My 2D Lithospheric Drip Geodynamic Models

Upper Mantle only, uniform hot initial conditions, no perturbation

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e6

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

1.0

MPEG

1e6

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

1.0

MPEG

1e6

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

1.0

MPEG

1e6

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

1.0

MPEG

1e6

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

1.0

MPEG

1e7

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

1.0

MPEG

1e7

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

1.0

MPEG

1e7

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

1.0

MPEG

1e7

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

1.0

MPEG

1e7

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

1.0

MPEG

1e8

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

1.0

MPEG

1e8

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

1.0

MPEG

1e8

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

1.0

MPEG

1e8

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

1.0

MPEG

1e8

uniform hot

none

769

97

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

1.0

150 My half-space cooling initial conditions with 100 km perturbation, 0.5% cooler

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e5

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10000)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10000)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10000)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 100km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10000)

0.5

150 My half-space cooling initial conditions with 10 km perturbation, 0.5% cooler

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e5)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e6)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e5)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e6)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e5)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e6)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1000)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e5)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e6)

0.5

150 My half-space cooling initial conditions with no perturbation

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e5

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e5

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e5

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e6

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e6

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e6

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e7

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e7

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e7

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e8

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e8

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e8

150 My HS cooling

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

Uniformly hot initial conditions with no perturbation

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e5

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e5

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e6

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e7

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

0

0.5

MPEG

1e7

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e8

uniform hot

none

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

150 My half-space cooling initial conditions, 660km transition zone, with 10 km perturbation, 0.5% cooler

MPEG

Rayleigh #

Initial Condition

Perturbation

Grid X

Grid Z

Grid Refinement

Heat Prod Type

Heat Prod Q

Material Type

Layers

Viscosity Type

Viscosity Prefactor

Temp Depend Type

A

Tref

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

0.5

MPEG

1e5

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

0.5

MPEG

1e6

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

0.5

MPEG

1e7

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e4)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(10)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(100)

0.5

MPEG

1e8

150 My HS cooling

depth = 100km 10km circle -.5% temp

2305

385

none

constant

0

layers

1

constant

1

exp(A(Tref-T)

ln(1e3)

0.5