Phase difference element having birefringent film containing titanium oxide tantalum oxide

The invention claimed is: 1. A phase difference element, comprising a transparent substrate and a birefringent film in which tantalum oxide and titanium oxide are obliquely deposited on one surface of the transparent substrate, wherein: the birefringent film comprises a plurality of first photorefractive films and second photorefractive films that are directly and alternately laminated to each other and have different oblique deposition directions, a ratio of titanium atoms to a total of titanium atoms and tantalum atoms in the birefringent film is 4.0 atomic % or higher and 30 atomic % or lower, each of the first photorefractive films and each of the second photorefractive films comprises crystal grains oriented along the oblique deposition direction, and each of the first photorefractive films and each of the second photorefractive films comprise tantalum oxide and titanium oxide, and each of the first photorefractive films is a single layer and each of the second photorefractive films is a single layer. 2. The phase difference element according to claim 1 , wherein the ratio of titanium atoms to the total of titanium atoms and tantalum atoms in the birefringent film is 10 atomic % or higher and 20 atomic % or lower. 3. The phase difference element according to claim 1 , wherein the transparent substrate is a quartz glass substrate. 4. The phase difference element according to claim 1 , wherein a component parallel to a front surface of the transparent substrate in the first oblique direction and a component parallel to the front surface of the transparent substrate in the second oblique direction are directed to respective directions opposite to each other. 5. A display device comprising: the phase difference element according to claim 1 ; and a liquid crystal display, wherein light passing through the liquid crystal display and the phase difference element is emitted from the display device. 6. A phase difference element, comprising a transparent substrate and a birefringent film, the birefringent film including a plurality of first photorefractive films and second photorefractive films that are directly and alternately laminated to each other, each of the first photorefractive films being grown on the transparent substrate or one of the second photorefractive films along a first oblique direction from which a material vapor enters, the material vapor being emitted from a deposition material containing Ta 2 O 5 and TiO 2 and going straight ahead, and each of the second photorefractive films being grown on one of the first photorefractive films along a second oblique direction from which the material vapor enters, the second oblique direction being different from the first oblique direction, wherein: a ratio of Ti to a total of Ta and Ti, (Ti/(Ta+Ti)), of the first and the second photorefractive films is 4.0 atomic % or higher and 30 atomic % or lower, each of the first photorefractive films comprises crystal grains oriented along the first oblique direction and each of the second photorefractive films comprises crystal grains oriented along the second oblique direction, and each of the first photorefractive films and each of the second photorefractive films comprise tantalum oxide and titanium oxide, and each of the first photorefractive films is a single layer and each of the second photorefractive films is a single layer. 7. The phase difference element according to claim 6 , wherein the ratio of Ti to the total of Ta and Ti, (Ti/(Ta+Ti)), of the first and the second photorefractive films is 10 atomic % or higher and 20 atomic % or lower. 8. A method for producing a phase difference element, comprising: obliquely depositing Ta 2 O 5 and TiO 2 on a transparent substrate in a first oblique direction to form a first photorefractive film, and obliquely depositing Ta 2 O 5 and TiO 2 on the first photorefractive film in a second oblique direction to form a second photorefractive film, the second oblique direction being different from the first oblique direction, and forming a birefringent film having a plurality of first photorefractive films and second photorefractive films that are directly and alternately laminated to each other, wherein Ta 2 O 5 and TiO 2 are obliquely deposited such that a ratio of titanium atoms to a total of titanium atoms and tantalum atoms in the birefringent film is 4.0 atomic % or higher to 30 atomic % or lower, each of the first photorefractive films comprises crystal grains oriented along the first oblique direction and each of the second photorefractive films comprises crystal grains oriented along the second oblique direction, and each of the first photorefractive films and each of the second photorefractive films comprise tantalum oxide and titanium oxide, and each of the first photorefractive films is a single layer and each of the second photorefractive films is a single layer. 9. The method for producing a phase difference element according to claim 8 , comprising, after forming the birefringent film, performing an annealing treatment.