Experiments show that silts and silty soils exhibit contraction followed by dilation during shearing and the slope of failure line decreases at large strains, termed as phase transformation behaviour. This paper is to develop a new micromechanical stress-strain model that accounts for the phase transformation behaviour by explicitly employing the phase transformation line and its related friction angles. The overall strain includes plastic sliding and plastic compression among grains. The internal-friction angle at the phase transformation state and the void state variable are employed to describe the phase transformation behaviour. The model is examined by simulating undrained and drained triaxial compression tests performed on Pitea silts. The local stress-strain behaviour for contact planes is also investigated. Experiments show that silts and silty soils exhibit contraction followed by dilation during shearing and the slope of failure line decreases at large strain, termed as phase transformation behavior. This paper is to develop a new micromechanical stress-strain model that accounts for the phase transformation behavior by surprise employing the phase transformation line and its related friction angles. The overall strain includes plastic sliding and plastic compression among grains. The internal-friction angle at the phase transformation state and the void state variable are employed to describe the phase transformation behavior. model is examined by simulating undrained and drained triaxial compression tests performed on Pitea silts. The local stress-strain behavior for contact planes is also investigated.