#include #include #include #include #include #include #include #include "optics.h" #include "quantum_efficiency.h" #include "solid_angle.h" #include "pdg.h" #include "vector.h" #include "muon.h" #include "sno.h" #include "scattering.h" #include "pmt_response.h" #include "misc.h" static int initialized = 0; static double *x, *dEdx, *csda_range; static size_t size; static gsl_interp_accel *acc_dEdx; static gsl_spline *spline_dEdx; static gsl_interp_accel *acc_range; static gsl_spline *spline_range; /* Muon critical energy in H2O and D2O. These values are used in computing the * kinetic energy of the muon as a function of distance in get_T(). * * These values come from * http://pdgprod.lbl.gov/~deg/AtomicNuclearProperties/HTML/deuterium_oxide_liquid.html for D2O and * http://pdg.lbl.gov/2018/AtomicNuclearProperties/HTML/water_liquid.html for H2O. */ static const double MUON_CRITICAL_ENERGY_H2O = 1029.0e6; static const double MUON_CRITICAL_ENERGY_D2O = 967.0e3; static int init() { int i, j; char line[256]; char *str; double value; int n; FILE *f = fopen("muE_deuterium_oxide_liquid.txt", "r"); if (!f) { fprintf(stderr, "failed to open muE_water_liquid.txt: %s\n", strerror(errno)); return -1; } i = 0; n = 0; /* For the first pass, we just count how many values there are. */ while (fgets(line, sizeof(line), f)) { size_t len = strlen(line); if (len && (line[len-1] != '\n')) { fprintf(stderr, "got incomplete line on line %i: '%s'\n", i, line); goto err; } i += 1; /* Skip the first 10 lines since it's just a header. */ if (i <= 10) continue; if (!len) continue; else if (line[0] == '#') continue; else if (strstr(line, "Minimum ionization")) continue; else if (strstr(line, "Muon critical energy")) continue; str = strtok(line," \n"); while (str) { value = strtod(str, NULL); str = strtok(NULL," \n"); } n += 1; } x = malloc(sizeof(double)*n); dEdx = malloc(sizeof(double)*n); csda_range = malloc(sizeof(double)*n); size = n; i = 0; n = 0; /* Now, we actually store the values. */ rewind(f); while (fgets(line, sizeof(line), f)) { size_t len = strlen(line); if (len && (line[len-1] != '\n')) { fprintf(stderr, "got incomplete line on line %i: '%s'\n", i, line); goto err; } i += 1; /* Skip the first 10 lines since it's just a header. */ if (i <= 10) continue; if (!len) continue; else if (line[0] == '#') continue; else if (strstr(line, "Minimum ionization")) continue; else if (strstr(line, "Muon critical energy")) continue; str = strtok(line," \n"); j = 0; while (str) { value = strtod(str, NULL); switch (j) { case 0: x[n] = value; break; case 7: dEdx[n] = value; break; case 8: csda_range[n] = value; break; } j += 1; str = strtok(NULL," \n"); } n += 1; } fclose(f); acc_dEdx = gsl_interp_accel_alloc(); spline_dEdx = gsl_spline_alloc(gsl_interp_linear, size); gsl_spline_init(spline_dEdx, x, dEdx, size); acc_range = gsl_interp_accel_alloc(); spline_range = gsl_spline_alloc(gsl_interp_linear, size); gsl_spline_init(spline_range, x, csda_range, size); initialized = 1; return 0; err: fclose(f); return -1; } double muon_get_range(double T, double rho) { /* Returns the approximate range a muon with kinetic energy `T` will travel * in water before losing all of its energy. This range is interpolated * based on data from the PDG which uses the continuous slowing down * approximation. * * `T` should be in MeV, and `rho` should be in g/cm^3. * * Return value is in cm. * * See http://pdg.lbl.gov/2018/AtomicNuclearProperties/adndt.pdf. */ if (!initialized) { if (init()) { exit(1); } } return gsl_spline_eval(spline_range, T, acc_range)/rho; } double muon_get_dEdx(double T, double rho) { /* Returns the approximate dE/dx for a muon in water with kinetic energy * `T`. * * `T` should be in MeV and `rho` in g/cm^3. * * Return value is in MeV/cm. * * See http://pdg.lbl.gov/2018/AtomicNuclearProperties/adndt.pdf. */ if (!initialized) { if (init()) { exit(1); } } if (T < spline_dEdx->x[0]) return spline_dEdx->y[0]; return gsl_spline_eval(spline_dEdx, T, acc_dEdx)*rho; }