A liquid crystal device comprising: a pair of substrates having an electrode arrangement thereon;an orientation control means provided on at least one of said substrates; anda ferroelectric or antiferroelectric liquid crystal layer interposed between said substrates, said liquid crystal layer being
A liquid crystal device comprising: a pair of substrates having an electrode arrangement thereon;an orientation control means provided on at least one of said substrates; anda ferroelectric or antiferroelectric liquid crystal layer interposed between said substrates, said liquid crystal layer being uniaxially oriented by virtue of said orientation control means,wherein means for suppressing an orientation control effect of said orientation control means with respect to said liquid crystal layer is provided between said liquid crystal layer and said orientation control means.
대표청구항▼
1. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second orientation control film over the first orientation c
1. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second orientation control film over the first orientation control film;a second electrode over the second orientation control film;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode;a plurality of first grains between the first orientation control film and the liquid crystal layer; anda plurality of second grains between the second orientation control film and the liquid crystal layer,wherein the plurality of first grains comprise a first resin, andwherein the plurality of second grains comprise a second resin. 2. The active matrix type display of claim 1, wherein a size of one of the plurality of first grains is not larger than 500 nm. 3. The active matrix type display of claim 1, wherein a size of one of the plurality of second grains is not larger than 500 nm. 4. The active matrix type display of claim 1, wherein the first resin comprises an UV curable resin irradiated by an UV light. 5. The active matrix type display of claim 1, wherein the second resin comprises an UV curable resin irradiated by an UV light. 6. The active matrix type display of claim 1, wherein the liquid crystal layer has a smectic phase. 7. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second orientation control film over the first orientation control film;a second electrode over the second orientation control film;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode;a plurality of first columns between the first orientation control film and the liquid crystal layer; anda plurality of second columns between the second orientation control film and the liquid crystal layer,wherein the plurality of first columns comprise a first resin, andwherein the plurality of second columns comprise a second resin. 8. The active matrix type display of claim 7, wherein the first resin comprises an UV curable resin irradiated by an UV light. 9. The active matrix type display of claim 7, wherein the second resin comprises an UV curable resin irradiated by an UV light. 10. The active matrix type display of claim 7, wherein the liquid crystal layer has a smectic phase. 11. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second orientation control film over the first orientation control film;a second electrode over the second orientation control film;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode;a first resin between the first orientation control film and the liquid crystal layer; anda second resin between the second orientation control film and the liquid crystal layer,wherein the first resin is in the form of a plurality of grains or a film, andwherein the second resin is in the form of a plurality of grains or a film. 12. The active matrix type display of claim 11, wherein a size of one of the plurality of grains is not larger than 500 nm. 13. The active matrix type display of claim 11, wherein the first resin comprises an UV curable resin irradiated by an UV light. 14. The active matrix type display of claim 11, wherein the second resin comprises an UV curable resin irradiated by an UV light. 15. The active matrix type display of claim 11, wherein the liquid crystal layer has a smectic phase. 16. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second orientation control film over the first orientation control film;a second electrode over the second orientation control film;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode;a plurality of first grains between the first orientation control film and the liquid crystal layer; anda plurality of second grains between the second orientation control film and the liquid crystal layer,wherein the plurality of first grains and the second grains are precipitated from a mixture of an UV curable resin and a liquid crystal irradiated by an UV light. 17. The active matrix type display of claim 16, wherein a size of one of the plurality of first grains is not larger than 500 nm. 18. The active matrix type display of claim 16, wherein a size of one of the plurality of second grains is not larger than 500 nm. 19. The active matrix type display of claim 16, wherein the mixture contains a reaction initiator for the UV light. 20. The active matrix type display of claim 16, wherein the liquid crystal layer has a smectic phase. 21. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second electrode over the first orientation control film;a second substrate over the second electrode;a liquid crystal layer between the first orientation control film and the second electrode;a plurality of grains between the first orientation control film and the liquid crystal layer,wherein the plurality of grains comprise a resin. 22. The active matrix type display of claim 21, wherein a size of one of the plurality of grains is not larger than 500 nm. 23. The active matrix type display of claim 21, wherein the resin comprises an UV curable resin irradiated by an UV light. 24. The active matrix type display of claim 21, wherein the liquid crystal layer has a smetic phase. 25. The active matrix type display of claim 21, wherein a second orientation control film is formed between the liquid crystal layer and the second electrode. 26. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a first orientation control film over the first electrode;a second substrate over the first orientation control film;a liquid crystal layer between the first orientation control film and the second substrate;a plurality of grains between the first orientation control film and the liquid crystal layer,wherein the plurality of grains comprise a resin. 27. The active matrix type display of claim 26, wherein a size of one of the plurality of grains is not larger than 500 nm. 28. The active matrix type display of claim 26, wherein the resin comprises an UV curable resin irradiated by an UV light. 29. The active matrix type display of claim 26, wherein the liquid crystal layer has a smetic phase. 30. The active matrix type display of claim 26, wherein a second orientation control film is formed between the liquid crystal layer and the second substrate. 31. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second electrode over the first electrode;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode;a plurality of grains between the first electrode and the liquid crystal layer,wherein the plurality of grains comprise a resin. 32. The active matrix type display of claim 31, wherein a size of one of the plurality of grains is not larger than 500 nm. 33. The active matrix type display of claim 31, wherein the resin comprises an UV curable resin irradiated by an UV light. 34. The active matrix type display of claim 31, wherein the liquid crystal layer has a smetic phase. 35. The active matrix type display of claim 31, wherein a first orientation control film is formed any one of between the first electrode and the liquid crystal layer or between the liquid crystal layer and the second electrode. 36. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second substrate over the first electrode;a liquid crystal layer between the first electrode and the second substrate;a plurality of grains between the first electrode and the liquid crystal layer,wherein the plurality of grains comprise a resin. 37. The active matrix type display of claim 36, wherein a size of one of the plurality of grains is not larger than 500 nm. 38. The active matrix type display of claim 36, wherein the resin comprises an UV curable resin irradiated by an UV light. 39. The active matrix type display of claim 36, wherein the liquid crystal layer has a smetic phase. 40. The active matrix type display of claim 36, wherein a first orientation control film is formed any one of between the first electrode and the liquid crystal layer or between the liquid crystal layer and the second substrate. 41. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second electrode over the first electrode;a second substrate over the second electrode;a liquid crystal layer between the first electrode and the second electrode; anda resin film between the first electrode and the liquid crystal layer,wherein a plurality of grains are disposed on a surface of the resin film and are in contact with the liquid crystal layer. 42. The active matrix type display of claim 41, wherein the resin film comprises an UV curable resin irradiated by an UV light. 43. The active matrix type display of claim 41, wherein the liquid crystal layer has a smetic phase. 44. The active matrix type display of claim 41, wherein the active matrix type display is configured to be driven in a TN mode or an STN mode. 45. The active matrix type display of claim 41, wherein the thin film transistor is a crystalline transistor. 46. The active matrix type display of claim 41, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or an antiferroelectric liquid crystal. 47. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second substrate over the first electrode;a liquid crystal layer between the first electrode and the second substrate; anda resin film between the first electrode and the liquid crystal layer,wherein a plurality of grains are disposed on a surface of the resin film and are in contact with the liquid crystal layer. 48. The active matrix type display of claim 47, wherein the resin film comprises an UV curable resin irradiated by an UV light. 49. The active matrix type display of claim 47, wherein the liquid crystal layer has a smetic phase. 50. The active matrix type display according to claim 47, wherein the active matrix type display is configured to be driven in a TN mode or an STN mode. 51. The active matrix type display according to claim 47, wherein the thin film transistor is a crystalline transistor. 52. The active matrix type display according to claim 47, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or an antiferroelectric liquid crystal. 53. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second electrode over the first electrode;a second substrate over the second electrode;a liquid crystal layer between the first electrode and second electrode;a first resin film between the first electrode and the liquid crystal layer; anda second resin film between the liquid crystal layer and the second electrode,wherein a fist plurality of grains are disposed on a surface of the resin film and are in contact with the liquid crystal layer, andwherein a second plurality of grains are disposed on a surface of the second resin film and are in contact with the liquid crystal layer. 54. The active matrix type display of claim 53, wherein each of the first resin film and the second resin film comprises an UV curable resin irradiated by an UV light. 55. The active matrix type display of claim 53, wherein the liquid crystal layer has a smectic phase. 56. The active matrix type display according to claim 53, wherein the active matrix type display is configured to be driven in a TN mode or an STN mode. 57. The active matrix type display according to claim 53, wherein the thin film transistor is a crystalline transistor. 58. The active matrix type display according to claim 53, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or an antiferroelectric liquid crystal. 59. An active matrix type display comprising: a first substrate;a thin film transistor over the first substrate;a first electrode electrically connected to the thin film transistor;a second substrate over the first electrode;a liquid crystal layer between the first electrode and the second substrate;a first resin film between the first electrode and the liquid crystal layer; anda second resin film between the liquid crystal layer and the second substrate,wherein a fist plurality of grains are disposed on a surface of the first resin film and are in contact with the liquid crystal layer, andwherein a second plurality of grains are disposed on a surface of the second resin film and are in contact with the liquid crystal layer. 60. The active matrix type display according to claim 59, wherein each of the first resin film and the second resin film comprises an UV curable resin irradiated by an UV light. 61. The active matrix type display of claim 59, wherein the liquid crystal layer has a smetic phase. 62. The active matrix type display according to claim 59, wherein the active matrix type display is configured to be driven in a TN mode or an STN mode. 63. The active matrix type display according to claim 59, wherein the thin film transistor is a crystalline transistor. 64. The active matrix type display according to claim 59, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or antiferroelectric liquid crystal 65. A manufacturing method of an active matrix type display, comprising the steps of: providing a first substrate and a second substrate;forming a thin film transistor over the first substrate;forming an insulating layer over the film transistor;forming an electrode over the insulating layer, wherein the electrode is electrically connected to the thin film transistor;forming a plurality of grains over the insulating layer and the electrode; andforming a liquid crystal layer between the first substrate and the second substrate,wherein the liquid crystal layer is in contact with the plurality of grains. 66. The manufacturing method of an active matrix type display according to claim 65, further comprising the step of forming an orientation control film over the insulating layer and the electrode, wherein the orientation control film is formed before forming the plurality of grains. 67. The manufacturing method of an active matrix type display according to claim 66, further comprising the step of irradiating the liquid crystal layer with an UV light, whereby the plurality of grains are formed on a surface of the orientation control film. 68. The manufacturing method of an active matrix type display according to claim 67, wherein the UV light irradiation is applied in a direction normal to a surface of the first substrate. 69. The manufacturing method of an active matrix type display according to claim 65, wherein the step of forming the plurality of grains is after the step of forming the liquid crystal layer. 70. The manufacturing method of an active matrix type display according to claim 65, wherein the plurality of grains comprises an UV curable resin irradiated by an UV light. 71. The manufacturing method of an active matrix type display according to claim 65, wherein the liquid crystal layer has a smetic phase. 72. The manufacturing method of an active matrix type display according to claim 65, wherein a driving mode of the active matrix type display is a TN mode or an STN mode. 73. The manufacturing method of an active matrix type display according to claim 65, wherein the thin film transistor is a crystalline transistor formed by crystallizing an amorphous film by heating. 74. The manufacturing method of an active matrix type display according to claim 65, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or an antiferroelectric liquid crystal. 75. A manufacturing method of an active matrix type display, comprising the steps of: providing a first substrate and a second substrate;forming a thin film transistor over the first substrate;forming an insulating layer over the film transistor;forming an electrode over the insulating layer, wherein the first electrode is electrically connected to the thin film transistor;forming a first plurality of grains over the insulating layer and the first electrode;forming a second electrode over the second substrate;forming a second plurality of grains over the second electrode;forming a liquid crystal layer between the first substrate and the second substrate,wherein the liquid crystal layer is in contact with the first plurality of grains and with the second plurality of grains. 76. The manufacturing method of an active matrix type display according to claim 75, further comprising the step of forming an orientation control film over the insulating layer and the first electrode, wherein the orientation control film is formed before forming the first plurality of grains. 77. The manufacturing method of an active matrix type display according to claim 76, further comprising the step of irradiating the liquid crystal layer with an UV light, whereby the first plurality of grains are formed on a surface of the orientation control film. 78. The manufacturing method of an active matrix type display according to claim 77, wherein the UV light irradiation is applied in a direction normal to a surface of the first substrate. 79. The manufacturing method of an active matrix type display according to claim 75, wherein the step of forming the first plurality of grains and the step of forming the second plurality of grains are after the step of forming the liquid crystal layer. 80. The manufacturing method of an active matrix type display according to claim 75, wherein each of the first plurality of grains and the second plurality of grains comprises an UV curable resin irradiated by an UV light. 81. The manufacturing method of an active matrix type display according to claim 75, wherein the liquid crystal layer has a smectic phase. 82. The manufacturing method of an active matrix type display according to claim 75, wherein a driving mode of the active matrix type display is a TN mode or an STN mode. 83. The manufacturing method of an active matrix type display according to claim 75, wherein the thin film transistor is a crystalline transistor formed by crystallizing an amorphous film by heating. 84. The manufacturing method of an active matrix type display according to claim 75, wherein the liquid crystal layer comprises a ferroelectric liquid crystal or an antiferroelectric liquid crystal. 85. The manufacturing method of an active matrix type display according to claim 75, wherein the first plurality of grains and the second plurality of grains are formed at the same time by irradiating the liquid crystal layer by an UV light.
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