pair_gw_zbl.cpp
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Created: Sun, Nov 10, 06:43

pair_gw_zbl.cpp
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	/* ----------------------------------------------------------------------
	LAMMPS - Large-scale Atomic/Molecular Massively Parallel Simulator
	http://lammps.sandia.gov, Sandia National Laboratories
	Steve Plimpton, sjplimp@sandia.gov

	Copyright (2003) Sandia Corporation. Under the terms of Contract
	DE-AC04-94AL85000 with Sandia Corporation, the U.S. Government retains
	certain rights in this software. This software is distributed under
	the GNU General Public License.

	See the README file in the top-level LAMMPS directory.
	------------------------------------------------------------------------- */

	/* ----------------------------------------------------------------------
	Contributing author: German Samolyuk (ORNL)
	Based on PairTersoffZBL by Aidan Thompson (SNL) and David Farrell (NWU)
	------------------------------------------------------------------------- */

	#include <math.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include "pair_gw_zbl.h"
	#include "atom.h"
	#include "update.h"
	#include "neighbor.h"
	#include "neigh_list.h"
	#include "neigh_request.h"
	#include "force.h"
	#include "comm.h"
	#include "memory.h"
	#include "error.h"

	#include "math_const.h"
	using namespace LAMMPS_NS;
	using namespace MathConst;

	#define MAXLINE 1024
	#define DELTA 4

	/* ---------------------------------------------------------------------- */

	PairGWZBL::PairGWZBL(LAMMPS *lmp) : PairGW(lmp)
	{
	// hard-wired constants in metal or real units
	// a0 = Bohr radius
	// epsilon0 = permittivity of vacuum = q / energy-distance units
	// e = unit charge
	// 1 Kcal/mole = 0.043365121 eV

	if (strcmp(update->unit_style,"metal") == 0) {
	global_a_0 = 0.529;
	global_epsilon_0 = 0.00552635;
	global_e = 1.0;
	} else if (strcmp(update->unit_style,"real") == 0) {
	global_a_0 = 0.529;
	global_epsilon_0 = 0.00552635 * 0.043365121;
	global_e = 1.0;
	} else error->all(FLERR,"Pair gw/zbl requires metal or real units");
	}

	/* ---------------------------------------------------------------------- */

	void PairGWZBL::read_file(char *file)
	{
	int params_per_line = 21;
	char *words = new char[params_per_line+1];

	memory->sfree(params);
	params = NULL;
	nparams = maxparam = 0;

	// open file on proc 0

	FILE *fp;
	if (comm->me == 0) {
	fp = force->open_potential(file);
	if (fp == NULL) {
	char str[128];
	sprintf(str,"Cannot open GW potential file %s",file);
	error->one(FLERR,str);
	}
	}

	// read each line out of file, skipping blank lines or leading '#'
	// store line of params if all 3 element tags are in element list

	int n,nwords,ielement,jelement,kelement;
	char line[MAXLINE],*ptr;
	int eof = 0;

	while (1) {
	if (comm->me == 0) {
	ptr = fgets(line,MAXLINE,fp);
	if (ptr == NULL) {
	eof = 1;
	fclose(fp);
	} else n = strlen(line) + 1;
	}
	MPI_Bcast(&eof,1,MPI_INT,0,world);
	if (eof) break;
	MPI_Bcast(&n,1,MPI_INT,0,world);
	MPI_Bcast(line,n,MPI_CHAR,0,world);

	// strip comment, skip line if blank

	if ((ptr = strchr(line,'#'))) *ptr = '\0';
	nwords = atom->count_words(line);
	if (nwords == 0) continue;

	// concatenate additional lines until have params_per_line words

	while (nwords < params_per_line) {
	n = strlen(line);
	if (comm->me == 0) {
	ptr = fgets(&line[n],MAXLINE-n,fp);
	if (ptr == NULL) {
	eof = 1;
	fclose(fp);
	} else n = strlen(line) + 1;
	}
	MPI_Bcast(&eof,1,MPI_INT,0,world);
	if (eof) break;
	MPI_Bcast(&n,1,MPI_INT,0,world);
	MPI_Bcast(line,n,MPI_CHAR,0,world);
	if ((ptr = strchr(line,'#'))) *ptr = '\0';
	nwords = atom->count_words(line);
	}

	if (nwords != params_per_line)
	error->all(FLERR,"Incorrect format in GW potential file");

	// words = ptrs to all words in line

	nwords = 0;
	words[nwords++] = strtok(line," \t\n\r\f");
	while ((words[nwords++] = strtok(NULL," \t\n\r\f"))) continue;

	// ielement,jelement,kelement = 1st args
	// if all 3 args are in element list, then parse this line
	// else skip to next line

	for (ielement = 0; ielement < nelements; ielement++)
	if (strcmp(words[0],elements[ielement]) == 0) break;
	if (ielement == nelements) continue;
	for (jelement = 0; jelement < nelements; jelement++)
	if (strcmp(words[1],elements[jelement]) == 0) break;
	if (jelement == nelements) continue;
	for (kelement = 0; kelement < nelements; kelement++)
	if (strcmp(words[2],elements[kelement]) == 0) break;
	if (kelement == nelements) continue;

	// load up parameter settings and error check their values

	if (nparams == maxparam) {
	maxparam += DELTA;
	params = (Param ) memory->srealloc(params,maxparamsizeof(Param),
	"pair:params");
	}

	params[nparams].ielement = ielement;
	params[nparams].jelement = jelement;
	params[nparams].kelement = kelement;
	params[nparams].powerm = atof(words[3]);
	params[nparams].gamma = atof(words[4]);
	params[nparams].lam3 = atof(words[5]);
	params[nparams].c = atof(words[6]);
	params[nparams].d = atof(words[7]);
	params[nparams].h = atof(words[8]);
	params[nparams].powern = atof(words[9]);
	params[nparams].beta = atof(words[10]);
	params[nparams].lam2 = atof(words[11]);
	params[nparams].bigb = atof(words[12]);
	params[nparams].bigr = atof(words[13]);
	params[nparams].bigd = atof(words[14]);
	params[nparams].lam1 = atof(words[15]);
	params[nparams].biga = atof(words[16]);
	params[nparams].Z_i = atof(words[17]);
	params[nparams].Z_j = atof(words[18]);
	params[nparams].ZBLcut = atof(words[19]);
	params[nparams].ZBLexpscale = atof(words[20]);

	// currently only allow m exponent of 1 or 3

	params[nparams].powermint = int(params[nparams].powerm);

	if (
	params[nparams].lam3 < 0.0 \|\| params[nparams].c < 0.0 \|\|
	params[nparams].d < 0.0 \|\| params[nparams].powern < 0.0 \|\|
	params[nparams].beta < 0.0 \|\| params[nparams].lam2 < 0.0 \|\|
	params[nparams].bigb < 0.0 \|\| params[nparams].bigr < 0.0 \|\|
	params[nparams].bigd < 0.0 \|\|
	params[nparams].bigd > params[nparams].bigr \|\|
	params[nparams].lam3 < 0.0 \|\| params[nparams].biga < 0.0 \|\|
	params[nparams].powerm - params[nparams].powermint != 0.0 \|\|
	(params[nparams].powermint != 3 && params[nparams].powermint != 1) \|\|
	params[nparams].gamma < 0.0 \|\|
	params[nparams].Z_i < 1.0 \|\| params[nparams].Z_j < 1.0 \|\|
	params[nparams].ZBLcut < 0.0 \|\| params[nparams].ZBLexpscale < 0.0)
	error->all(FLERR,"Illegal GW parameter");

	nparams++;
	}

	delete [] words;
	}

	/* ---------------------------------------------------------------------- */

	void PairGWZBL::repulsive(Param *param, double rsq, double &fforce,
	int eflag, double &eng)
	{
	double r,tmp_fc,tmp_fc_d,tmp_exp;

	// GW repulsive portion

	r = sqrt(rsq);
	tmp_fc = gw_fc(r,param);
	tmp_fc_d = gw_fc_d(r,param);
	tmp_exp = exp(-param->lam1 * r);
	double fforce_gw = param->biga * tmp_exp * (tmp_fc_d - tmp_fc*param->lam1);
	double eng_gw = tmp_fc * param->biga * tmp_exp;

	// ZBL repulsive portion

	double esq = pow(global_e,2.0);
	double a_ij = (0.8854*global_a_0) /
	(pow(param->Z_i,0.23) + pow(param->Z_j,0.23));
	double premult = (param->Z_i * param->Z_j * esq)/(4.0MY_PIglobal_epsilon_0);
	double r_ov_a = r/a_ij;
	double phi = 0.1818exp(-3.2r_ov_a) + 0.5099exp(-0.9423r_ov_a) +
	0.2802exp(-0.4029r_ov_a) + 0.02817exp(-0.2016r_ov_a);
	double dphi = (1.0/a_ij) * (-3.20.1818exp(-3.2*r_ov_a) -
	0.94230.5099exp(-0.9423*r_ov_a) -
	0.40290.2802exp(-0.4029*r_ov_a) -
	0.20160.02817exp(-0.2016*r_ov_a));
	double fforce_ZBL = premult-phi/rsq + premultdphi/r;
	double eng_ZBL = premult(1.0/r)phi;

	// combine two parts with smoothing by Fermi-like function

	fforce = -(-F_fermi_d(r,param) * eng_ZBL +
	(1.0 - F_fermi(r,param))*fforce_ZBL +
	F_fermi_d(r,param)eng_gw + F_fermi(r,param)fforce_gw) / r;

	if (eflag)
	eng = (1.0 - F_fermi(r,param))eng_ZBL + F_fermi(r,param)eng_gw;
	}

	/* ---------------------------------------------------------------------- */

	double PairGWZBL::gw_fa(double r, Param *param)
	{
	if (r > param->bigr + param->bigd) return 0.0;
	return -param->bigb * exp(-param->lam2 * r) * gw_fc(r,param) *
	F_fermi(r,param);
	}

	/* ---------------------------------------------------------------------- */

	double PairGWZBL::gw_fa_d(double r, Param *param)
	{
	if (r > param->bigr + param->bigd) return 0.0;
	return param->bigb * exp(-param->lam2 * r) *
	(param->lam2 * gw_fc(r,param) * F_fermi(r,param) -
	gw_fc_d(r,param) * F_fermi(r,param) - gw_fc(r,param) *
	F_fermi_d(r,param));
	}

	/* ----------------------------------------------------------------------
	Fermi-like smoothing function
	------------------------------------------------------------------------- */

	double PairGWZBL::F_fermi(double r, Param *param)
	{
	return 1.0 / (1.0 + exp(-param->ZBLexpscale*(r-param->ZBLcut)));
	}

	/* ----------------------------------------------------------------------
	Fermi-like smoothing function derivative with respect to r
	------------------------------------------------------------------------- */

	double PairGWZBL::F_fermi_d(double r, Param *param)
	{
	return param->ZBLexpscaleexp(-param->ZBLexpscale(r-param->ZBLcut)) /
	pow(1.0 + exp(-param->ZBLexpscale*(r-param->ZBLcut)),2.0);
	}

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