Added the possibility to have sub-steps

Now per each Coulomb collision process there is the possibility to do sub-steps. This helps in improving accuracy without reducing the time step of the problem.
2023-07-16 14:47:59 +02:00 · 2023-07-12 14:21:29 +02:00 · 2023-07-12 14:21:29 +02:00
commit 28b2bf206a
3 changed files with 55 additions and 43 deletions
--- a/src/modules/init/moduleInput.f90
+++ b/src/modules/init/moduleInput.f90
@ -637,6 +637,7 @@ MODULE moduleInput
      CHARACTER(:), ALLOCATABLE:: electron
      INTEGER:: e
      CLASS(meshCell), POINTER:: cell
+      INTEGER:: subSteps

      !Firstly, check if the object 'interactions' exists
      CALL config%info('interactions', found)
@ -770,8 +771,13 @@ MODULE moduleInput
              pt_i = speciesName2Index(species_i)
              CALL config%get(object // '.species_j', species_j, found)
              pt_j = speciesName2Index(species_j)
+              CALL config%get(object // '.subSteps', subSteps, found)
+              IF (.NOT. found) THEN
+                subSteps = 1

-              CALL coulombMatrix(i)%init(pt_i, pt_j)
+              END IF
+
+              CALL coulombMatrix(i)%init(pt_i, pt_j, subSteps)

            END DO

--- a/src/modules/mesh/moduleMesh.f90
+++ b/src/modules/mesh/moduleMesh.f90
@ -961,10 +961,12 @@ MODULE moduleMesh

      CLASS(meshParticles), INTENT(in), TARGET:: self
      CLASS(meshCell), POINTER:: cell
+      TYPE(interactionsCoulomb):: pair
      INTEGER:: e
      INTEGER:: k
      INTEGER:: i, j
      INTEGER:: n
+      INTEGER:: t
      TYPE(lNode), POINTER:: partTemp
      INTEGER(8), ALLOCATABLE:: cellNodes(:)
      CLASS(meshNode), POINTER:: node
@ -995,14 +997,15 @@ MODULE moduleMesh
                 temperatureNodes(1:cell%nNodes))

        DO k=1, nCoulombPairs
-          i = coulombMatrix(k)%sp_i%n
-          j = coulombMatrix(k)%sp_j%n
+          pair = coulombMatrix(k)
+          i = pair%sp_i%n
+          j = pair%sp_j%n

          !Do scattering of particles from species_i due to species j
          !Compute background properties of species_j
          DO n = 1, cell%nNodes
            node => self%nodes(cellNodes(n))%obj
-            CALL calculateOutput(node%output(j), output, node%v, coulombMatrix(k)%sp_j)
+            CALL calculateOutput(node%output(j), output, node%v, pair%sp_j)
            densityNodes(n)      = output%density/n_ref
            velocityNodes(n,1:3) = output%velocity(1:3)/v_ref
            temperatureNodes(n)  = output%temperature/T_ref
@ -1018,7 +1021,7 @@ MODULE moduleMesh

            !If cell temperature is too low, skip particle to avoid division by zero
            IF (temperature>eps) THEN
-              l2 = coulombMatrix(k)%l2_j/temperature
+              l2 = pair%l2_j/temperature
              l  = SQRT(l2)

            ELSE
@ -1028,17 +1031,13 @@ MODULE moduleMesh

            END IF

+            A  = pair%A_i*density
+
+            !Do the required substeps
+            DO t = 1, pair%nSubSteps
              C = partTemp%part%v - velocity
              normC = NORM2(C)

-            !If relative velocity is too low, skip collision to avoid division by zero and move to next particle
-            IF (normC < eps) THEN
-              partTemp => partTemp%next
-
-              CYCLE
-
-            END IF
-
              !C_3 = z; C_1, C2 = x, y (per)
              C_per = NORM2(C(1:2))
              cosPhi = C(1)  / C_per
@ -1056,13 +1055,12 @@ MODULE moduleMesh
              lW = l * normC
              GlW = G(lW)
              HlW = H(lW)
-            A  = coulombMatrix(k)%A_i*density
              AW = A / normC

              !Calculate changes in W due to collision process
-            deltaW_par = - A * coulombMatrix(k)%one_plus_massRatio_ij * l2 * GlW * tauMin
-            deltaW_par_square = SQRT(AW * GlW * tauMin)*randomMaxwellian()
-            deltaW_per_square = SQRT(AW * HlW * tauMin)*randomMaxwellian()
+              deltaW_par = - A * pair%one_plus_massRatio_ij * l2 * GlW * pair%tauSub
+              deltaW_par_square = SQRT(AW * GlW * pair%tauSub)*randomMaxwellian()
+              deltaW_per_square = SQRT(AW * HlW * pair%tauSub)*randomMaxwellian()

              !Random angle to distribute perpendicular change in velocity
              theta_per = PI2*random()
@ -1075,6 +1073,8 @@ MODULE moduleMesh
              !Update particle velocity and return to laboratory frame
              partTemp%part%v = MATMUL(rotation, W) + velocity

+            END DO
+                                               
            !Move to the next particle in the list
            partTemp => partTemp%next

--- a/src/modules/moduleCoulomb.f90
+++ b/src/modules/moduleCoulomb.f90
@ -12,6 +12,8 @@ MODULE moduleCoulomb
    REAL(8):: lnCoulomb !This can be done a function in the future
    REAL(8):: A_i
    REAL(8):: l2_j
+    REAL(8):: tauSub
+    INTEGER:: nSubSteps
    CONTAINS
      PROCEDURE, PASS:: init => initInteractionCoulomb

@ -44,7 +46,7 @@ MODULE moduleCoulomb

    END FUNCTION H

-    SUBROUTINE initInteractionCoulomb(self, i, j)
+    SUBROUTINE initInteractionCoulomb(self, i, j, subSteps)
      USE moduleSpecies
      USE moduleErrors
      USE moduleConstParam
@ -52,10 +54,14 @@ MODULE moduleCoulomb
      IMPLICIT NONE

      CLASS(interactionsCoulomb), INTENT(out):: self
+      INTEGER, INTENT(in):: subSteps
      INTEGER, INTENT(in):: i, j
      REAL(8):: Z_i, Z_j
      REAL(8):: scaleFactor

+      self%nSubSteps = subSteps
+      self%tauSub    = tauMin / REAL(self%nSubSteps)
+
      self%sp_i => species(i)%obj
      self%sp_j => species(j)%obj