# Stresses with Gradients in a Nonuniform Material

With the `block insitu topography`

command, it is easy to install the initial stresses even when materials of different densities are present. Consider a layered system with a free surface, enclosed in a box with roller side boundaries and a fixed base. Suppose that the material has the following density distribution:

1600 kg/m

^{3}from 0 to 10 m depth2000 kg/m

^{3}from 10 to 15 m2200 kg/m

^{3}from 15 to 25 m

Assume a horizontal stress ratio of 0.25. An equilibrium state is produced by the data file the following example.

**Initial stress gradient in a nonuniform material**

```
model new
model large-strain off
block create brick 0,20 0,20 0,25
block cut joint-set dip 0.0 origin 0,0,10 join
block cut joint-set dip 0.0 origin 0,0,15 join
block zone generate edgelength 2.0
block zone cmodel assign elastic
block zone property density 1600 bulk 5e9 shear 3e9 range position-z 0,10
block zone property density 2000 bulk 5e9 shear 3e9 range position-z 10,15
block zone property density 2200 bulk 5e9 shear 3e9 range position-z 15,25
model gravity 0 0 -10
block insitu topography ratio-x 0.25 ratio-y 0.25
block gridpoint apply velocity-x = 0.0 range position-x 0.0
block gridpoint apply velocity-x = 0.0 range position-x 20.0
block gridpoint apply velocity-y = 0.0 range position-y 0.0
block gridpoint apply velocity-y = 0.0 range position-y 20.0
block gridpoint apply velocity-z = 0.0 range position-z 0.0
model history mechanical unbalanced-maximum
model solve
```

An individual block is created for each material density; fictitious joints separate each block. The internal stress profile is calculated automatically for each block from the known overburden above it. In this case, it is assumed that all horizontal stress ratios are the same, but it would be possible to specify different horizontal stresses in different layers by giving multiple `block insitu topography`

commands with different ratios specified over different ranges.

This example is not in equilibrium at one calculation step; approximately 500 steps are required. The presence of the fictitious joints also prevents the model from being in equilibrium when the initial stresses match the boundary stresses. A jointed model will often require more steps to equilibrate than an unjointed model.

⇐ Stresses with Gradients in an Unjointed Medium: Uniform Material | Compaction within a Model with Nonuniform Zoning ⇒

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