\_ij). Each block has nr entries with 5 entries per
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line.
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* Line 1: beta_sigma(r1), beta_sigma(r2), beta_sigma(r3), beta_sigma(r4),
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beta_sigma(r5) (for the e_1-e_1 interaction type)
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* Line 2: beta_sigma(r6), beta_sigma(r7), beta_sigma(r8), beta_sigma(r9),
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beta_sigma(r10) (this continues until nr)
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* Line 1: beta\_sigma(r1), beta\_sigma(r2), beta\_sigma(r3), beta\_sigma(r4),
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beta\_sigma(r5) (for the e\_1-e\_1 interaction type)
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* Line 2: beta\_sigma(r6), beta\_sigma(r7), beta\_sigma(r8), beta\_sigma(r9),
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beta\_sigma(r10) (this continues until nr)
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* ...
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* Line nr/5+1: beta_sigma(r1), beta_sigma(r2), beta_sigma(r3),
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beta_sigma(r4), beta_sigma(r5) (for the e_1-e_2 interaction type)
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* Line nr/5+1: beta\_sigma(r1), beta\_sigma(r2), beta\_sigma(r3),
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beta\_sigma(r4), beta\_sigma(r5) (for the e\_1-e\_2 interaction type)
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The next section contains a block for each interaction type for
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beta_(pi,ij)(r_ij). Each block has nr entries with 5 entries per line.
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beta\_(pi,ij)(r\_ij). Each block has nr entries with 5 entries per line.
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* Line 1: beta_pi(r1), beta_pi(r2), beta_pi(r3), beta_pi(r4), beta_pi(r5)
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(for the e_1-e_1 interaction type)
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* Line 2: beta_pi(r6), beta_pi(r7), beta_pi(r8), beta_pi(r9),
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beta_pi(r10) (this continues until nr)
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* Line 1: beta\_pi(r1), beta\_pi(r2), beta\_pi(r3), beta\_pi(r4), beta\_pi(r5)
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(for the e\_1-e\_1 interaction type)
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* Line 2: beta\_pi(r6), beta\_pi(r7), beta\_pi(r8), beta\_pi(r9),
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beta\_pi(r10) (this continues until nr)
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* ...
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* Line nr/5+1: beta_pi(r1), beta_pi(r2), beta_pi(r3), beta_pi(r4),
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beta_pi(r5) (for the e_1-e_2 interaction type)
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* Line nr/5+1: beta\_pi(r1), beta\_pi(r2), beta\_pi(r3), beta\_pi(r4),
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beta\_pi(r5) (for the e\_1-e\_2 interaction type)
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The next section contains a block for each interaction type for the
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THETA_(S,ij)((THETA_(sigma,ij))\^(1/2), f_(sigma,ij)). Each block has
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THETA\_(S,ij)((THETA\_(sigma,ij))\^(1/2), f\_(sigma,ij)). Each block has
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nBOt entries with 5 entries per line.
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* Line 1: THETA_(S,ij)(r1), THETA_(S,ij)(r2), THETA_(S,ij)(r3),
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THETA_(S,ij)(r4), THETA_(S,ij)(r5) (for the e_1-e_2 interaction type)
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* Line 2: THETA_(S,ij)(r6), THETA_(S,ij)(r7), THETA_(S,ij)(r8),
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THETA_(S,ij)(r9), THETA_(S,ij)(r10) (this continues until nBOt)
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* Line 1: THETA\_(S,ij)(r1), THETA\_(S,ij)(r2), THETA\_(S,ij)(r3),
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THETA\_(S,ij)(r4), THETA\_(S,ij)(r5) (for the e\_1-e\_2 interaction type)
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* Line 2: THETA\_(S,ij)(r6), THETA\_(S,ij)(r7), THETA\_(S,ij)(r8),
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THETA\_(S,ij)(r9), THETA\_(S,ij)(r10) (this continues until nBOt)
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* ...
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* Line nBOt/5+1: THETA_(S,ij)(r1), THETA_(S,ij)(r2), THETA_(S,ij)(r3),
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THETA_(S,ij)(r4), THETA_(S,ij)(r5) (for the e_1-e_2 interaction type)
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* Line nBOt/5+1: THETA\_(S,ij)(r1), THETA\_(S,ij)(r2), THETA\_(S,ij)(r3),
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THETA\_(S,ij)(r4), THETA\_(S,ij)(r5) (for the e\_1-e\_2 interaction type)
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The next section contains a block of N lines for e_1-e_N
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The next section contains a block of N lines for e\_1-e\_N
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* Line 1: delta\^mu (for e_1)
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* Line 2: delta\^mu (for e_2 and repeats to e_N)
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* Line 1: delta\^mu (for e\_1)
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* Line 2: delta\^mu (for e\_2 and repeats to e\_N)
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The last section contains more constants for e_i-e_j interactions with
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The last section contains more constants for e\_i-e\_j interactions with
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i=0->N, j=i->N
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* Line 1: (A_ij)\^(mu\*nu) (for e1-e1)
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* Line 2: (A_ij)\^(mu\*nu) (for e1-e2 and repeats as above)
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* Line 1: (A\_ij)\^(mu\*nu) (for e1-e1)
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* Line 2: (A\_ij)\^(mu\*nu) (for e1-e2 and repeats as above)
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----------
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@ -274,34 +274,34 @@ the tabulated functions are given.
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* Line 1: nr, ntheta, nBOt (nr is the number of divisions the radius is broken
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into for function tables and MUST be a factor of 5; ntheta is the power of the
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power of the spline used to fit the angular function; nBOt is the number
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of divisions for the tabulated values of THETA_(S,ij)
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* Line 2: delta_1-delta_7 (if all are not used in the particular
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of divisions for the tabulated values of THETA\_(S,ij)
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* Line 2: delta\_1-delta\_7 (if all are not used in the particular
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* formulation, set unused values to 0.0)
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Following this N lines for e_1-e_N containing p_pi.
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Following this N lines for e\_1-e\_N containing p\_pi.
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* Line 3: p_pi (for e_1)
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* Line 4: p_pi (for e_2 and continues to e_N)
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* Line 3: p\_pi (for e\_1)
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* Line 4: p\_pi (for e\_2 and continues to e\_N)
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The next section contains several pair constants for the number of
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interaction types e_i-e_j, with i=1->N, j=i->N
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interaction types e\_i-e\_j, with i=1->N, j=i->N
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* Line 1: r_cut (for e_1-e_1 interactions)
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* Line 2: c_sigma, a_sigma, c_pi, a_pi
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* Line 3: delta_sigma, delta_pi
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* Line 4: f_sigma, k_sigma, delta_3 (This delta_3 is similar to that of
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* Line 1: r\_cut (for e\_1-e\_1 interactions)
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* Line 2: c\_sigma, a\_sigma, c\_pi, a\_pi
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* Line 3: delta\_sigma, delta\_pi
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* Line 4: f\_sigma, k\_sigma, delta\_3 (This delta\_3 is similar to that of
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the previous section but is interaction type dependent)
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The next section contains a line for each three body interaction type
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e_j-e_i-e_k with i=0->N, j=0->N, k=j->N
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e\_j-e\_i-e\_k with i=0->N, j=0->N, k=j->N
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* Line 1: g0, g1, g2... (These are coefficients for the angular spline
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of the g_(sigma,jik)(THETA_ijk) for e_1-e_1-e_1 interaction. The
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of the g\_(sigma,jik)(THETA\_ijk) for e\_1-e\_1-e\_1 interaction. The
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function can contain up to 10 term thus 10 constants. The first line
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can contain up to five constants. If the spline has more than five
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terms the second line will contain the remaining constants The
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following lines will then contain the constants for the remaining g0,
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g1, g2... (for e_1-e_1-e_2) and the other three body
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g1, g2... (for e\_1-e\_1-e\_2) and the other three body
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interactions
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The rest of the table has the same structure as the previous section
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@ -327,34 +327,34 @@ the tabulated functions are given.
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* Line 1: nr, ntheta, nBOt (nr is the number of divisions the radius is broken
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into for function tables and MUST be a factor of 5; ntheta is the number of
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divisions for the tabulated values of the g angular function; nBOt is the number
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of divisions for the tabulated values of THETA_(S,ij)
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* Line 2: delta_1-delta_7 (if all are not used in the particular
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of divisions for the tabulated values of THETA\_(S,ij)
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* Line 2: delta\_1-delta\_7 (if all are not used in the particular
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* formulation, set unused values to 0.0)
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Following this N lines for e_1-e_N containing p_pi.
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Following this N lines for e\_1-e\_N containing p\_pi.
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* Line 3: p_pi (for e_1)
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* Line 4: p_pi (for e_2 and continues to e_N)
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* Line 3: p\_pi (for e\_1)
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* Line 4: p\_pi (for e\_2 and continues to e\_N)
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The next section contains several pair constants for the number of
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interaction types e_i-e_j, with i=1->N, j=i->N
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interaction types e\_i-e\_j, with i=1->N, j=i->N
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* Line 1: r_cut (for e_1-e_1 interactions)
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* Line 2: c_sigma, a_sigma, c_pi, a_pi
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* Line 3: delta_sigma, delta_pi
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* Line 4: f_sigma, k_sigma, delta_3 (This delta_3 is similar to that of
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* Line 1: r\_cut (for e\_1-e\_1 interactions)
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* Line 2: c\_sigma, a\_sigma, c\_pi, a\_pi
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* Line 3: delta\_sigma, delta\_pi
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* Line 4: f\_sigma, k\_sigma, delta\_3 (This delta\_3 is similar to that of
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the previous section but is interaction type dependent)
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The next section contains a line for each three body interaction type
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e_j-e_i-e_k with i=0->N, j=0->N, k=j->N
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e\_j-e\_i-e\_k with i=0->N, j=0->N, k=j->N
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* Line 1: g(theta1), g(theta2), g(theta3), g(theta4), g(theta5) (for the e_1-e_1-e_1
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* Line 1: g(theta1), g(theta2), g(theta3), g(theta4), g(theta5) (for the e\_1-e\_1-e\_1
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interaction type)
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* Line 2: g(theta6), g(theta7), g(theta8), g(theta9), g(theta10) (this continues
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until ntheta)
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* ...
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* Line ntheta/5+1: g(theta1), g(theta2), g(theta3), g(theta4), g(theta5), (for the
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e_1-e_1-e_2 interaction type)
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e\_1-e\_1-e\_2 interaction type)
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The rest of the table has the same structure as the previous section (see above).
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Axel Kohlmeyer