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 // ABLAXX statistical de-excitation model

 // Pekka Kaitaniemi, HIP (translation)

 // Christelle Schmidt, IPNL (fission code)

 // Davide Mancusi, CEA (contact person INCL/ABLA)

 // Aatos Heikkinen, HIP (project coordination)

 //

 #define ABLAXX_IN_GEANT4_MODE 1


 #include "globals.hh"


 #ifndef G4Abla_hh

 #define G4Abla_hh 1


 #ifdef ABLAXX_IN_GEANT4_MODE

 #include "globals.hh"

 #else

 #include "G4INCLGeant4Compat.hh"

 #include "G4INCLConfig.hh"

 #endif


 #include "G4AblaRandom.hh"

 #include "G4AblaDataDefs.hh"

 #include "G4AblaFissionBase.hh"


 class G4Abla {


 public:

 #ifdef ABLAXX_IN_GEANT4_MODE

   G4Abla(G4Volant *aVolant, G4VarNtp *aVarntp);

 #else

   G4Abla(G4INCL::Config *config, G4Volant *aVolant, G4VarNtp *aVarntp);

 #endif


   ~G4Abla();


   G4Abla(G4Abla const &other);


   G4Abla &operator=(G4Abla const &other);


   void setVerboseLevel(G4int level);


   G4Volant* getVolant() {

     return volant;

   }


   void breakItUp(G4int nucleusA, G4int nucleusZ, G4double nucleusMass, G4double excitationEnergy,

                  G4double angularMomentum, G4double recoilEnergy, G4double momX, G4double momY, G4double momZ,

                  G4int eventnumber);


   // Evaporation

 public:

   void initEvapora();


   void qrot(G4double z, G4double a, G4double bet, G4double sig, G4double u, G4double *qr);


   void mglw(G4double a, G4double z, G4double *el);


   void mglms(G4double a, G4double z, G4int refopt4, G4double *el);


   G4double spdef(G4int a, G4int z, G4int optxfis);


   G4double fissility(int a,int z, int optxfis);


   void evapora(G4double zprf, G4double aprf, G4double *ee_par, G4double jprf,

                G4double *zf_par, G4double *af_par, G4double *mtota_par,

                G4double *pleva_par, G4double *pxeva_par, G4double *pyeva_par,

                G4int *ff_par, G4int *inttype_par, G4int *inum_par);


   void direct(G4double zprf,G4double a, G4double ee, G4double jprf,

               G4double *probp_par, G4double *probn_par, G4double *proba_par,

               G4double *probf_par, G4double *ptotl_par, G4double *sn_par, G4double *sbp_par, G4double *sba_par, G4double *ecn_par,

               G4double *ecp_par,G4double *eca_par, G4double *bp_par, G4double *ba_par, G4int, G4int inum, G4int itest);


   void densniv(G4double a, G4double z, G4double ee, G4double esous, G4double *dens, G4double bshell, G4double bs, G4double bk,

                G4double *temp, G4int optshp, G4int optcol, G4double defbet);


   G4double bfms67(G4double zms, G4double ams);


   void lpoly(G4double x, G4int n, G4double pl[]);


   G4double eflmac(G4int ia, G4int iz, G4int flag, G4int optshp);


   void appariem(G4double a, G4double z, G4double *del);


   void parite(G4double n, G4double *par);


   G4double tau(G4double bet, G4double homega, G4double ef, G4double t);


   G4double cram(G4double bet, G4double homega);


   G4double bipol(int iflag, G4double y);


   void barfit(G4int iz, G4int ia, G4int il, G4double *sbfis, G4double *segs, G4double *selmax);


   G4double haz(G4int k);

   void standardRandom(G4double *rndm, G4long *seed);


   G4double expohaz(G4int k, G4double T);


   G4double fd(G4double E);


   G4double f(G4double E);


   G4double fmaxhaz(G4double T);


   G4double pace2(G4double a, G4double z);


   void guet(G4double *x_par, G4double *z_par, G4double *find_par);


 public:

   // Coordinate system transformations:

   void lorab(G4double gam, G4double eta, G4double ein, G4double pin[],

              G4double *eout, G4double pout[]);


   void translab(G4double gamrem, G4double etrem, G4double csrem[4], G4int nopart, G4int ndec);

   void translabpf(G4double masse1, G4double t1, G4double p1, G4double ctet1,

                   G4double phi1, G4double gamrem, G4double etrem, G4double R[][4],

                   G4double *plab1, G4double *gam1, G4double *eta1, G4double csdir[]);


   void rotab(G4double R[4][4], G4double pin[4], G4double pout[4]);


   // Utils

   G4int min(G4int a, G4int b);

   G4double min(G4double a, G4double b);

   G4int max(G4int a, G4int b);

   G4double max(G4double a, G4double b);


   G4int nint(G4double number);

   G4int secnds(G4int x);

   G4int mod(G4int a, G4int b);

   G4double dmod(G4double a, G4double b);

   G4double dint(G4double a);

   G4int idint(G4double a);

   G4int idnint(G4double value);

   G4double utilabs(G4double a);

   G4double dmin1(G4double a, G4double b, G4double c);

   G4Ec2sub* getFrldmTable() {

     return ec2sub;

   }


 private:

   G4int verboseLevel;

   G4int ilast;


   G4AblaFissionBase *fissionModel;

   G4Pace *pace;

   G4Ald *ald;

   G4Eenuc *eenuc;

   G4Ec2sub *ec2sub;

   G4Ecld *ecld;

   G4Fb *fb;

   G4Fiss *fiss;

   G4Opt *opt;

   G4Volant *volant;

   G4VarNtp *varntp;

 #ifndef ABLAXX_IN_GEANT4_MODE

   G4INCL::Config *theConfig;

 #endif

 };


 #endif

G4Abla::ec2sub
G4Ec2sub * ec2sub
Definition: G4Abla.hh:318

G4Abla::ecld
G4Ecld * ecld
Definition: G4Abla.hh:319

G4Abla
Class containing ABLA de-excitation code.
Definition: G4Abla.hh:54

G4Abla::parite
void parite(G4double n, G4double *par)
PROCEDURE FOR CALCULATING THE PARITY OF THE NUMBER N.
Definition: G4Abla.cc:2561

G4Abla::eflmac
G4double eflmac(G4int ia, G4int iz, G4int flag, G4int optshp)
This function will calculate the liquid-drop nuclear mass for spheri configuration according to the p...
Definition: G4Abla.cc:2385

G4Abla::setVerboseLevel
void setVerboseLevel(G4int level)
Set verbosity level.
Definition: G4Abla.cc:76

G4INCL::Config
The INCL configuration object.
Definition: G4INCLConfig.hh:60

G4Abla::G4Abla
G4Abla(G4Volant *aVolant, G4VarNtp *aVarntp)
This constructor is used by standalone test driver and the Geant4 interface.
Definition: G4Abla.cc:45

G4Abla::getVolant
G4Volant * getVolant()
Get the internal output data structure pointer.
Definition: G4Abla.hh:89

G4Abla::lorab
void lorab(G4double gam, G4double eta, G4double ein, G4double pin[], G4double *eout, G4double pout[])
Definition: G4Abla.cc:3489

config_s
Definition: deflate.cc:117

G4INCLConfig.hh

G4Abla::nint
G4int nint(G4double number)
Definition: G4Abla.cc:3631

G4Fiss
Definition: G4AblaDataDefs.hh:150

G4Abla::utilabs
G4double utilabs(G4double a)
Definition: G4Abla.cc:3733

z
G4double z
Definition: TRTMaterials.hh:39

G4Abla::haz
G4double haz(G4int k)
Random numbers.
Definition: G4Abla.cc:3520

G4Abla::getFrldmTable
G4Ec2sub * getFrldmTable()
Definition: G4Abla.hh:306

G4Abla::ald
G4Ald * ald
Definition: G4Abla.hh:316

G4Abla::translabpf
void translabpf(G4double masse1, G4double t1, G4double p1, G4double ctet1, G4double phi1, G4double gamrem, G4double etrem, G4double R[][4], G4double *plab1, G4double *gam1, G4double *eta1, G4double csdir[])
Definition: G4Abla.cc:3428

G4Abla::mglms
void mglms(G4double a, G4double z, G4int refopt4, G4double *el)
Mglms.
Definition: G4Abla.cc:971

G4long
long G4long
Definition: G4Types.hh:80

G4Abla::varntp
G4VarNtp * varntp
Definition: G4Abla.hh:324

G4Abla::fmaxhaz
G4double fmaxhaz(G4double T)
tirage aleatoire dans une maxwellienne
Definition: G4Abla.cc:3032

G4Abla::lpoly
void lpoly(G4double x, G4int n, G4double pl[])
This subroutine calculates the ordinary legendre polynomials of order 0 to n-1 of argument x and stor...
Definition: G4Abla.cc:2367

a
G4double a
Definition: TRTMaterials.hh:39

G4AblaFissionBase
Definition: G4AblaFissionBase.hh:50

G4Abla::fissility
G4double fissility(int a, int z, int optxfis)
Calculation of fissility parameter.
Definition: G4Abla.cc:1064

G4Abla::cram
G4double cram(G4double bet, G4double homega)
KRAMERS FAKTOR - REDUCTION OF THE FISSION PROBABILITY INDEPENDENT OF EXCITATION ENERGY.
Definition: G4Abla.cc:2615

G4Abla::direct
void direct(G4double zprf, G4double a, G4double ee, G4double jprf, G4double *probp_par, G4double *probn_par, G4double *proba_par, G4double *probf_par, G4double *ptotl_par, G4double *sn_par, G4double *sbp_par, G4double *sba_par, G4double *ecn_par, G4double *ecp_par, G4double *eca_par, G4double *bp_par, G4double *ba_par, G4int, G4int inum, G4int itest)
Calculation of particle emission probabilities.
Definition: G4Abla.cc:1457

G4Abla::opt
G4Opt * opt
Definition: G4Abla.hh:322

G4int
int G4int
Definition: G4Types.hh:78

G4Abla::mglw
void mglw(G4double a, G4double z, G4double *el)
Model de la goutte liquide de c.
Definition: G4Abla.cc:944

G4Eenuc
Definition: G4AblaDataDefs.hh:200

G4Abla::fb
G4Fb * fb
Definition: G4Abla.hh:320

G4Abla::mod
G4int mod(G4int a, G4int b)
Definition: G4Abla.cc:3675

G4Abla::evapora
void evapora(G4double zprf, G4double aprf, G4double *ee_par, G4double jprf, G4double *zf_par, G4double *af_par, G4double *mtota_par, G4double *pleva_par, G4double *pxeva_par, G4double *pyeva_par, G4int *ff_par, G4int *inttype_par, G4int *inum_par)
Main evaporation routine.
Definition: G4Abla.cc:1098

G4Abla::densniv
void densniv(G4double a, G4double z, G4double ee, G4double esous, G4double *dens, G4double bshell, G4double bs, G4double bk, G4double *temp, G4int optshp, G4int optcol, G4double defbet)
Level density parameters.
Definition: G4Abla.cc:2127

G4Abla::spdef
G4double spdef(G4int a, G4int z, G4int optxfis)
Definition: G4Abla.cc:1014

G4Abla::verboseLevel
G4int verboseLevel
Definition: G4Abla.hh:311

G4Abla::breakItUp
void breakItUp(G4int nucleusA, G4int nucleusZ, G4double nucleusMass, G4double excitationEnergy, G4double angularMomentum, G4double recoilEnergy, G4double momX, G4double momY, G4double momZ, G4int eventnumber)
Main interface to the de-excitation code.
Definition: G4Abla.cc:102

G4AblaDataDefs.hh

G4Opt
Options.
Definition: G4AblaDataDefs.hh:186

G4Abla::eenuc
G4Eenuc * eenuc
Definition: G4Abla.hh:317

G4Volant
Evaporation and fission output data.
Definition: G4AblaDataDefs.hh:223

G4Ecld
Shell corrections and deformations.
Definition: G4AblaDataDefs.hh:122

G4INCLGeant4Compat.hh

G4Abla::fiss
G4Fiss * fiss
Definition: G4Abla.hh:321

iz
G4double iz
Definition: TRTMaterials.hh:39

G4VarNtp
Definition: G4AblaDataDefs.hh:280

p1
const G4double p1
Definition: G4PreCompoundAlpha.cc:49

G4Abla::ilast
G4int ilast
Definition: G4Abla.hh:312

G4Abla::idnint
G4int idnint(G4double value)
Definition: G4Abla.cc:3713

G4Abla::idint
G4int idint(G4double a)
Definition: G4Abla.cc:3699

n
const G4int n
Definition: G4UrQMD1_3Interface.hh:144

globals.hh

G4Abla::~G4Abla
~G4Abla()
Basic destructor.
Definition: G4Abla.cc:82

G4Abla::standardRandom
void standardRandom(G4double *rndm, G4long *seed)

G4AblaRandom.hh

G4Abla::bipol
G4double bipol(int iflag, G4double y)
CALCULATION OF THE SURFACE BS OR CURVATURE BK OF A NUCLEUS RELATIVE TO THE SPHERICAL CONFIGURATION BA...
Definition: G4Abla.cc:2632

G4Abla::translab
void translab(G4double gamrem, G4double etrem, G4double csrem[4], G4int nopart, G4int ndec)
Definition: G4Abla.cc:3202

G4Abla::operator=
G4Abla & operator=(G4Abla const &other)
Dummy assignment operator.

G4Pace
Masses.
Definition: G4AblaDataDefs.hh:66

G4Abla::dmin1
G4double dmin1(G4double a, G4double b, G4double c)
Definition: G4Abla.cc:3719

G4Abla::initEvapora
void initEvapora()
Initialize ABLA evaporation code.
Definition: G4Abla.cc:682

G4Abla::pace2
G4double pace2(G4double a, G4double z)
Definition: G4Abla.cc:3093

G4Fb
Fission barriers.
Definition: G4AblaDataDefs.hh:172

G4Ec2sub
Definition: G4AblaDataDefs.hh:82

G4AblaFissionBase.hh

G4Abla::volant
G4Volant * volant
Definition: G4Abla.hh:323

G4Abla::max
G4int max(G4int a, G4int b)
Definition: G4Abla.cc:3621

G4Abla::tau
G4double tau(G4double bet, G4double homega, G4double ef, G4double t)
RISE TIME IN WHICH THE FISSION WIDTH HAS REACHED 90 PERCENT OF ITS FINAL VALUE.
Definition: G4Abla.cc:2586

G4Abla::bfms67
G4double bfms67(G4double zms, G4double ams)
This subroutine calculates the fission barriers of the liquid-drop model of Myers and Swiatecki (1967...
Definition: G4Abla.cc:2350

G4Abla::f
G4double f(G4double E)
FONCTION INTEGRALE DE FD(E)
Definition: G4Abla.cc:3026

G4InuclParticleNames::gam
Definition: G4InuclParticleNames.hh:61

G4Abla::guet
void guet(G4double *x_par, G4double *z_par, G4double *find_par)
Definition: G4Abla.cc:3131

G4Abla::fissionModel
G4AblaFissionBase * fissionModel
Definition: G4Abla.hh:314

G4Ald
Definition: G4AblaDataDefs.hh:103

G4double
double G4double
Definition: G4Types.hh:76

bk
static unsigned bk
Definition: csz_inflate.cc:360

G4Abla::expohaz
G4double expohaz(G4int k, G4double T)
TIRAGE ALEATOIRE DANS UNE EXPONENTIELLLE : Y=EXP(-X/T)
Definition: G4Abla.cc:3012

G4Abla::pace
G4Pace * pace
Definition: G4Abla.hh:315

G4Abla::barfit
void barfit(G4int iz, G4int ia, G4int il, G4double *sbfis, G4double *segs, G4double *selmax)
THIS SUBROUTINE RETURNS THE BARRIER HEIGHT BFIS, THE GROUND-STATE ENERGY SEGS, IN MEV...
Definition: G4Abla.cc:2687

G4Abla::appariem
void appariem(G4double a, G4double z, G4double *del)
Procedure for calculating the pairing correction to the binding energy of a specific nucleus...
Definition: G4Abla.cc:2531

G4Abla::qrot
void qrot(G4double z, G4double a, G4double bet, G4double sig, G4double u, G4double *qr)
Coefficient of collective enhancement including damping Input: z,a,bet,sig,u Output: qr - collective ...
Definition: G4Abla.cc:898

G4Abla::secnds
G4int secnds(G4int x)
Definition: G4Abla.cc:3659

G4Abla::min
G4int min(G4int a, G4int b)
Definition: G4Abla.cc:3601

G4Abla::dmod
G4double dmod(G4double a, G4double b)

G4Abla::rotab
void rotab(G4double R[4][4], G4double pin[4], G4double pout[4])
Definition: G4Abla.cc:3505

G4Abla::dint
G4double dint(G4double a)
Definition: G4Abla.cc:3685

G4Abla::fd
G4double fd(G4double E)
DISTRIBUTION DE MAXWELL.
Definition: G4Abla.cc:3019