Oriented poly(vinylidene fluoride) (PVDF) films consisting of beta crystals were prepared by the solid-state coextrusion (SC) of a gel film near the melting temperature (T-m) and by conventional cold tensile drawing (TD) of a melt-quenched film. These films were annealed over the temperature range of 75-190 degreesC (below and above the static T-m while the sample length was kept constant or constant loads were applied. After annealing with the sample length kept constant, the dynamic Young's modulus markedly decreased because of the relaxation of oriented amorphous chains, as shown by infrared spectroscopy. In contrast, annealing under a constant load improved the chain orientation in both the crystalline and amorphous regions, resulting in an increase in the modulus from an initial 10.5 to 14.3 GPa for the SC and from an initial 3.3 to 4.8 GPa for the TD. The SC, annealed at 190 degreesC with a constant load corresponding to an initial tension of 200 MPa, exhibited an extreme crystalline-chain orientation of 0.998 and a modulus of 14.3 GPa, among the highest values ever reported for PVDF. Although the remanent polarization (P-r) of the TD increased slightly from the initial 62 to 68 mC/m(2), P-r of the SC stayed constant at 100 mC/m(2) independently of the annealing conditions. This suggests that the P-r value of 100 mC/m(2) approached the equilibrium value for this PVDF sample containing 3.5 mol% structural defects. Therefore, although the modulus and P-r of the TD increased slightly with annealing, the maximum values achieved by annealing were markedly lower than those of the SC and annealed SC. (C) 2003 Wiley Periodicals, Inc.