from nsim.model import Value
ps = SI(1e-12, "s"); nm = SI(1e-9, "m") # Useful definitions
theta_rad = 3.141592654
phi_rad = 1.570796327
#length, width, thick = (2*nm, 16*nm, 64*nm) # System geometry
current_density = SI( 100e10, "A/m^2") # Applied current
Happ_dir = [0, 0, 0] # Applied field (mT)-
# Material definition
anis = cubic_anisotropy(axis1=[1, 0, 0], axis2=[0,1,0], K1=SI(-1e4, "J/m^3"))
mat = MagMaterial("Co",
Ms=SI(9.0e5, "A/m"),
exchange_coupling=SI(2.0e-11, "J/m"),
llg_gamma_G=SI(2.3245e5, "m/s A"),
if not os.path.exists(mesh_filename):
netgen_mesh_from_file(mesh_geo, mesh_filename)
relaxed_m = "m0.h5"
film_centre = (5, 50, 50)
do_relaxation = not os.path.exists(relaxed_m)
ps = SI(1e-12, "s")
mat = MagMaterial("Py",
Ms=SI(0.86e6, "A/m"),
exchange_coupling=SI(13e-12, "J/m"),
llg_damping=SI(0.5 if do_relaxation else 0.01))
mat.sl_P = 0.0 if do_relaxation else 0.4 # Polarisation
mat.sl_d = SI(3e-9, "m") # Free layer thickness
sim = Simulation(do_sl_stt=True)
sim.load_mesh(mesh_filename, [("region1", mat)], unit_length=SI(1e-9, "m"))
def m0(r):
dx, dy, dz = tuple(ri - ri0*1e-9 for ri, ri0 in zip(r, film_centre))
v = (1.0e-9, dz, -dy)
vn = (1.0e-9**2 + dy*dy + dz*dz)**0.5
return tuple(vi/vn for vi in v)
sim.set_m(m0)
sim.set_H_ext([0, 0, 0], SI("A/m"))
# Applied field
Happ_dir = [0, 0, 10] # in mT
# Material definition
mat = MagMaterial("Py",
Ms=SI(860e3, "A/m"),
exchange_coupling=SI(13e-12, "J/m"),
llg_gamma_G=SI(221017, "m/s A"),
llg_damping=SI(0.014))
# Parameters relevant to spin-torque transfer
# Current and Current Density
I = SI(5e-5, "A")
J = I / (length * width)
mat.sl_P = 0.4 # Polarisation
mat.sl_lambda = 2.0 # lambda parameter
mat.sl_d = height # Free layer thickness
# Direction of the polarisation
theta = 40.0
phi = 90.0
theta_rad = math.pi * theta / 180.0
phi_rad = math.pi * phi / 180.0
P_direction = [
math.sin(theta_rad) * math.cos(phi_rad),
math.sin(theta_rad) * math.sin(phi_rad),
math.cos(theta_rad)
]
sim = Simulation(do_sl_stt=True, do_demag=False)
# create mesh if required
if not os.path.exists(mesh_filename):
netgen_mesh_from_file(mesh_geo, mesh_filename)
relaxed_m = "m0.h5"
film_centre = (5, 50, 50)
do_relaxation = not os.path.exists(relaxed_m)
ps = SI(1e-12, "s")
mat = MagMaterial("Py",
Ms=SI(0.86e6, "A/m"),
exchange_coupling=SI(13e-12, "J/m"),
llg_damping=SI(0.5 if do_relaxation else 0.01))
mat.sl_P = 0.0 if do_relaxation else 0.4 # Polarisation
mat.sl_d = SI(10e-9, "m") # Free layer thickness
sim = Simulation(do_sl_stt=True)
sim.load_mesh(mesh_filename, [("region1", mat)], unit_length=SI(1e-9, "m"))
def m0(r):
dx, dy, dz = tuple(ri - ri0 * 1e-9 for ri, ri0 in zip(r, film_centre))
v = (1.0e-9, dz, -dy)
vn = (1.0e-9**2 + dy * dy + dz * dz)**0.5
return tuple(vi / vn for vi in v)
sim.set_m(m0)
mesh_geo = \
("algebraic3d\n"
"solid cube = orthobrick (0, 0, 0; %s, %s, %s) -maxh = 2.5;\n"
"tlo cube;\n" % tuple(map(lambda x: float(x/nm), (length, width, thick))))
netgen_mesh_from_string(mesh_geo, mesh_filename, keep_geo=True)
# Material definition
anis = uniaxial_anisotropy(axis=[0, 0, 1], K1=-SI(0.1e6, "J/m^3"))
mat = MagMaterial("Py",
Ms=SI(860e3, "A/m"),
exchange_coupling=SI(13e-12, "J/m"),
llg_gamma_G=SI(221017, "m/s A"),
llg_damping=SI(0.014),
anisotropy=anis)
mat.sl_P = 0.4 # Polarisation
mat.sl_lambda = 2.0 # lambda parameter
mat.sl_d = SI(5.0e-9, "m") # Free layer thickness
sim = Simulation(do_sl_stt=True, do_demag=False)
sim.load_mesh(mesh_filename, [("region1", mat)], unit_length=nm)
sim.set_m([1, 0.01, 0.01])
sim.set_H_ext(Happ_dir, 0.001*Tesla/mu0)
# Direction of the polarization
theta_rad = math.pi*theta/180.0
phi_rad = math.pi*phi/180.0
P_direction = [math.sin(theta_rad)*math.cos(phi_rad),
math.sin(theta_rad)*math.sin(phi_rad),
math.cos(theta_rad)]
