Blue phase liquid crystal composite material and liquid crystal display comprising the same

Abstract

A blue phase liquid crystal composite material and a liquid crystal display comprising the same, can solve the problem of small Kerr constant of the current blue phase liquid crystal and the liquid crystal display comprising the same. The blue phase liquid crystal composite material of the present disclosure is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator. The blue phase liquid crystal composite material of the present disclosure has the advantages of large Kerr constant, low voltage, high contrast, rapid response to electric field, good stability, and the like.

Claims

1. A blue phase liquid crystal composite material, comprising 55.0 wt %-84.9 wt % of a parent blue phase liquid crystal, 5.0 wt %-30.0 wt % of a benzyne compound, 5.0 wt %-30.0 wt % of a chiral compound, 5.0 wt %-30.0 wt % of a photo-polymerizable monomer, and 0.1 wt %-2.0 wt % of a photoinitiator, wherein the benzyne compound has the structural of formula below: ##STR00060## wherein R.sub.1 is any one of alkylphenyl, alkoxyphenyl, alkylbiphenyl, alkoxybiphenyl, alkylphenylethynyl, alkoxyphenylethynyl, alkylnaphthyl, or alkoxynaphthyl; R.sub.2 is hydrogen or fluoro; R.sub.3 is hydrogen or fluoro; and R.sub.4 is any one of cyano, thiocyano, trifluoromethyl, p-cyanophenyl, p-thiocyanophenyl, or p-trifluoromethylphenyl, wherein the blue phase liquid crystal composite material having a Kerr constant up to an order of magnitude of 10.sup.10 mV.sup.2 and a voltage as low as 34V.

2. The blue phase liquid crystal composite material according to claim 1, wherein R.sub.1 has the structure of formula selected from the group consisting of: ##STR00061## wherein n is an integer between 1-20.

3. The blue phase liquid crystal composite material according to claim 1, wherein R.sub.4 has the structure of formula selected from the group consisting of: ##STR00062## wherein X and Y are independently selected from a hydrogen atom or a fluorine atom.

4. The blue phase liquid crystal composite material according to claim 1, wherein the chiral compound is an isosorbitol compound or a mannitol chiral compound.

5. The blue phase liquid crystal composite material according to claim 4, wherein the isosorbitol compound or the mannitol chiral compound has the structure of formula selected from the group consisting of: ##STR00063## wherein R is alkyl having from 1 to 10 carbon atoms.

6. The blue phase liquid crystal composite material according to claim 1, wherein the photo-polymerizable monomer is one or more of 12HMA, TMPTMA, C6M, and C3M, wherein 12HMA, TMPTMA, C6M, and C3M have the structure of formula below: ##STR00064##

7. The blue phase liquid crystal composite material according to claim 1, wherein the photoinitiator is an ultraviolet photoinitiator 2,2-Dimethoxy-2-phenylacetophenone having the structural of formula below: ##STR00065##

8. A liquid crystal display comprising the blue phase liquid crystal composite material according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates the blue phase texture of the blue phase liquid crystal composite material of Example 1 of the invention at different temperature under polarized light.

(2) FIG. 2 illustrates plot of voltage vs. transmittance of the blue phase liquid crystal composite material of the Comparative Example of the invention.

(3) FIG. 3 illustrates plot of voltage vs. transmittance of the blue phase liquid crystal composite material of the Example 1 of the invention.

(4) FIG. 4 illustrates plot of voltage vs. transmittance of the blue phase liquid crystal composite material of the Example 2 of the invention.

(5) FIG. 5 illustrates plot of voltage vs. transmittance of the blue phase liquid crystal composite material of the Example 3 of the invention.

(6) FIG. 6 illustrates plot of voltage vs. transmittance of the blue phase liquid crystal composite material of the Example 9 of the invention.

(7) FIG. 7 illustrates plot of induced birefringence vs. squared voltage of the blue phase liquid crystal composite material of the Example 9 of the invention.

DETAILED DESCRIPTION

(8) In order that the skilled artisan can better understand the technical solutions of embodiments of the invention, the invention will be further described in detail in conjunction with figures and specific embodiments.

(9) The present disclosure provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator.

(10) Where, the weight percentage of each of the components is:

(11) parent blue phase liquid crystal: 55.0 wt %-84.9 wt %;

(12) benzyne compound: 5.0 wt %-30.0 wt %;

(13) chiral compound: 5.0 wt %-30.0 wt %;

(14) photo-polymerizable monomer: 5.0 wt %-30.0 wt %; and

(15) photoinitiator: 0.1 wt %-2.0 wt %.

(16) For example, the aforesaid components can be mixed thoroughly in a certain ratio and irradiated at a certain temperature (for example, at room temperature) with light at a wavelength corresponding to the photoinitiator for a period of time to initiate the polymerization of the photo-polymerizable monomer, to provide the blue phase liquid crystal composite material. A skilled artisan can readily determine the wavelength range and the irradiation duration in view of the photoinitiator used.

(17) The drive voltage of a polymer dispersed blue phase liquid crystal is primarily dependent on the Kerr constant K of the material. The increase of K value favors the decrease of the drive voltage of a polymer dispersed blue phase liquid crystal, and the increase of the birefringence of the material favors the increase of K value.

(18) By adding benzyne molecules, which have a large dielectric constant () and a large birefringence (n), to the parent blue phase liquid crystal, a blue phase liquid crystal composite material with a large Kerr constant and a low voltage can be obtained upon polymerization. The saturation voltage of a blue phase liquid crystal composite material can be as low as 34V, and the magnitude of the Kerr constant can be 10.sup.10 mV.sup.2, which is about 100 times larger than an ordinary blue phase liquid crystal. The blue phase liquid crystal composite material provided in the present disclosure, therefore, has the advantages of low voltage, high contrast, rapid response to electric field, good stability, and the like.

(19) By applying the aforesaid blue phase liquid crystal composite material to a liquid crystal display, the present disclosure further provide a liquid crystal display with a low drive voltage and a rapid response to electric field, thereby solving the problem of the liquid crystal display prepared by the prior method which has a high drive voltage and a slow response to electric field. The liquid crystal display can be any product or component having a display function, such as a liquid crystal panel, a cell phone, a tablet, a television, a display, a laptop, a digital frame, a navigator, and the like.

(20) The following examples are provided to illustrate the process for preparing the blue phase liquid crystal composite material. The examples are illustrative only and not intended to limit the scope of the invention.

Example 1

(21) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator,

(22) wherein the benzyne compound has the structure of formula below,

(23) ##STR00007##

(24) wherein R.sub.1 has the structure of formula below,

(25) ##STR00008##

(26) wherein n is 2; R.sub.2 is hydrogen; R.sub.3 is hydrogen; and R.sub.4 is cyano.

(27) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(28) The chiral compound has the structure of formula below:

(29) ##STR00009##

(30) wherein R is methyl.

(31) The photo-polymerizable monomer is 12HMA which has the structure of formula below:

(32) ##STR00010##

(33) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(34) The weight percentages of the aforesaid components are shown in Table 1.

(35) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 2

(36) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(37) wherein the benzyne compound has the structure of formula below,

(38) ##STR00011##

(39) wherein R.sub.1 has the structure of formula below:

(40) ##STR00012##

(41) wherein n is 4; R.sub.2 is fluoro; R.sub.3 is hydrogen; R.sub.4 is cyano.

(42) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(43) The chiral compound has the structure of formula below:

(44) ##STR00013##
wherein R is propyl.

(45) The photo-polymerizable monomer is C6M which has the structure of formula below:

(46) ##STR00014##

(47) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(48) The weight percentages of the aforesaid components are shown in Table 1.

(49) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 3

(50) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(51) wherein the benzyne compound has the structure of formula below,

(52) ##STR00015##

(53) wherein R1 has the structure of formula below,

(54) ##STR00016##
wherein n is 12; R.sub.2 is fluoro; R.sub.3 is fluoro; R.sub.4 is cyano.

(55) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(56) The chiral compound has the structure of formula below:

(57) ##STR00017##
wherein R is n-decyl.

(58) The photo-polymerizable monomer is 12HMA which has the structure of formula below:

(59) ##STR00018##

(60) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(61) The weight percentages of the aforesaid components are shown in Table 1.

(62) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 4

(63) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(64) wherein the benzyne compound has the structure of formula below,

(65) ##STR00019##

(66) wherein R.sub.1 has the structure of formula below,

(67) ##STR00020##

(68) wherein n is 16; R.sub.2 is fluoro; R.sub.3 is fluoro; R.sub.4 is thiocyano.

(69) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(70) The chiral compound has the structure of formula below:

(71) ##STR00021##
wherein R is n-hexyl.

(72) The photo-polymerizable monomer is C6M which has the structure of formula below,

(73) ##STR00022##

(74) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(75) The weight percentages of the aforesaid components are shown in Table 1.

(76) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 5

(77) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(78) wherein the benzyne compound has the structure of formula below,

(79) ##STR00023##

(80) wherein R.sub.1 has the structure of formula below,

(81) ##STR00024##

(82) wherein n is 8; R.sub.2 is hydrogen; R.sub.3 is hydrogen; R.sub.4 has the structure of formula below,

(83) ##STR00025##
wherein X is a hydrogen atom, Y is a fluorine atom.

(84) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(85) The chiral compound has the structure of formula below:

(86) ##STR00026##
wherein R is n-decyl.

(87) The photo-polymerizable monomer is 12HMA which has the structure of formula below,

(88) ##STR00027##

(89) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(90) The weight percentages of the aforesaid components are shown in Table 1.

(91) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 6

(92) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(93) wherein the benzyne compound has the structure of formula below,

(94) ##STR00028##

(95) wherein R.sub.1 has the structure of formula below,

(96) ##STR00029##
wherein n is 20; R.sub.2 is fluoro; R.sub.3 is fluoro; R.sub.4 is trifluoromethyl.

(97) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(98) The chiral compound has the structure of formula below:

(99) ##STR00030##
wherein R is n-heptyl.

(100) The photo-polymerizable monomer is TMPTMA which has the structure of formula below,

(101) ##STR00031##

(102) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(103) The weight percentages of the aforesaid components are shown in Table 1.

(104) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 7

(105) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(106) wherein the benzyne compound has the structure of formula below,

(107) ##STR00032##

(108) wherein R.sub.1 has the structure of formula below,

(109) ##STR00033##

(110) wherein n is 18; R.sub.2 is hydrogen; R.sub.3 is hydrogen; R.sub.4 has the structure of formula below,

(111) ##STR00034##
wherein X and Y are both a fluorine atom.

(112) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(113) The chiral compound has the structure of formula below:

(114) ##STR00035##
wherein R is n-nonyl.

(115) The photo-polymerizable monomer is C3M which has the structure of formula below,

(116) ##STR00036##

(117) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(118) The weight percentages of the aforesaid components are shown in Table 1.

(119) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 8

(120) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(121) wherein the benzyne compound has the structure of formula below,

(122) ##STR00037##

(123) wherein R.sub.1 has the structure of formula below,

(124) ##STR00038##
wherein n is 15; R.sub.2 is fluoro; R.sub.3 is fluoro;

(125) R.sub.4 has the structure of formula below,

(126) ##STR00039##
wherein X is a fluorine atom, Y is a hydrogen atom.

(127) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(128) The chiral compound has the structure of formula below:

(129) ##STR00040##
wherein R is propyl.

(130) The photo-polymerizable monomer is TMPTMA which has the structure of formula below,

(131) ##STR00041##

(132) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(133) The weight percentages of the aforesaid components are shown in Table 1.

(134) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 9

(135) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(136) wherein the benzyne compound has the structure of formula below,

(137) ##STR00042##

(138) wherein R.sub.1 has the structure of formula below,

(139) ##STR00043##
wherein n is 5; R.sub.2 is fluoro; R.sub.3 is fluoro; R.sub.4 is thiocyano.

(140) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(141) The chiral compound has the structure of formula below:

(142) ##STR00044##
wherein R is n-butyl.

(143) The photo-polymerizable monomer is C6M which has the structure of formula below,

(144) ##STR00045##

(145) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(146) The weight percentages of the aforesaid components are shown in Table 1.

(147) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 10

(148) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(149) wherein the benzyne compound has the structure of formula below,

(150) ##STR00046##

(151) wherein R.sub.1 has the structure of formula below,

(152) ##STR00047##
wherein n is 14; R.sub.2 is hydrogen; R.sub.3 is hydrogen;

(153) R.sub.4 has the structure of formula below,

(154) ##STR00048##
wherein X is a fluorine atom, Y is a hydrogen atom.

(155) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(156) The chiral compound has the structure of formula below:

(157) ##STR00049##
wherein R is ethyl.

(158) The photo-polymerizable monomer is TMPTMA which has the structure of formula below,

(159) ##STR00050##

(160) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(161) The weight percentages of the aforesaid components are shown in Table 1.

(162) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 11

(163) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(164) wherein the benzyne compound has the structure of formula below,

(165) ##STR00051##

(166) wherein R.sub.1 has the structure of formula below,

(167) ##STR00052##
wherein n is 1; R.sub.2 is fluoro; R.sub.3 is fluoro; R.sub.4 is fluoromethyl.

(168) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(169) The chiral compound has the structure of formula below:

(170) ##STR00053##
wherein R is methyl.

(171) The photo-polymerizable monomer is C6M which has the structure of formula below,

(172) ##STR00054##

(173) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(174) The weight percentages of the aforesaid components are shown in Table 1.

(175) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Example 12

(176) The example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by the photo polymerization of the components comprising: a parent blue phase liquid crystal, a benzyne compound, a chiral compound, a photo-polymerizable monomer, and a photoinitiator;

(177) wherein the benzyne compound has the structure of formula below,

(178) ##STR00055##

(179) wherein R.sub.1 has the structure of formula below,

(180) ##STR00056##
wherein n is 3; R.sub.2 is hydrogen; R.sub.3 is hydrogen;

(181) R.sub.4 has the structure of formula below,

(182) ##STR00057##
wherein X is a fluorine atom, Y is a hydrogen atom.

(183) The parent blue phase liquid crystal is SLC-X (available from Yongsheng Huatsing Liquid Crystal Co., Ltd, n=0.253, =29.6, 298K), which mainly comprises a biphenyl nitrile liquid crystal (biphenyl alkyl nitrile liquid crystal or biphenyl alkoxynitrile liquid crystal) and a fluorine containing small molecule liquid crystal. The parent blue phase liquid crystal has a viscosity less than 50 mPa, a melting point lower than 40 C., and a clearing point at 30-200 C.

(184) The chiral compound has the structure of formula below:

(185) ##STR00058##
wherein R is methyl.

(186) The photo-polymerizable monomer is TMPTMA which has the structure of formula below,

(187) ##STR00059##

(188) The photoinitiator is 2,2-dimethoxy-2-phenylacetophenone (trade name 651, available from Adamas Reagent, Ltd.).

(189) The weight percentages of the aforesaid components are shown in Table 1.

(190) The aforesaid components are mixed according to the weight percentages as shown in Table 1, and then filled into a liquid crystal box. After irradiation with ultraviolet light at 10 mW/cm.sup.2 at room temperature for 20 minutes, a blue phase liquid crystal composite material is formed. By observation with a polarizing microscope, the temperature range of this blue phase liquid crystal composite material can reach the room temperature after polymerization. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

Comparative Example

(191) The Comparative Example provides a blue phase liquid crystal composite material, wherein the blue phase liquid crystal composite material is produced by photo polymerization of the components which differ from those of Example 1 in that no benzyne compound is included, and the parent blue phase liquid crystal with the same weight percentage as the benzyne compound is included as the substituent. Other components and weight percentages thereof in the blue phase liquid crystal composite material are the same as those used in Example 1. The resulting blue phase liquid crystal composite material is tested for n, , and saturation voltage, and the results are shown in Table 1.

(192) Testing Methods:

(193) The method for evaluating the electro-optical performance of the blue phase liquid crystal composite material in the example is as follows:

(194) The electro-optical hysteresis property of the blue phase liquid crystal composite material

(195) The electro-optical hysteresis property of the blue phase liquid crystal is usually defined as V/V.sub.on, wherein V.sub.on is the voltage value corresponding to the maximal transmittance, and V is the voltage difference between the forward voltage and the reverse voltage where the transmittance is half of the maximal transmittance. The smaller the V/V.sub.on, the smaller the electro-optical hysteresis, and vice versa.

(196) 2. Calculation of Kerr Constant K of the Blue Phase Liquid Crystal Composite Material

(197) Calculation of Kerr constant K: based on the formula (1) for Kerr effect, within a certain range of field strength, n.sub.induced/ is positively proportional to the square of electric field strength E. Kerr constant K will be the slope of the plot made from n.sub.induced/ and E.
n.sub.induced=KE.sup.2(1)

(198) TABLE-US-00001 TABLE 1 The raw components for the blue phase liquid crystal composite material and amounts thereof, and testing results for the performance of the composite material Raw components for the blue phase liquid crystal composite material parent blue phase benzyne liquid chiral Type and wt % of compound crystal compound photo-polymerizable photoinitiator Performance tests Ex. No. (wt %) (wt %) (wt %) monomer (wt %) n Vsat Comparative 69.8 25 C3M, 5 0.2 0.232 25.3 70 Example 1 5 64.8 25 C3M, 5 0.2 0.243 28.5 39 2 5 55 9.9 TMPTMA, 30 0.1 0.252 30.2 36 3 15 69.5 5 C6M, 10 0.5 0.255 33.2 34 4 8.2 81 5 C3M, 5 0.8 0.242 28.7 36 5 8.8 55 30 12HMA, 5 1.2 0.249 30.0 43 6 5 84.9 5 C6M, 5 0.1 0.253 33.4 38 7 18 58.2 9 12HMA, 13 1.8 0.241 27.5 41 8 30 55 8 TMPTMA, 5 2 0.244 30.2 37 9 23 58.6 13 C6M, 5 0.4 0.251 32.2 39 10 16.7 56 5 TMPTMA, 21 1.3 0.240 28.7 35 11 7 60.9 25 C3M, 7 0.1 0.246 30.0 39 12 11 67 10 12HMA, 11.1 0.9 0.250 32.5 42

(199) The blue phase texture of the blue phase liquid crystal composite material in Example 1 at different temperature under polarized light is shown in FIG. 1.

(200) From Table 1 and FIG. 2, it can be seen that for Comparative Example 1, n and are the smallest, and Vsat is the largest. After the addition of a benzyne compound, the n and in all Examples have been increased to a certain extent, and the corresponding saturation voltages (Vsat) have been significantly reduced. Moreover, according to FIGS. 3-5, for the analogical compounds (Examples 1-3), the more the fluoro is on the side chain, the higher the increase of its dielectric constant is, and the smaller the saturation voltage is. This is because the fluoro in the side chain can significantly increase the dielectric constant of the compound. Therefore, after the addition in Examples 1-3, the dielectric constant of the blue phase liquid crystal composite materials gradually increases.

(201) FIGS. 2-5 show the electro-optical performance tests of the blue phase liquid crystal composite materials, from which it can be seen that the saturation voltages (i.e., the voltages where the transmittance is the largest one) are 70V, 39V, 36V, and 34V, respectively. As can be seen, the saturation voltage has been effectively reduced.

(202) By way of example, the invention merely provides the electro-optical performance test chart plot for the blue phase liquid crystal composite material of Example 9 (see FIG. 6). As can be seen, the saturation voltage (the voltages where the transmittance is the largest one) is 39V.

(203) From the electro-optical curve measured for the blue phase liquid crystal composite material of each example, it can be derived that the order of magnitude of Kerr constant is 10.sup.10 mV.sup.2, which is about 100 times larger than Kerr constant of a coventinal blue phase liquid crystal. For example, FIG. 7 shows plot of induced birefringence vs. squared voltage of the blue phase liquid crystal composite material of the Example 9, in which the slope is Kerr constant of 4.510.sup.10 mV.sup.2.

(204) From the aforesaid testing results, it can be seen that by adding a benzyne compound with a large birefringence and high dielectric constant, the n and of the blue phase liquid crystal composite material thus obtained are greatly increased, and the saturation voltages are greatly improved, as compared to no addition of the benzyne compound. The minimal saturation voltage has been decreased to 34V, and the effect is very significant.

Example 13

(205) The example provides a liquid crystal display, which comprises the aforesaid blue phase liquid crystal composite material. The liquid crystal display can be any product or component having a display function, such as a liquid crystal panel, a cell phone, a tablet, a television, a display, a laptop, a digital frame, a navigator, and the like.

(206) It should be understood that the aforesaid embodiments are merely for illustrating the principle of the invention, but the invention is not limited thereto. To a person of ordinary skill in the art, various variations and modifications can be made without departing from the spirits and fundamentals of the invention, and such variations and modifications will be contemplated within the scope of the invention.

(207) This application claims the priority of Chinese application No. 201310214774.X filed on May 31, 2013, which is incorporated herein by reference in its entirety as part of the present application.