OBJECTIVE: On the basis of recent experimental data, a new mathematical model that predicts creep in human root dentin has been developed. METHOD: The chosen constitutive model comprises fractional derivatives of stress and strain and the restrictions on the coefficients that follow from the Clausius-Duhem inequality. RESULTS: The four constants describing mechanical properties of the human dentin at constant temperature are calculated from a highly non-linear system involving Mittag-Leffler-type functions. Special attention is paid to thermodynamical restrictions that should be observed in determining parameters of the model from experimental results. SIGNIFICANCE: The proposed model allows us to predict behavior of a human dentin in different load situations. Also it could be used for describing mechanical properties of dentin that are important in the development of 'dentin-like' restorative materials.
OBJECTIVE: On the basis of recent experimental data, a new mathematical model that predicts creep in human root dentin has been developed. METHOD: The chosen constitutive model comprises fractional derivatives of stress and strain and the restrictions on the coefficients that follow from the Clausius-Duhem inequality. RESULTS: The four constants describing mechanical properties of the human dentin at constant temperature are calculated from a highly non-linear system involving Mittag-Leffler-type functions. Special attention is paid to thermodynamical restrictions that should be observed in determining parameters of the model from experimental results. SIGNIFICANCE: The proposed model allows us to predict behavior of a human dentin in different load situations. Also it could be used for describing mechanical properties of dentin that are important in the development of 'dentin-like' restorative materials.
Authors: Tan Sui; Jiří Dluhoš; Tao Li; Kaiyang Zeng; Adrian Cernescu; Gabriel Landini; Alexander M Korsunsky Journal: Materials (Basel) Date: 2018-08-21 Impact factor: 3.623