TREA

FLUORESCENT LIQUID CRYSTALLINE CHARGE TRANSFER MATERIALS

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Information

  • Patent Application
  • 20010004107
  • Publication Number
    20010004107
  • Date Filed
    November 02, 1998
    26 years ago
  • Date Published
    June 21, 2001
    23 years ago
Information
Abstract
The present invention relates to novel charge transfer materials which have both the advantageous properties of amorphous materials such as structural flexibility and uniformity over large areas, and those of crystalline materials such as molecular orientation and which are excellent in charge transferability, thin-film formability, and durability of various types. The liquid crystalline charge transfer materials have the following structure (A) containing a fluorescent skeletal structure Y, and the core Z of a liquid crystal: 1
Description


TECHNICAL FIELD

[0001] The present invention relates to fluorescent liquid crystalline charge transfer materials. More particularly, the present invention relates to liquid crystalline organic materials having fluorescence and charge transferability, and to various elements or devices using these organic materials.


BACKGROUND OF THE INVENTION

[0002] As charge transfer materials, there have conventionally been known those materials which are obtained by dissolving or dispersing charge transfer molecules, which will become charge transfer sites, in matrix materials such as polycarbonate resins; and those materials such as polyvinyl carbazole which have polymer backbones and charge transfer molecular structures as pendants to the backbones. These materials have widely been used for producing photoconductors for use in copying machines, printers, and the like.

[0003] In the case of the dispersion-type charge transfer materials in the above-described conventional charge transfer materials, it is desirable for improving charge transferability that charge transfer molecules be highly soluble in a matrix polymer. Practically, however, charge transfer molecules are crystallized in a matrix when the concentration of the charge transfer molecules in the matrix is made high. Therefore, the concentration of charge transfer molecules in a matrix is, in general, limited to 20 to 50% by weight although it depends on the type of the charge transfer molecules. Consequently, the amount of the matrix having no charge transferability becomes 50% by weight or more of the whole material; and, when such a material is made into a film, the sufficiently high charge transferability and speed of response of the charge transfer molecules are restricted by the matrix.

[0004] On the other hand, in the case of charge transfer polymers of the above-described pendant type, although the proportion of pendants having charge transferability is high, the polymers have many practical problems in film formability, and also in mechanical strength, environmental stability and durability when they are made into films. Further, in the charge transfer materials of this type, the charge transfer pendants are locally in close proximity. Such locally close pendants become stable sites when hopping of electric charges is conducted, and act as a kind of traps. Consequently, the mobility of electric charges is lowered.

[0005] Furthermore, the features of the above-described amorphous materials, viewed from electrical characteristics are different from those of crystalline materials; and the amorphous materials have such a problem that hopping sites have fluctuation in terms of not only space but also energy. For this reason, the mobility of electric charges in the amorphous materials is highly dependent on the concentration of charge transfer sites; and it is generally from about 10−6 to 10−5 cm2/vs. This value is much smaller than the mobility of electric charges in molecular crystals, which is in the range of 0.1 to 1 cm2/vs. Moreover, there is such a problem that the charge transferabiltiy is highly dependent on both temperature and electric field strength. This is the great difference between the amorphous charge transfer materials and crystalline ones.

[0006] In addition, for such applications that require charge transfer layers having large areas, polycrystalline charge transfer materials are anticipated because they can uniformly be made into charge transfer films having large areas. However, polycrystalline materials are essentially unhomogeneous from the microscopical point of view. They have therefore some problems; for example, it is necessary to suppress those defects which will be formed on particle-particle interfaces.

[0007] An object of the present invention is therefore to solve the aforementioned problems in the prior art, thereby providing novel charge transfer materials which have both the advantageous properties of amorphous materials such as structural flexibility and uniformity over large areas, and those of crystalline materials such as molecular orientation and which are excellent in charge transferability, thin-film formability, and durability of various types.

[0008] Further, we also found that some of the above-described novel charge transfer materials themselves are fluorescent. When a display element such as an electro-luminescent element is composed by using such a charge transfer material, it is not necessary to introduce any fluorescent material which tends to impede the orientation of molecules in a liquid crystal. Therefore, the present invention is also provide charge transfer materials which are free from lowering of charge transferability, which do not change the nature of liquid crystals and which can attain high mobility of electric charges.

[0009] Furthermore, the liquid crystalline materials of the present invention have both charge transferability and fluorescence. Therefore, when they are used, for example, as electro-luminescent elements, the electro-luminescent elements can be produced by using only the liquid crystalline materials, and the production process of the elements can thus be simplified, although it is necessary, for composing conventional electro-luminescent elements, to use two or three layers of an electron transfer layer, a hole transfer layer and a luminescent layer respectively made from materials having electron transferability, hole transferability or fluorescence.


DISCLOSURE OF THE INVENTION

[0010] The above-described object is attained by the present invention which will be described hereinafter. Namely, a first embodiment of the present invention is a liquid crystalline charge transfer material having the following structure (A) containing a fluorescent skeletal structure Y, and the core Z of a liquid crystal:
3

[0011] wherein R1, which may directly be combined with Z without interposing X1 represents a saturated or unsaturated, and linear, branched or cyclic hydrocarbon group having 1 to 22 carbon atoms; and X1 and X2 represent oxygen atom, sulfur atom, or —CO—, —OCO—, —COO—, —N═CH—, —CONH—, —NH—, —NHCO— or —CH2— group.

[0012] A second embodiment of the present invention is a liquid crystalline charge transfer material having the following skeletal structure (B) containing the fluorescent core Y of a liquid crystal:
4

[0013] wherein R1 and R2, which may directly be combined with Y without interposing X1 and X2, represents a saturated or unsaturated, and linear, branched or cyclic hydrocarbon group having 1 to 22 carbon atoms; and X1 and X2 represent oxygen atom, sulfur atom, or —CO—, —OCO—, —COO—, —N═CH—, —CONH—, —NH—, —NHCO— or —CH2— group.

[0014] Liquid crystalline molecules have self-orienting property due to their structures. Therefore, in the case of charge transfer in which liquid crystalline molecules are used as hopping sites, scattering of hopping sites in terms of both space and energy is prevented unlike in the case of charge transfer utilizing the previously-mentioned molecule-dispersed materials, and band-like charge transfer which can be seen in molecular liquid crystals is thus attained. For this reason, the liquid crystalline molecules can attain extremely high mobility of electric charges as compared with the conventional molecule-dispersed materials; and, moreover, the mobility is not dependent on electric field. In addition, by introducing fluorescent skeletal structures to the above-described liquid crystalline molecules having self-orienting property, there can be obtained liquid crystalline charge transfer materials whose self-orienting property is not adversely affected by the addition of fluorescent materials.






BRIEF DESCRIPTION OF THE DRAWINGS

[0015] In the drawings,

[0016]
FIG. 1 is a schematic view showing an electro-luminescent element;

[0017]
FIG. 2 is a schematic view showing an electro-luminescent element (an example of electrode pattern);

[0018]
FIG. 3 is a schematic view showing an electro-luminescent element;

[0019]
FIG. 4 is a schematic view showing an electro-luminescent element;

[0020]
FIG. 5 is a schematic view showing an optical sensor;

[0021]
FIG. 6 is a schematic view showing an optical sensor;

[0022]
FIG. 7 is a schematic view showing an optical sensor;

[0023]
FIG. 8 is a schematic view showing an image-displaying element;

[0024]
FIG. 9 is a schematic view showing an image-recording device;

[0025]
FIG. 10 is a schematic view showing an image-recording device;

[0026]
FIG. 11 is a schematic view showing a spacial optical modulator; and

[0027]
FIG. 12 is a schematic view showing a thin-film transistor.






BEST MODE FOR CARRYING OUT THE INVENTION

[0028] By showing preferable embodiments of the present invention, the present invention will be described more specifically.

[0029] Liquid crystalline charge transfer materials of the present invention will be enumerated below. Among the following charge transfer materials, preferable ones are those liquid crystalline charge transfer materials which fulfill the previously-mentioned requirements, and, at the same time, have the core (6π electron system aromatic ring)1, (10π electron system aromatic ring)m or (14π electron system aromatic ring)n (where 1, m and n are an integer of 0 to 4, provided that 1+m+n=1 to 4), the 6π electron system aromatic ring being combined through a combining group having carbon-carbon double bond or carbon-carbon triple bond. The number of the aromatic rings combined are restricted by taking mobility of electric charges into consideration. Examples of 6π electron system aromatic rings include benzene, pyridine, pyrimidine, pyridazine, pyrazine and tropolone rings; examples of 10π electron system aromatic rings include naphthalene, azulene, benzofuran, indole, indazole, benzothiazole, benzoxazole, benzimidazole, quinoline, isoquinoline, quinazoline and quinoxaline rings; and 14π electron system aromatic rings include phenanthrene and anthracene rings. It has been known that these π electron system aromatic rings show fluorescence when voltage or light is applied thereto. Those charge transfer materials which are preferably used in the present invention have structures combined with these π electron system aromatic rings, so that they are more preferable from the viewpoint of fluorescence.
15LRCrLCC5H11—CO—NH—NH—CO—CH2—CNK 124S 141 IC6H13—CO—NH—NH—CO—CH2—CNK 121S 162 IC7H15—CO—NH—NH—CO—CH2—CNK 125S 184 IC8H17—CO—NH—NH—CO—CH2—CNK 130S 178 IC4H9—O——CO—NH—NH—CO—CH2—CNK 141S 130 IC5H11—O——CO—NH—NH—CO—CH2—CNK 138S 149 IC6H13—O——CO—NH—NH—CO—CH2—CNK 133S 167 IC7H15—O——CO—NH—NH—CO—CH2—CNK 134S 179 IC8H17—O——CO—NH—NH—CO—CH2—CNK 131S 188 IC9H19—O——CH═CH—CO—NH—NH—CO—CH2—CNK 142S 215 I6LRCrLCC10H21—O——COO—C3H8—SiMe2C4H9K 1A 27 IC10H21—O——C4H8—CHMe—O—C3H71K?S 20 S 21 C* 31 A 37 U7LRCrLCC6H13—O—C4H9K 26S 44.5 IC8H17—O—C6H13K 57I 37 C 58 A 79 IC8H17—O—C8H17K 22S 37 G 51 F 62 C 77 A 85 IC8H17—OOC—C5H11K 84C 69 N 70 IC8H17—OOC—C6H13K 61C 77 IC8H17—OOC—C7H15K 41F 77 C 85 IC8H17—OOC—C8H17K 58G 48 F 85 C 88 IC8H17—OOC—C9H19K 36G 60 F 92 IC8H17—OOC—C10H21K 13G 66 F 93 IC8H17—OOC—C11H23K 26G 43 F 96 IC4H9—O——C4H9K 43S 62 IC4H9—O——C6H13K 50S 54 N 61 IC4H9—O——C8H17K 33B 57.3 C 66.8 A 69.4 IC5H11—O——C6H13K 20.5H 31.5 G 45 F 48.5 C 58 N 60.8 IC5H11—O——C7H15K 26.5G 35 F 48 C 67.5 N 68.7 IC5H11—O——C8H17K 37.4B 52 C 70.1 IC5H11—O——C9H19K 42.5B 65 C 72.4 A 74.5 IC5H11—O——C10H21K 44.4B 66.7 C 70.4 A 74.7 IC6H13—O——C3H7K 50S 72 IC6H13—O——C6H13K 22C 66 N 69 BC6H13—O——C7H15K 34H 31.2 G 44.4 F 53 C 74.4 N 75.2 IC6H13—O——C8H17K 30G 23 I 58 C 77 IC6H13—O——C9H19K 36B 64.4 C 80.5 IC6H13—O——C10H21K 30B 67.6 C 80 IC7H15—O——C5H11K 56.9S 61.8 N 68.2 IC7H15—O——C6H13K 40C 68 BC7H15—O——C7H15K 31G 40 I 52 C 77 IC7H15—O——C8H17K 38.5F 56 C 76.5 IC7H15—O——C9H19K 33B 64 C 81.5 IC7H15—O——C10H21K 41B 67.8 C 80.8 I8LRCrLCC3H7—CO—C7H15K 116A 119 IC4H9—CO—C6H13K 114A 123 IC5H11—CO—C5H11K 107E 83 A 127 IC6H13—CO—C4H9K 92E 92 A 126 IC7H15—CO—C3H7K 75E 73 A 107 IC8H17—CO—C2H5K 80E 55 A 117 IC9H19—CO—C2H5K 75A 120 IC9H19—CO—C3H7K 74E 64 A 104 IC9H19—CO—C4H9K 71A 118 IC9H19—CO—C5H11K 98A 118 IC6H13—O——O—C6H13K 114S 125 IC7H15—O——O—C7H15K 99S 101 S 123 IC8H17—O——O—C8H17K 90S 93 S 122 IC9H19—O——O—C9H19K 93S 119 IC10H21—O——O—C10H21K 94S 117 IC11H23—O——O—C11H23K 98S 113 IC12H25—O——O—C12H25K 99S 109 IC4H9—CO——CO—C4H9K 130E 108 A 157 IC5H11—CO——CO—C5H11K 149A 164 IC6H13—CO——CO—C6H13K 146.5A 166 IC7H15—CO——CO—C7H15K 140A 167 IC5H11—COO——OOC—C5H11K 109A 117 BC6H13—COO——OOC—C6H13K 72X 105 A 119 BC7H15—COO——OOC—C7H15K 57X 83 X 93 A 123 BC9H19—COO——OOC—C9H19K 88A 126 B9LRCrLCC5H11—O——C7H15K 78A 73 IC6H13—O——C6H13K 79A 74 IC6H13—O——C7H15K 83A 82 IC7H15—O——C5H11K 72C 74 A 79 IC7H15—O——C6H13K 74C 81 IC7H15—O——C7H15K 79C 89 IC7H15—O——C8H17K 70C 85 IC7H15—O——C9H19K 77C 89 IC7H15—O——C10H21K 75C 86 IC8H17—O——C5H11K 73C 69 A 81 IC8H17—O——C6H13K 73C 80 A 83 IC8H17—O——C7H15K 80C 87 IC8H17—O——C8H17K 80C 90 IC8H17—O——C9H19K 77C 90 IC8H17—O——C10H21K 78G 70 C 90 IC9H19—O——C5H11K 69G 53 C 68 A 82 IC9H19—O——C6H13K 62G 61 C 81 A 83 IC9H19—O——C7H15K 72C 87 IC9H19—O——C9H19K 76C 90 IC10H21—O——C5H11K 73F 55 C 57 A 84 IC10H21—O——C6H13K 50.6S 65.4 C 81.1 A 85.4 IC10H21—O——C7H15K 70C 89 IC10H21—O——C9H19K 79C 92 IC4H9—CMe2—C4H8—O——C7H15K 49C 33 IC4H9—CMe2—C8H12—O——C7H15K 54C 55 IC7H15—COO——C7H15K 79B 66 A 73 IC8H17—COO——C9H19K 85C 84.5 IC11H23—COO——C11H23K 88B 85 IC8H17—O——CHMe—C2H51K 52A 19 IC7H15—C4H8—CHMe—C2H5SK 42.6C* 27.5 A 34 I10LRCrLCC6H13—O——CH═CH—CH2—O—CH3K 16B 30 N 38 IC7H15—O——CH═CH—CH2—O—CH3K 14B 38 ICH3—CO——C3H7K 45S 54 IC4H9—CO——C5H11K 60.7B 52.5 N 58 IC4H9—CO——C7H15K 56.5A 50.5 N 64.3 IC6H13—CO——C7H15K 70B 71.5 IC8H17—CO——C7H15K 70.2E 43 B 80.1 IC3H7—CF2—CO——C5H11K 20B 33 N 53.9 ICH3—NH—CH%CH—CO——C6H13K 107.8A 144.3 N 153 IC2H5—NH—CH%CH—CO——C6H13K 68.4A 76.8 N 120 IC6H13—NH—CH%CH—CO——C6H13K 61C 35 N 104.2 IC7H15—NH—CH%CH—CO——C6H13K 55.2H 40 C 68.9 N 107.8 IC8H17—NH—CH%CH—CO——C6H13K 50.8H 57.8 C 80.3 N 104 IC9H19—NH—CH%CH—CO——C6H13K 54H 74.6 C 94.1 N 107.3 IC10H21—NH—CH%CH—CO——C6H13K 61.3H 83.3 C 100.1 N 105.2 IC11H23—NH—CH%CH—CO——C6H13K 66.7H 94.4 C 106.6 N 109.3 IC12H25—NH—CH%CH—CO——C6H13K 64.1H 97.8 C 109 N 109.4 IC13H27—NH—CH%CH—CO——C6H13K 65H 103.2 C 111.4 IC14H29—NH—CH%CH—CO——C6H13K 55H 102.1 C 109.8 IC15H31—NH—CH%CH—CO——C6H13K 54.2H 106.1 C 110.6 IC18H37—NH—CH%CH—CO——C6H13K 54.1H 107.4 IC4H9—OOC——C5H11K 11A −4 N −3.2 IC3H7—COO——C3H7K 11B 26.1 N 30.3 IC4H9—COO——C3H7K 32.3B 42.7 IC5H11—COO——C7H15K 34.2B 64.5 IC8H17—O——OOC—CH2—CHMe—C3H6—CHMe—CH3SK 53B 39 IC10H21—O——OOC—CHF—C4H9SK 42.5B 41 IC5H11—O——OOC—CHF—C4H9RK 42B 59 IC6H13—O——OOC—CHF—C4H9RK 52B 59 IC7H15—O——OOC—CHF—C4H9RK 42B 64 I11LRCrLCC2H5—O——CNK 150S 144 N 189 IC8H17—C6H13K 68C 106 N 116 IC5H11—O—C4H9K 77S 76 N 118 IC5H11—O——C5H11K 73C 77 N 118 IC5H11—O——C6H13K 73C 88 N 114 IC5H11—O——C7H15K 71C 96 A 98 N 118 IC5H11—O——C8H17K 73C 92 A 105 N 112 IC6H13—O——C5H11K 68C 93 N 125 IC6H13—O——C6H13K 66C 98 N 117 IC6H13—O——C7H15K 65C 104 A 106 N 121 IC6H13—O——C8H17K 69C 104 A 113 N 117 IC7H15—O——C5H11K 73C 98 N 121 IC7H15—O——C6H13K 70C 105 N 116 IC7H15—O——C7H15K 70C 109 A 113 N 120 IC7H15—O——C8H17K 71C 109 A 115 N 116 IC8H17—O——C5H11K 72C 104 N 120 IC8H17—O——C6H13K 68C 106 N 116 IC8H17—O——C7H15K 70C 109 A 117 N 120 IC8H17—O——C8H17K 69C 113 A 118 IC9H19—O——C5H11K 76C 107 A 109 N 118 IC9H19—O——C6H13K 76C 111 A 113 N 116 IC9H19—O——C7H15K 76C 113 A 119 IC9H19—O——C8H17K 75C 114 A 117 IC10H21—O——C5H11K 77C 107 A 113 N 118 IC10H21—O——C6H13K 75C 110 A 114 N 116 IC10H21—O——C7H15K 74C 114 A 119 IC10H21—O——C8H17K 68C 114 A 116 IC11H23—O——C5H11K 83C 105 A 114 N 116 IC11H23—O——C6H13K 82C 110 A 115 IC11H23—O——C7H15K 81C 113 A 118 I12LRCrLCC7H15—CNK 125.6S 154.1 N 163.7 IC8H17—O——O—C8H17K 93C 105 A 111 N 129 IC8H17—O——O—CH2—CH/O\CH[t]-C4H9SK 85C* 128.4 A 130.5 N* 141 I13LRCrLCNC——O—C5H10—SiMeCl2K 119.4S 191.4 IC10H21—O——HK 106.8 B 94 IC7H15—CNK 61.5S 73.5 N 96 IC8H17—CNK 52S 57.5 A 80 N 89 BC9H19—CNK 56.2A 94.4 N 96.7 IC10H21—CNK 47.2A 95.1 IC11H23—CNK 65.5A 100.2 IC7H15—O——CNK 80A 80.5 N 126 BC8H17—O——CNK 103A 110 N 128 BC10H21—O——CNK 87A 129 BC17H36—CONH——CNK 144S 159 IC2H5—CHMe—C4H8—CN1K 59.4S 67.2 IC2H5—CHMe—C5H10—CNK 44.7S 68.3 IC7H15—O——NO2K 77.5A 94 N 106.5 BC8H17—O——NO2K 111A 111 N 114 IC10H21—O——NO2K 97A 116 IC12H25—O——NO2K 85A 115 IC12H25—NH——NO2K 109E 141 IC18H37—NH——NO2K 112.1E 132 IC17H35—CONH——NO2K 139A 160 BC8H17—C8H17K 46H 106 G 108 IC9H19—C9H19K 41H 93 G 109 IC10H21—C10H21K 64H 92 G 106 IC11H23—C11H23K 61S 70 H 85 G 106 IC12H25—C12H25K 75S 77 H 81 G 103 IC5H11—O—CH3K 118B 109.8 N 124.7 IC5H11—O—C8H17K 121.3S 121.1 S 125.5 S 131 ICH3—O——O—C9H19K 149S 142.5 N 142.6 ICH3—O——O—C12H25K 142S 136 ICH3—O——O—C14H29K 139S 132 I14LRCrLCC9H19—O—C7H15K 46C 41 N 61 IC9H19—O—C8H17K 53C 48 N 64 IC9H19—O—C9H19K 54C 52 N 63 IC9H19—O—C10H21K 58.7C 57.9 N 65.8 IC9H19—O—C12H25K 62.1B 47.5 C 63.1 A 63.8 N 66.5 IC9H19—O—C14H29K 63.7B 55.7 C 65.4 A 66.8 IC9H19—O—C16H33K 69.4B 61.3 C 66.4 A 67.6 IC10H21—O—C5H11K 52.5A 42.4 N 52.5 IC10H21—O—C6H13K 44.1B 33.6 A 47.7 N 59 IC10H21—O—C7H15K 52.8B 38.2 C 40.6 A 51.7 N 58.7 IC10H21—O—C8H17K 55.2B 40.5 C 52.4 A 55.9 N 82.5 IC10H21—O—C10H21K 61.4B 45.9 C 60.5 A 62.1 N 64.5 IC10H21—O—C12H25K 64.5B 51 C 64.1 A 65.7 IC10H21—O—C14H29K 65.2B 58.1 C 66.7 IC10H21—O—C16H33K 67.2B 64.2 C 69.6 IC12H25—O—C16H33K 73.7B 68.9 C 71 IC6H13—CO—C4H9K 80A 76 IC6H13—CO—C5H11K 91.6A 80.4 IC6H13—CO—C7H15K 91.4A 85.8 IC9H19—CO—C5H11K 86.7A 88.5 IC10H21—CO—C4H9K 81.4A 87.3 IC10H21—CO—C5H11K 87.8A 93.3 IC10H21—CO—C7H15K 97.1A 93 IC4H9—CO—CH2—OOC—C3H7K 80.2S 90.4 N 95.6 IC10H21—OOC—C7H15K 69C 61.7 N 70.4 IC6H13—O——C6H13K 43.7A 36.7 N 59.6 IC6H13—O——C8H17K 43.6A 42.1 N 61.6 IC6H13—O——C9H19K 38.3C 26.1 A 40 N 65.2 IC6H13—O——C10H21K 51A 49 N 62 IC6H13—O——C12H25K 61.2A 51.4 N 62.2 I15LRCrLCC4H9—O——CH3K 65G 45 N 72 IC4H9—O——C2H5K 40.5G 51 N 65.5 IC4H9—O——C4H9K 8G 41 B 45 A 45.5 N 75 IC4H9—O——C5H11K 28S 30 S 41.5 A 44.4 N 84.6 IC4H9—O——C6H13K 26B 47.3 A 54.7 N 76.9 IC4H9—O——C7H15K 20S 29 B 48.8 A 56.6 N 83.3 IC4H9—O——C8H17K 33B 49.5 A 64.5 N 79 IC4H9—O——C9H19K ?B 48 A 64.7 N 80.2 IC4H9—O——C10H21K 44.3B 46.8 A 64.7 N 76.7 IC4H9—O——C12H25K 37.5G 45.6 B 52.5 A 69.4 N 76.7 IC5H11—O——CH3K 55G 44 N 70.5 IC5H11—O——C2H5K 49.2G 54.2 N 59 IC5H11—O——C3H7K 24A 58 N 77.7 BC5H11—O——C4H9K 20G 51.9 A 52.4 N 69.2 IC5H11—O——C5H11K 28G 46.1 B 48 C 52 A 53 N 77.5 IC5H11—O——C6H13K 34.5G 41 F 44.3 B 51.6 C 53 A 61.1 N 72.9 IC5H11—O——C7H15K 29.5G 33.9 B 51 C 53.1 A 62.8 N 78 IC5H11—O——C8H17K 43.2G 26.2 B 53.7 A 67.8 N 75.1 IC5H11—O——C9H19K ?B 52.9 A 68.7 N 76.7 IC5H11—O——C10H21K 41B 54 A 67 N 76.2 IC5H11—O——C11H23K ?B 53 A 70.4 N 75.1 IC5H11—O——C12H25K 37B 53.3 A 71 N 73.9 IC5H11—O——C13H27K ?B 52.9 A 70.2 N 73.2 IC5H11—O——C14H29K ?B 52.7 A 69.5 N 71.2 IC6H13—O——CH3K 58G 44 B 53 N 76 IC6H13—O——C2H5K 47G 58 N 70 IC6H13—O——C3H7K 29G 65.7 A 68 N 85.6 IC6H13—O——C4H9K 33.5G 58.5 B 59.8 A 70.1 N 77.8 IC6H13—O——C5H11K 41.9G 45.6 B 62 A 75.1 N 85 IC6H13—O——C6H13K 15G 35 B 63 A 77 N 82 I16LRCrLCC8H17—C8H17K 47.9A 36.4 N 41.8 IC9H19—C9H19K 37B 40.5 A 53.2 IC10H21—C10H21K 42.3B 44.6 A 53.7 ICH3—O—C5H11K 61S 48 N 63 IC4H9—O—C7H15K 53.7C 40.3 N 70.2 IC4H9—O—C8H17K 55.2B 35 C 54.2 A 57.6 N 75.2 IC4H9—O—C9H19K 62.1C 58.9 A 63.8 N 73.2 IC4H9—O—C10H21K 54.4B 50.3 C 61.5 A 69.4 N 75.8 IC4H9—O—C12H25K 62I 60 C 64 A 76 N 76.2 IC4H9—O—C14H29K 64S 68 C 69 A 77 IC4H9—O—C18H37K 72.5S 72 A 77 IC8H17—O—C7H15K 53.2C 56.6 A 60.2 N 77.5 IC9H19—O—C8H17K 49.2I 44.8 C 66 A 77.8 N 84.7 IC9H19—O—C9H19K 51I 51.5 C 72.5 A 80.5 N 84.7 IC9H19—O—C10H21K 42.5I 62.3 C 77.2 A 87.3 IC9H19—O—C12H25K 41.5 G 52 I 72.2 C 83 A 88.3 IC9H19—O—C14H29K 51G 68 I 81.1 C 88.2 IC9H19—O—C16H33K 57.5 G 77.7 I 86.2 C 88.6 IC9H19—O—C18H37K 63G 81.8 I 89 ICH3—OOC—CH═CH——CH═CH—COO—CH3K 237S 246 S 249 ICH3—OOC—CH═CH——CH═CH—COO—C2H5K 237S 246 S 249 ICH3OOC—CH═CH——CH═CH—COO—C2H5K 237S 246 S 249 IC2H5OOC—CH═CH——CH═CH—COO—C2H5K 156A 240 IC3H7OOC—CH═CH——CH═CH—COO—C3H7K 120S 209 ICH3—O——CH═CH—COO—C2H5K 117.7A 124.2 N 142.8 IC2H5—O——CH═CH—COO—C2H5K 110S 137 S 147 N 160 IC5H11—O——CH═CH—COO—C5H11K 87E 91 A 133 IC5H11—O——CH═CH—COOO—C10H21K 50.5E 64 A 119 IC10H21—O——CH═CH—COO—C5H11K 54B 94.5 C 95 A 127.5 IC10H21—O——CH═CH—COO—C10H21K 59E 60 B 72 C 95 A 116.5 ICH3—COO——CH═CH—COO—C2H5K 138.3A 153.2 N 162.2 I17LRCrLCC7H15—O—CHMe—CH2—OOC——COO—CH2—CHMe—O—C7H153K 57.8A 80.1 IC8H17—O—CHMe—CH2—OOC——COO—CH2—CHMe—O—C8H173K 63A 84.1 ICH3—COO——OOC—CH3K 229S 282.5 X 284.5 ICH3—OCOO——OCOO—CH3K 229S 257 N 277 IC2H5—OCOO——OCOO—C2H5K 213S 225.5 X 242.5 IC5H11—CHCN—OOC—CHMe—C2H55K 124A <7 IC10H21—O—CHMe—C5H11RK 76.5S 101.5 S 116 C* 122.5 A 126 IC8H17—COO—CHMe—C6H131K 116.5A 123.4 IC8H17—COO—CH2—CHMe—C2H51K 104.7S 125.1 G* 126.9 B 147.6 A 173.5 IC8H17—COO—CH2—CHCl—CH2—CHMe—CH31K 114.2G* 106 I* 114.2 A 153.5 IC8H17—COO—CH2—CHCN—CH2—CHMe—CH31K 81.8B 83.8 A 96.7 IC5H11—O—C3H5—CHMe—C2H5SK ?B 198 A 215.5 IC10H21—O—C3H5—CHMe—C2H5SK 65S 181.5 C* 188.5 A 191 IC8H17—COO—CH2—CHCl—CH31K 54.9S 111.7 G* 148.5 C* 149.1 A 195.4 IC8H17—COO—CH2—CHCl—C4H91K 123.6G* 130.6 C* 139.7 A 169.5 IC8H17—COO—CH2—CHCN—CH31K 138C* 151.4 A 168.5 IC8H17—COO—CH2—CHCN—C2H51K 77.8G* 99.7 I* 118.6 A 139.6 IC8H17—COO—CH2—CHCN—C3H71K 97B 92.8 A 112.7 IC8H17—COO—CH2—CHCN—C4H91K 78.8B 86.7 A 101.2 IC5H11—O—CF3K 211B 221 A 239 IC5H11—O—CF2—HK 223A 241 IC3H7—O—CH2—O—CH2—CH/C\CH(t)—C3H7SK 210E 227.8 A 257.3 IC6H13—CHMe—OOC——COO—CH2—CHCl—CHMe—C2H5*K 55.2C* 57.9 A 79.1 IC6H13—CHMe—OOC——COO—CH2—CHCl—CH2—CHMe—CH33K 58.9C* 54.8 A 61.9 IC6H13—CHMe—OOC——COO—CH2CHCl—CH33K 79.8C* 90.4 A 120.2 IC6H13—CHMe—OOC——COO—CH2—CHCl—C3H73K 84.9C* 78.3 A 84.3 IC6H13—CHMe—OOC——COO—CH2—CHCl—C4H93K 91.8A 83.8 IC2H5—CHMe—CH2—OOC——COO—CH2—CHMe—C2H53K 132A 143 N* 145 ICH3—CHCl—CH2—OOC——COO—CH2—CHCl—CH33K 123A 135 N* 138 IC2H5—CHCl—CH2—OOC——COO—CH2—CHCl—C2H53K 137.3A 138.3 N* 151.5 BP 152.2 I18LRCrLCC6H9—COO—CHMe—CH2—O——C9H19S K 82.9S 101.2 C* 121.7 IC3H7—COO—CH2—CHMe—CH2—O——C6H13RK ?S 89 S 114 S 132 C* 145 A 145.5 IC3H7—O—CHMe—COO—CHMe—CH2—O——C5H11SK 76.2C* 101 A 113.3 N* 114.9 IC3H7—O—CHMe—COO—CHMe—CH2—O——C6H13SK 75.1C* 100.7 A 105.6 N* 109.2 IC3H7—O—CHMe—COO—CHMe—CH2—O——C7H18SK 73.5C* 104.2 N* 111.2 IC3H7—O—CHMe—COO—CHMe—CH2—O——C9H19SK 70.1C* 102.7 A 107.9 N* 109.5 IC4H9—O—CHMe—COO—CHMe—CH2—O——C5H11SK 78C* 93.4 A 111.1 IC4H9—O—CHMe—COO—CHMe—CH2—O——C6H13SK 67.6C* 94 A 106.1 IC4H9—O—CHMe—COO—CHMe—CH2—O——C7H15SK 83.5C* 97.8 A 106.8 IC4H9—O—CHMe—COO—CHMe—CH2O——C9H19SK 68.9C* 107 IC2H5—O—CH2—COO—CH2—CHMe —CH2—O——C6H13RK 63S 77.6 S 122.3 C* 132.3 A 138.8 IC3H7—O—CHMe—COO—CH2—CHMe—CH2—O——C6H13RK ?S 62 S 99 C* 116 A 117.4 IC3H7—O—CHMe—COO——C6H13RK 110S 116 S 132 C* 161.4 IC5H11—O—CHMe—C6H131K 78A 139 IC5H11—O—CHMe—C10H211K 70A 127 IC5H11—O——O—CHMe—C6H131K 104S 117 B 132 C* 142 A 185 IC4H9—O—CH2—CHMe—C2H5RK ?H 118.5 G* 139.2 F* 144.4 B 158.7 C* 165.8 A 191.4 IC7H18—O——O—CH2—CHMe—C2H51K 114E 127 F* 168 C* 213 A 215 IC8H17—O——O—CH2—CHMe—C2H51K 110E 122 F* 164 C* 212 A 214 IC9H19—O——O—CH2—CHMe—C2H51K 97E 117 F* 160 C* 207 A 208 IC10H21—O——O—CH2—CHMe—C2H51K 85E 108 F* 146 C* 205 A 206 IC8H17—O—C4H9—CHMe—C3H72K 67S 109 S 180 C 194 A 215 IC4H9—OOC—C4H9—CHMe—C2H5RK ?G* 111.3 F* 152.4 B 182.8 A 207 IC4H9—O—C5H10—CHMe—C2H5RK 61S 96.8 S 102.5 S 170 C* 182.3 A 196.3 IC8H17—O—CH2—CHF—C6H13RK 75.4S 106 B 153.7 C* 158.5 A 183.3 IC6H13—CHMe—O——C5H111K 58C* 115 A 118 N* 117 IC2H5—CHMe—COO—CHMe—CH2—O——C6H133K 107C* 112 IC2H5—CHMe—COO—CHMe—CH2—O——C7H153K 101C* 113.1 IC2H5—CHMe—COO—CHMe—CH2—O——C9H193K 92.3C* 108.6 N* 110.8 IC6H13—CHMe—OOC——C6H13RK 57.4S 80 S 90.3 C* 94 A 118.5 I19LRCrLCC3H7—COO—CH2—CHMe—C2H51K 127A 158 N* 166 IC5H11—COO—CH2—CHMe—C2H51K 89A 161.6 N* 162.3 IC6H13—COO—CH2—CHMe—C2H51K 68C* 86 A 157 IC7H15—COO—CH2—CHMe—C2H51K 62C* 90 A 158 IC8H17—COO—CH2—CHMe—C2H51K 67C* 101 A 153 IC9H17—COO—CH2—CHMe—C2H51K 53C* 100 A 151 IC10H21—COO—CH2—CHMe—C2H51K 57C* 102 A 148 IC12H25—COO—CH2—CHMe—C2H51K 42C* 81 A 175 UC5H11—COO—CH2—CHMe—C2H52K 106.5A 163 IC8H17—COO—CH2—CHMe—C2H52K 68.9I 51.4 C 103.6 A 154.5 IC8H17—COO—CH2—CHMe—C3H72K 57.2I 36.4 C 93.7 A 150.4 IC8H17—COO—CH2—CHMe—C4H92K 54.5I 35.7 C 91.7 A 145 IC7H15—OCOO—CH2—CHMe—C2H5SK 88.8B 105 A 160.7 N* 163.8 IC8H17—OCOO—CH2—CHMe—C2H5SK 78.3A 150.2 N* 165.2 IC4H9—O——CH2—CHMe—C2H5SK 107E 102 A 174 N* 193 IC5H11—O——CH2—CHMe—C2H5SK 91E 70 B 96 A 172 N* 186 IC6H13—O——CH2—CHMe—C2H5SK 88.5J* 84 C* 103.5 A 172 N* 182 IC7H15—O——CH2—CHMe—C2H5SK 86.5K 66 J* 70 I* 79 C* 126 A 170 N* 177 IC8H17—O——CH2—CHMe—C2H5SK 77K 61 J* 72 I* 80 C* 132 A 171 N* 174 IC9H19—O——CH2—CHMe—C2H5SK 82K 61 J* 70 I* 79 C* 133 A 169 N* 171 IC10H21—O——CH2—CHMe—C2H5SK 38K 60 J* 70 I* 79 C* 133 A 167 IC12H25—O——CH2—CHMe—C2H5SK 74J* 68 I* 79 C* 131 A 162 IC14H29—O——CH2—CHMe—C2H5SK 79J* 67 I* 79 C* 124 A 157 IC16H33—O——CH2—CHMe—C2H5SK 68J* 65 I* 79 C* 120 A 154 IC18H37—O——CH2—CHMe—C2H5SK 71J* 64.5 I* 79 C* 118 A 150 IC4H9—O——CH2—CHMe—C2H52K 107E 103 A 174 N 192 IC5H11—O——CH2—CHMe—C2H52K 90E 72 B 98 A 172 N 186 IC6H13—O——CH2—CHMe—C2H52K 88G 84 C 103 A 172 N 182 IC7H15—O——CH2—CHMe—C2H52K 86H 66 G 70 F 79 C 126 A 170 N 177 IC8H17—O——CH2—CHMe—C2H52K 74K 61 J 72 I 79 C 132 A 171 N 174 I20LRCrLCC2H5—CHMe—CH2—O—C7H15SK 65J* 85 I* 91 C* 110 N* 154 IC2H5—CHMe—CH2—O—C8H17SK 60J* 90 I* 92 C* 114 N* 163 IC2H5—CHMe—CH2—O—C9H19SK 89J* 88 I* 90 C* 115 N* 152 IC2H5—CHMe—CH2—O—C10H21SK 65J* 78 I* 87 C* 117 N* 148 IC2H5—CHMe—CH2—O—C12H25SK 50J* 70 I* 87 C* 116 N* 136 IC2H5—CHMe—CH2—O—C14H251K 50.8C* 93.1 A 130.8 UC2H5—CHMe—CH2—O—C10H212K 55J 78.8 I 90 C 117.3 N 151.6 IC2H5—CHMe—CH2—O—C2H4—O—C10H21SK 79.5S 75 C* 115.5 IC2H5—CHMe—CH2—O—CHMe——O—C10H213K 89C* 95 IC2H5—CHMe—CH2—NMe—CH2—O—C8H17SK 68S 103 C* 114 N* 128 IC2H5—CHMe—CH2—NMe—CH2—O—C12H25SK <25S 93 C* 111 N* 115 IC2H5—CHMe—CH2—NMe—CH2—O—C14H29SK 48S 83 C* 105 N* 109.1 IC2H5—CHMe—CH2—NMe—CH2—O—C15H30SK 65S 82 C* 104 N* 107 IC2H5—CHMe—CH2—NMe—CH2—O—C18H37SK 72S 75 C* 104 N* 107 IC2H5—CHMe—CH2—O——O—C8H17SK 136.5C* 128.8 N* 174 IC6H13—CHMe—CH2—O——O—C8H171K 108.2C* 125.3 N* 141.3 IC2H5—CHMe—CH2—OOC——O—C6H131K 94K 121.3 B.125.6 A 155.9 N* 177.5 IC2H5—CHMe—CH2—OOC——O—C8H171K 85.3E 102 B 118 C* 126.9 A 162.9 N* 170.4 IC2H5—CHMe—CH2—OOC——O—C10H211K 85.5B 97.9 C* 149.5 A 158.5 N* 162.7 IC2H5—CHMe—CH2—COO——O—C8H17SK 110C* 148.3 N* 189.9 IC2H5—CHMe—CH2—O—CHMe—COO——O—C7H153K 120C* 130 N* 134 IC2H5—CHMe—CH2—O—CHMe—COO——O—C8H173K 115C* 135 N* 139 IC2H5—CHMe—CH2—O—CHMe—COO——O—C9H193K 104C* 131 N* 133 IC2H5—CHMe—CH2—O—CHMe—COO——O—C10H213K 103C* 134 IC2H5—CHMe—CH2—O—CHMe—COO——O—C12H253K 106C* 129 IC2H5—CHMe—CH2—OCOO——O—C6H13SK 99.7C* 125.1 N* 185 IC2H5—CHMe—CH2—OCOO——O—C8H17SK 104C* 135.9 N* 173.8 IC2H5—CHMe—CH2—OCOO——O—C9H19SK 102.8C* 139.8 N* 170.4 IC2H5—CHMe—CH2—OCOO——O—C10H21SK 105.6C* 142.9 N* 168.8 IC2H5—CHMe—CH2—O—C2H4—O—C4H9SK ?S 64 C* 76 A 92 N* 126 I21LRCrLCC5H11—O—C8H17K 86.3C 88.3 N 132.4 IC6H13—O—C8H17K 87C 102.2 N 126.8 IC7H15—O—C8H17K 87.3I 76.4 C 112.6 A 123 N 130.9 IC8H17—O—C8H17K 87.6I 83.4 C 120 A 125 N 128.2 IC9H19—O—C8H17K 84.6B 92.3 C 124.7 A 129 N 129.5 IC10H21—O—C8H17K 87.8G 94.3 C 127.2 A 128.3 IC10H21—O——COO—CHMe—C6H131K ?CA ? C-g ? C* ? IC12H25—O——COO—CHMe—C6H131K ?CA ? C-g ? C* ? I22LRCrLCC10H21—O——OOC—C10H21K 40.7P −32 I23LRCrLCC6H13—BrK 104.5S 141.5 N 146.5 IC10H21—BrK 95S 143 IC12H25—BrK 100.5S 144.6 IC3H7—CNK 133.1A 107.3 N 209.1 IC12H25—CNK 98.5S 165 IC6H13—COO—C3H6—SiMe2C4H9K 45S −17 C 41 A 70 IH——O—C8H17K 116.7F 93 N 116.5 IH——O—C9H19K 113F 94.6 N 114.5 IH——O—C10H21K 110.8F 96.5 N 116 IH——O—C12H25K 114.6B 99.6 C 99.7 N 115.2 IC2H5—C9H19K 89.7G 95 N 114.6 IC2H5—C10H21K 72G 66.4 N 109.7 IC3H7—C8H17K 88.9G 73.6 N 110.8 IC3H7—C9H19K 88.2G 76.7 N 113.3 IC3H7—C10H21K 83G 74.1 N 110.6 IC4H9—C8H17K 90G 79 N 104.3 IC4H9—C9H19K 71.1G 81.6 N 106.6 IC4H9—C10H21K 70K 79.5 J 80.5 F 81.5 I 82.7 N 103.7 IC5H11—C8H17K 82.4G 82.3 N 108.5 IC5H11—C9H19K 80G 85.8 N 110.2 IC5H11—C10H21K 73.2K 78.9 J 82.5 F 84.3 I 86.3 C 87.7 N 106.7 IC6H13—C8H17K 78K 80.7 J 82.2 I 85 C 86.7 N 104.5 IC6H13—C9H19K 74.5K 82.6 J 85.4 F 87 I 88.3 C 91.4 N 107.2 IC6H13—C10H21K 67.4K 79.2 J 80.9 F 85 I 88 C 92.8 N 103.8 IC7H15—C8H17K 88K 68 J 78 I 81.6 C 91.6 N 107.4 IC7H15—C9H19K 86.3K 79 J 82.2 F 84.8 I 86.4 C 98 N 110.2 IC7H15—C10H21K 76.8K 76.6 J 78.1 F 83.4 I 86.5 C 96.6 N 106.7 IC8H17—C8H17K 87.3J 71.1 I 80 C 96.3 N 106.7 IC8H17—C9H19K 88.8J 76.4 F 82.6 I 84.9 C 100.6 N 108.1 IC8H17—C10H21K 75.8K 86.1 J 74 F 83.9 I 86.7 C 103 N 107 I24LRCrLCC8H17—C7H15K 60E 54.6 B 81.8 A 128.2 N 128.6 IC8H17—C8H17K 70E 47.7 B 82.2 A 126.6 IC4H9—O—C8H17K 84.4C 73.9 N 149.5 IC4H9—O—C9H19K 92C 78.6 N 141.7 IC4H9—O—C10H21K 88.8C 82.8 N 143.8 IC8H17—O—C5H11K 88.9E 84.3 B 99.7 A 137.6 N 147.3 IC8H17—O—C6H13K 86.1E 75.9 B 99.7 C 120.7 A 138.6 N 148.9 IC8H17—O—C7H15K 91.7E 73.3 B 97.8 C 125.6 A 138.8 N 146.2 IC8H17—O—C8H17K 87E 70.1 B 95.2 C 130.5 A 139.5 N 146.4 IC8H17—O—C9H19K 95.6E 88.9 B 95.5 C 130 A 139.5 N 143.2 IC8H17—O—C10H21K 92.3E 66.2 B 93.5 C 131 A 138.9 N 142.6 IC10H21—O—C5H11K 90.1H 81.5 B 102.8 C 119.6 A 141.1 N 143.2 IC10H21—O—C6H13K 89.5H 70 B 99.4 C 131.5 A 142.7 N 145.3 IC10H21—O—C7H15K 94.2H 65.5 B 100.5 C 135.7 A 141.7 N 143.1 IC10H21—O—C8H17K 93H 62.2 B 99.5 C 138 A 142 N 142.9 IC10H21—O—C9H19K 97H 60.5 B 99.9 C 137.8 A 141.1 IC10H21—O—C10H21K 96.5B 99.5 C 136.3 A 140.7 IC12H25—O—C5H11K 95.8H 83.2 G 93.4 B 103.8 C 123.9 A 140.4 IC12H25—O—C6H13K 95.8H 86.5 B 103.1 C 134 A 142.1 IC12H25—O—C7H15K 97.4H 82 B 102.5 C 137.1 A 140.4 IC12H25—O—C8H17K 97.4H 69 B 101.3 C 139.6 A 140.9 IC12H25—O—C9H19K 99.8H 63.7 B 102.2 C 139.6 IC12H25—O—C10H21K 97.9B 102.2 C 139.3 I25LRCrLCMe3Si—O—Me2Si—C4H5—C3H72K 65G 88 C 93 IMe3Si—CH2—SiMe2—C4H8—C3H72K 45C 86 IMe3Si—C2H4—SiMe2—C4H8—C3H72K 73E 77 C 84 IMe3Si—(CH2—SiMe2)2—C4H8—C3H72K ?G 43 C 71 I(Me3Si—CH2)2—SiMe—C2H4—SiMe2—C4H8—C3H72K ?G 45 C 55 IMe3Si—C2H4—SiMe2—O—SiMe2—C4H8—C3H72K 28C 72 I26LRCrLCC7H15—O—C6H13K 74C 77.9 A 123.3 IC7H15—O—C8H17K 78.6C 77.9 A 122 IC8H17—O—C6H13K 70C 99 A 122.3 IC8H17—O—C8H17K 77.3C 100.2 A 120.3 IC9H19—O—C6H13K 68.5C 103.5 A 123.8 IC9H19—O—C6H17K 72.9C 107.4 A 121.7 I27LRCrLCC9H19—O——C5H11K 74S 48 S 70.5 F 74 C 102 N 124.5 IC10H21—O——C5H11K 75S 56.5 B 83.5 C 111 N 125 IC11H23—O——C5H11K 74S 65 B 94 C 118 A 120 N 123 IC12H25—O——C5H11K 78B 90 C 115 N 124 IC7H15—CO—CH3K 125S 132 N 140.5 IC4H9—O——CO—CH3K 134S 144 N 176 IC6H13—O——CO—CH3K 149.5C 154.5 N 169 IC5H11—COO——CO—CH3K 143S 150 N 179 IC4H9—COO—C2H5K 118B 119.5 N 125 IC4H9—O——COO—C2H5K 121A 129 N 156.5 IC6H13—CHMe—OOC——O—C6H13RK 51S 82 IC6H13—CHMe—OOC——O—C7H15RK 62S 81 IC6H13—CHMe—OOC——O—C8H17RK 73S 83 IC6H13—CHMe—OOC——O—C9H19RK 70S 77 IC6H13—CHMe—OOC——O—C10H21RK 72S 76 A 81 IC6H13—CHMe—OOC——O—C11H23RK 55S 70 C* 74 A 79 IC6H13—CHMe—OOC——O—C12H25RK 54S 69 C* 75 A 79 ICH3—CHMe—CHCl—COO——O—C6H131K 59S 84 B 96 C* 106 N* 125 ICH3—CHMe—CHCl—COO——O—C7H151K 69S 96 C* 110 A 111 N* 122 ICH3—CHMe—CHCl—COO——O—C8H171K 81S 96 C* 112 A 115 N* 121.7 ICH3—CHMe—CHCl—COO——O—C9H191K 49I* 96.5 C* 114 A 117 N* 120 ICH3—CHMe—CHCl—COO——O—C10H211K 48I* 96 C* 114 A 118 N* 119.5 ICH3—CHMe—CHCl—COO——O—C11H231K 57I* 95.5 C* 114 A 119 ICH3—CHMe—CHCl—COO——O—C12H251K 60I* 95.2 C* 114 A 118 IC2H5—CHMe—C3H6—O——O—C9H191K 65J* 82 I* 95 C* 111 N* 123 IC2H5—CHMe—C4H8—O——O—C9H191K 60J* 79 I* 93 C* 111 A 118 IC2H5—CHMe—C5H10—O——O—C9H191K 72J* 82 I* 99 C* 121 N* 123 IC6H13—O——COO—CHMe—C6H13RK 50C* 65 A 100 IC7H15—O——COO—CHMe—C6H13RK 62C* 78 A 97 IC8H17—O——COO—CHMe—C6H13RK 68C* 83 A 99 I28LRCrLCC7H15—O—C8H17K 84.4C 79.3 N 104.6 IC8H17—O—C8H17K 87.1B 58 C 91.7 N 104.5 IC9H19—O—C8H17K 76.8B 65.6 C 97.2 N 105 IC10H21—O—C8H17K 81B 72.2 C 102.7 N 104.7 I29LRCrLCC7H15—O——COO—CHMe—C6H131K 92.3* 73.7 CA 87.5 C-g 90 C* 96.1 C-a 98.4 A 136 IC8H17—O——COO—CHMe—C6H131K 87.6* 71.6 CA 95.1 C-g 97 C* 104 C-a 105.5 A 135.3 IC9H19—O——COO—CHMe—C6H131K 62.2* 64 CA 92.5 C-g 95 C* 107.6 C-a 108.5 A 129.6 IC10H21—O——COO—CHMe—C6H13RK 58.2CA 94.6 C-g 96.1 C* 111.2 A 128.6 IC11H23—O——COO—CHMe—C6H131K 66CA 89 C-g 92.3 C* 112.4 A 123 IC12H25—O——COO—CHMe—C6H131K 73.4CA 92 C-g 94.3 C* 113.2 A 121.3 IC10H21—O——COO—CH2—CHMe—C2H5SK 53S 54 C* 131 A 169 N* 172 IC6H13—CHMe—OOC——O—C6H13RK 92C* 62 A 122 IC6H13—CHMe—OOC——O—C7H15RK 83C* 85 A 117 IC6H13—CHMe—OOC——O—C8H17RK 84C* 90 A 117 IC6H13—CHMe—OOC——O—C9H19RK 87C* 99 A 112 IC6H13—CHMe—OOC——O—C10H21RK 87C* 102 A 112 IC6H13—CHMe—OOC——O—C11H23RK 91C* 107 A 109 IC6H13—CHMe—OOC——O—C12H25RK 91C* 105 A 109 IC2H5—CHMe—CH2—OOC——O—C8H17SK 84C* 120 A 159 N* 175 IC2H5—CHMe—CH2—OOC——O—C10H21SK 91C* 122 A 158 N* 168 I30LRCrLCC10H21—O——CH3K 106.5S 121.5 N 202.5 IC10H21—O——C2H5K 84S 136.5 N 197 IC10H21—O——C4H9K 68B 88 C 151 N 192 IC12H25—O——CH3K 99.5S 142.5 N 193.5 IC12H25—O——C2H5K 90S 150 N 186.5 IC12H25—O——C4H9K 66B 91 C 159 N 185 IC14H29—O——CH3K 95S 155 N 184 IC14H29—O——C2H5K 94S 155 N 180 IC14H29—O——C4H9K 64B 95 C 162 N 178 IC16H33—O——CH3K 91S 160.5 N 178 IC16H33—O——C2H5K 94S 157 N 172 IC16H33—O——C4H9K 83B 96 C 163 N 172 IC18H37—O——CH3K 88S 159 N 171.5 IC18H37—O——C2H5K 95S 157.5 N 168.5 IC5H11—O——O—C8H17K 95S 138 N 226 IC6H13—O——O—C8H17K 90S 151 N 221 IC7H15—O——O—C2H5K 101.5C 73.8 N 250 IC7H15—O——O—C3H7K 114.3S 84.5 C 108 N 235 IC7H15—O——O—C4H9K 90.4S 88.4 C 128.4 N 234.6 IC7H15—O——O—C5H11K 89.4S 85.5 C 141.5 N 221.5 IC7H15—O——O—C6H13K 92S 83 S 84 C 150 N 221.7 IC7H15—O——O—C7H15K 101.4S 85 C 157 N 215.5 IC7H15—O——O—C8H17K 89.7S 84 S 86 C 162.6 N 213.4 IC7H15—O——O—C9H19K 92.9S 81.2 S 85.8 C 168.8 N 208.7 IC7H15—O——O—C10H21K 90.4S 80 S 85.5 C 167.4 N 205.3 IC8H17—O——O—C8H17K 94S 169 N 215.5 IC9H19—O——O—C2H5K 104.2C 99 N 238 IC9H19—O——O—C3H7K 105.4S 79 C 134.6 N 224 IC9H19—O——O—C4H9K 94.6S 80 C 148.8 N 221.8 IC9H19—O——O—C5H11K 91.2S 79 S 80.5 C 158.8 N 215.3 I31LRCrLCC2H5—C2H5K 127S 136 S 149 N 251 IC3H7—C3H7K 109.2H 114.5 G 143 C 150.7 A 180.6 N 255 IC4H9—C4H9K 113S 74 H 89.2 G 144.5 C 172 A 199 N 235 IC5H11—C5H11K 72.8H 62.8 G 139 F 148.8 C 178.3 A 212 N 233.3 IC6H13—C6H13K 71.3H 64.5 G 141.6 F 152.4 C 186.2 A 207.5 N 215.5 IC7H15—C7H15K 61.6H 48 G 143 F 156.9 C 191.4 A 210 N 211.5 IC8H17—C8H17K 63.5H 46 G 138.5 F 156.8 C 192.5 A 202.5 IC9H19—C9H19K 57.3G 132.5 F 155.5 I 157.5 C 192.7 A 199 IC10H21—C10H21K 73G 115 F 149 I 156 C 196 A 198 IC12H25—C12H25K 80.7G 112.9 F 136.9 I 151 C 180.3 IC13H27—C13H27K 95G 115 F 130 I 153 C 178 IC14H29—C14H29K 90F 120.1 I 144 C 170 IC15H31—C15H31K 91G 117 I 147 C 170 IC16H33—C16H33K 89F 133.6 I 138.8 C 160 IC2H5—OOC—CH═CH——CH═CH—COO—C2H5K 180.6B 189.7 C 232 A 305 N ? ZC5H11—OOC—CH═CH——CH═CH—COO—C5H11K 124.7B 133 C 247 A 307 N 314 ZC2H5—OOC—CMe═CH——CH═OMe—COO—C2H5K 169S 241 S 249 N 308 ZC4H9—O——O—C4H9K 191C 221 N 295 IC6H13—O——O—C6H13K 159S 176 S 232 S 239 N 262 IC8H17—O——O—C8H17K 144S 172 S 234 S 241 N 246 IC12H25—O——O—C12H25K 130S 162 S 215.1 IC2H5—S——S—C2H5K 175.8A 204.5 N 236.2 ICH3—O—CH2—O——O—CH2—O—CH3K 136 2B 140.9 A 147.1 N 222 IC4H9—O—CH2—O——O—CH2—O—C4H9K 106.2A 118.7 IC3H7—OOC——COO—C3H7K 153A 199 N 258 IC4H9—OOC——COO—C4H9K 92C 137 A 190 N 209 IC5H11—OOC——COO—C5H11K 100A 206 N 215 IC6H13—OOC——COO—C6H13K 113C 148 A 189 IC7H15—OOC——COO—C7H15K 92C 140 A 196 IC4H9—C4D9K 112S 146 C 174 A 201 N 238 I32LRCrLCC8H17—O——CH═C(COO—C6H13)2K 52C 51 A 85 N 101 IC8H17—O——CH═C(COO—C7H15)2K 58C 51.5 A 83 N 97 IC8H17—O——CH═C(COO—C8H17)2K 59C 53 A 84 N 94 IC8H17—O——CH═C(COO—C9H19)2K 58C 53 A 86 N 94 IC8H17—O——CH═C(COO—C10H21)2K 63C 55 A 84 N 91 IC8H17—O——CH═C(COO—C11H23)2K 61C 56 A 84 N 90 IC8H17—O——CH═C(COO—C12H25)2K 67C 57 A 85 N 89 IC8H17—O——CH═C(COO—C16H33)2K 83C 65 A 85 N 86 IC8H17—O——CH═C(COO—C18H37)2K 86C 69 A 83 IC9H19—O——CH═C(COO—C5H11)2K 70C 56 A 88 N 107 IC8H17—O——CHCN—CH(COO—C3H7)22K 60A 100 N 131 IC4H9—O——O—C8H17K ?C 65 N 207 IC5H11—O——O—C8H17K 97C 101 N 201 IC6H13—O——O—C8H17K 96C 132 A 144 N 198 IC7H15—O——O—C7H15K 87C 143 A 162 N 193 IC7H15—O——O—C8H17K ?C 142 A 155 N 193 IC8H17—O——O—CH3K 107A 122 N 226 IC8H17—O——O—C2H5K 110A 130 N 213 IC8H17—O——O—C8H17K 87C 145 A 163 N 189.5 IC8H17—O——O—CHMe—COO—C2H5SK 86A 117 N* 122 IC8H17—O——O—CHMe—COO—C8H17SK 71A 94 N* 113 IC8H17—O——CO—CH3K 131A 210 N 227 IC6H13—O——COO—C3H7K 101.5C 188.5 N 193 IC8H17—O——CO—N(—CH3)2K 127A 144 N 204 IC8H17—O——COO—N═C(—CH3)2K 116A 180 N 230 ZC8H17—O——COO—N═C(—C2H5)2K 77.5A 155.5 N 192 ZC8H17—O——COO—N═C(—C3H7)2K 91A 128 N 165 IC8H17—O——COO—N═C(—C7H15)2K 76A 83 N 116.5 IC8H17—O——COO—N═C(—C11H23)2K 73A 78 N 99 IC8H17—O——COO—N═C(—C13H27)2K 59A 78 N 93 I33LRCrLCC6H13—O——O—C6H13K 122.4B 132.6 N 243 IC8H17—O——O—C8H17K 61.2H 100.2 G 121.2 C 158.4 N 223.1 IC10H21—O——O—C10H21K 89.9H 87.2 G 95.5 C 173.4 N 202.1 I34LRCrLCC4H9—C4H9K 89P 107 IC6H13—C6H13K 70P 112 IC7H15—C7H15K 60P 114 IC12H25—C12H25K 53P 108.8 IC16H33—C16H33K 69P 102.5 I35LRCrLCC8H17—C8H17K 57P 61 IC9H19—C9H19K 57P 68 I36LRCrLCRefH—O—C5H12—O——O—C5H12—O—HK 97.9S 178.8 I5165H—CONH——NHOC—HK 274S 286 I4109Br—C3H6—COO——OOC—C3H6—BrK 114S 142 I7455Br—C4H8—COO——OOC—C4H8—BrK 96S 116 I7455Br—C5H10—COO——OOC—C5H10—BrK 57S 103 I7455Br—C7H14—COO——OOC—C7H14—BrK 71S 99 I745537LRCrLCBr—C10H20—COO——OOC—C10H20—BrK 83S 100 IC5H11—HK 11.5N −34 EC6H11—C2H4—O—HK 72S 112.5 IC2H5—O——O—HK 169X 176 IC8H17—O——O—CH2—CHlBu—O—HSK 95S 58 S 103 S 113.1 S 113.6 S 115.6 A 119.5 ICH3—O——O—C6H12—OOC—CMe═CH—HK 66S 73 IC2H5—O——O—C6H12—OOC—CMe═CH—HK 63.1N 87.6 IC5H11—O——O—C6H12—OOC—CMe═CH—HK 53S 57 IC6H13—O——O—C6H12—OOC—CMe═CH—HK 79S 84 IC4H9—CO—HK 4.5N 2 IC5H11—CO—HK 21.5N 23.5 IC6H13—CO—HK −5.5N 17.5 IC7H15—CO—HK 4.5N 33 IC8H17—CO—HK 20.5S 30 N 36 IC9H19—CO—HK 31S 42 N 45 IC10H21—CO—HK 42S 44 IC8H17—O——COO—CH2—CHMe—O—HSK 119A 118 IC2H5—O——OOC—CMe═CH—HK 95X 105 IC8H17—O——OOC—C4H8—OOC—CMe═CH—HK 80.6S 86.2 IC8H17—O——OOC—C2H4—CHMe—CH2—OOC—CMe═CH—H1K 46S 64.1 IC6H13—O——OOC—C11H22—NHOC—CMe═CH—HK 111S 132 X ? IC2H5—CHMe—CHF—CH2—OOC——O—H3K 127.5ICH3—CHMe—CH2—CHCl—CH2—OOC——O—HSK 48.3IC2H5—CHMe—CH2—O——O—C6H12—OOC—CMe═CH—HSK 42.5S 49 IC8F17—C11H22—O——CONH—HK 224IH2C═CH—C4H9—O——O—HK 138IH2C═CH—C9H18—O——O—HK 134S 139 IC5H11—CH═CH—FK ?S 123 IC3H7—SO2—FK 94N −100 EC4H9—C:::C——FK ?S 73.7 IC5H11—C2H4—ClK 49N 14 EC4H9—O——CO—CH2—ClK 115E 110 IC5H11—O——CO—CH2—ClK 98E 72 A 103 IC6H13—O——CO—CH2—ClK 87E 107 A 116 IC7H15—O——CO—CH2—ClK 93E 106 A 122 IC8H17—O——CO—CH2—ClK 88E 105 A 126 IC9H19—O——CO—CH2—ClK 95E 102 A 126 IC10H21—O——CO—CH2—ClK 89E 101 A 128 IC5H11—CO—C2H4—CO——BrK 119A 123.8 IC6H13—CO—C2H4—CO——BrK 120.3A 127.5 IC3H7—COO—CH2—CO——BrK 94.4S 112 IC5H11—COO——BrK 70E 83 B 103 IC6H13—COO——BrK 68.5E 74 B 104 IC7H15—COO——BrK 76S 59.7 B 104.5 IC8H17—COO——BrK 69E 46 B 103 IC9H18—COO——BrK 73.5B 102.5 IC5H11—CH2—BrK 76N 1.5 EC5H11—C:::C—BrK 88X 108 ICH3—O——O—C9H18—BrK 88.4IC6H13—CO—CH2—BrK 64A 52 IC7H15—CO—CH2—BrK 60.5A 59.5 IC8H17—CO—CH2—BrK 65.5A 64 IC9H19—CO—CH2—BrK 64A 67 IC10H21—CO—CH2—BrK 72.5A 70 IC2H5—O——CO—CH2—BrK 137S 112.5 IC3H7—O——CO—CH2—BrK 124S 118.5 IC4H8—O——CO—CH2—BrK 107E 106 IC5H11—O——CO—CH2—BrK 93E 101 IC6H13—O——CO—CH2—BrK 79E 98 A 104 IC7H15—O——CO—CH2—BrK 96E 92 A 104 IC8H17—O——CO—CH2—BrK 80E 95 A 107 IC9H19—O——CO—CH2—BrK 95E 100 A 118 IC10H21—O——CO—CH2—BrK 91E 98 A 116 IC7H15—O——CO—CHCl—Br2K 95A 56 IC8H17—O——CO—CHCl—Br2K 68A 71 IC9H19—O——CO—CHCl—Br2K 68A 78 IC10H21—O——CO—CHCl—Br2K 65A 66 IC2H5—CHMe—C2H4—COO——Br1K 56S 28 IC5H11—O——NO2K 54.5N <42 IC6H13—O——NO2K 67N 32.5 IC7H15—O——NO2K 38.5A 30.5 N 38.5 BC8H17—O——NO2K 51.5A 49.5 N 51.5 BH2C═CH—O—C11H22—O——NO2K 97IC6H13—CH═CF2K 59S 95.8 IC5H11—CH2—CH═CF2K 36.9S 53.1 IC5H11—C2H4—CH═CF2K −25.4S 30.8 S 50.6 IC9H19—O——COO-isopinocampheylRK 67.5A 48.7 N 55.7 ICH3—C5H11K 48N-1 IC2H5—C5H11K <20S 33.9 IC3H7—C5H11K −18S 47.8 IC3H7—C6H13K −10.5E 48 IC3H7—C7H15K −14E 29 B 50.5 IC4H9—C6H13K −2E 40.5 B 48.5 IC4H9—C7H15K −15E 16.5 B 38.5 IC5H11—C5H11K 25.1E 46.1 E 47.1 L 52.3 IC5H11—C6H13K ?E 11.7 E 41.7 E 42.6 L 53.7 IC5H11—C7H15K ?E 36 B 63 IC6H13—C6H13K 25.1E 46.1 E 47.1 L 52.3 IC6H13—C7H15K ?E 29.7 E 30.2 L 58.1 IC7H15—C7H15K ?E 19.5 E 35.1 L 61 IC8H17—C8H17K 57P 61 IC9H18—C9H19K 57P 68 IC5H11—CH2—O—CH3K 48S 47 IC5H11—CH2—O—C3H7K 27S 21 IC5H11—CH2—O—C5H11K 16S 10 IC5H11—O—C2H5K 72S 81 IC5H11—O—C4H9K 37S 80.1 S 88.1 IC5H11—O—C6H13K 82 S 84 IC6H13—O—C6H13K 9E 68 B 83.9 IC7H15—O—C6H13K 58B 88.5 IC8H17—O—C6H13K 46B 84 IC8H17—O—C8H17K 57E 86 IC9H19—O—C6H13K 34B 82 IC3H7—NH—C4H9K 75S 74.1 IC5H11—NH—C4H9K 45A 78 IC3H7—CO—C2H5K 42S 130 IC5H11—CO—CH3K 77B 84 IC5H11—CO—C4H9K 90S 106.2 S 110.5 IC5H11—CO—C6H11K 106B 104 A 109.5 IC5H11—CO—C6H13K 96A 111 IC6H13—CO—CH3K 79B 85.5 IC6H13—CO—C5H11K 106A 105.9 IC7H15—CO—CH3K 76.5B 84.5 IC7H15—CO—C5H11K 94.3B 95.6 A 103.8 IC8H17—CO—CH3K 86.5B 84 IC8H17—CO—C5H11K 87.5B 92.2 A 101.3 IC9H19—CO—CH3K 85B 82.5 IC9H19—CO—C5H11K 80.2B 88.1 A 99.7 IC10H21—CO—C5H11K 77.5B 88.8 A 98.7 IC10H21—CO—C9H19K 57.8E 101 IC5H11—CO—CH2—CO—CH3K 110X 135 IC10H21—CO—CH2—CO—CH3K 86E 97 B 107 A 135 IC5H11—CO—CH2—OOC—C3H7K 85S 147 IC8H17 —CO—CH2—OOC—C3H7K 70S 144 IC6H13—CO—CH═CH—COO—C2H5K 40S 59 IC6H13—CO—CH═CH—COO—C3H7K 40S 66 IC6H13—CO—CH═CH—COO—C4H9K 34S 68 IC6H13—CO—CH═CH—COO—C5H11K 25S 57 IC8H17—CO—CH═CH—COO—C3H7K 62S 72 IC8H17—CO—CH═CH—COO—C4H9K 56S 69 IC8H17—CO—CH═CH—COO—C5H11K 54S 70 IC8H17—CO—CH—CH—COO—C6H13K 36S 71 IC8H17—CO—CH═CH—COO—C7H15K 40S 72 IC8H17—CO—CH═CH—COO—C8H17K 35S 71 IC3H7—COO—C3H7K 63X 61 IC5H11—COO—C3H7K 55X 58 IC5H11—COO—C8H17K 29B 25 IC6H17—COO—C2H5K 64B 61.4 A 61.4 IC8H17—COO—C3H7K 60A 57 IC5H11—COS—C2H5K ?E 103.5 L 113 A 121.4 UC5H11—COS—C3H7K ?E 90 L 110.3 A 118.5 IC5H11—COS—C4H9K ?E 75 L 109 A 120.5 IC5H11—COS—C5H11K ?E 59.8 L 104.5 A 120 IC5H11—COS—C6H13K ?E 50 L 102 A 118 IC5H11—COS—C7H15K ?E 40.1 L 100.2 A 116.7 IC5H11—COS—C8H17K ?E 33 L 99.8 A 116.3 IC5H11—COS—C9H19K ?E 25 L 95.4 A 113.8 IC5H11—COS—C10H21K ?E 15 L 94 A 113.2 IC5H11—OOC—C5H11K 45.7S 67.4 IC8H17—OOC—C7H15K 65E 83 B 91 IC7H15—OOC—CHMe—CHMe—O—CH31K −18C* 9 A 13 IC8H17—OOC—CHMe—CHMe—O—CH31K 32C* 10 A 15 IC5H11—CMe═N—O—C2H5K 73A 91 IC6H13—CMe═N—OOC—C4H9K 89A 88 IC6H13—CMe═N—OOC—C8H17K 70A 86 IC8H17—O——C5H10—CHMe—O—C3H71K 14S 18 S 37 C* 41 IC10H21—O——C5H10—CHMe—O—CH31K 41S 49 C* 53 IC10H21—O——C5H10—CHMe—O—C2H51K 31S 32 S 38 C* 48 IC10H21—O——C5H10—CHMe—O—C3H71K 28S 23 S 35 C* 44 IC10H21—O——C5H10—CHMe—O—C4H91K 33S 25 C* 35 A 39 IC10H21—O——C5H10—CHMe—O—C5H111K 32S 27 C* 30 A 36 IC12H25—O——C6H10—CHMe—O—C3H71K 40C* 44 UC10H21—O——C6H12—CHMe—O—C3H71K 43S 46 S 56 IC2H5—O——O—C2H5K 178X 185 IC6H13—O——O—C6H13K 124N 130 UC8H17—O——O—CHMe—COO—CH3SK 57A 49.2 IC8H17—O——O—CHMe—COO—C2H5SK 39A 42 ICH3—O——CO—C2H5K 145.7E 146.4 ICH3—O——CO—C3H7K 126.2E 122.2 A 125.9 ICH3—O——CO—C4H9K 120.5A 117.7 ICH3—O——CO—C5H11K 123A 119 ICH3—O——CO—C6H13K 118A 117 ICH3—O——CO—C7H15K 120A 117.7 ICH3—O——CO—C8H17K 116A 116.2 ICH3—O——CO—C9H19K 118A 116.7 IC2H5—O——CO—CH3K 96E 156.2 IC2H5—O——CO—C2H5K 124E 172.4 IC2H5—O——CO—C3H7K 123E 156.2 IC2H5—O——CO—C4H9K 108E 136 A 153 IC2H5—O——CO—C5H11K 110E 129.9 A 150.6 IC2H5—O——CO—C6H13K 107E 124 A 148 IC2H5—O——CO—C7H15K 111.5E 121 A 146.4 IC2H5—O——CO—C8H17K 108E 120.2 A 144.8 IC2H5—O——CO—C9H19K 118E 121.7 A 143.1 IC3H7—O——CO—CH3K 107E 155.6 IC3H7—O——CO—C2H5K 119E 177.3 IC3H7—O——CO—C3H7K 136.5E 153.9 A 158.2 IC3H7—O——CO—C4H9K 126E 135.7 A 154.6 IC3H7—O——CO—C5H11K 116E 125.9 A 150.3 IC3H7—O——CO—C6H13K 113E 120.1 A 147.3 IC3H7—O——CO—C7H15K 118E 121 A 145.2 IC3H7—O——CO—C8H17K 115E 120.3 A 143 IC3H7—O——CO—C9H19K 106E 119.5 A 141 IC4H9—O——CO—CH3K 97E 144 IC4H9—O——CO—C2H5K 114E 167.3 A 171.4 IC4H9—O——CO—C3H7K 101.5E 145.7 A 155.9 IC4H9—O——CO—C4H9K 124E 136.2 A 156.8 IC4H9—O——CO—C5H11K 115E 120 A 150.8 IC4H9—O——CO—C6H13K 109E 115 A 151.5 IC4H9—O——CO—C7H15K 99E 113.7 A 148.3 IC4H9—O——CO—C8H17K 102.5E 111.8 A 146.8 IC4H9—O——CO—C9H19K 107E 111.5 A 144.7 IC5H11—O——CO—CH3K 90E 139.5 IC5H11—O——CO—C2H5K 91E 155.6 A 169 IC5H11—O——CO—C3H7K 93E 129.5 A 150.8 IC5H11—O——CO—C4H9K 124E 121 A 152.1 IC5H11—O——CO—C5H11K 128.8E 127 A 147.8 IC5H11—O——CO—C6H13K 117E 113 A 146.3 IC5H11—O——CO—C7H15K 111E 108 A 143.8 IC5H11—O——CO—C8H17K 104E 101 A 144 IC5H11—O——CO—C9H19K 102.7E 101.5 A 141.8 IC6H13—O——CO—CH3K 91E 137 IC6H13—O——CO—C2H5K 78E 149 A 165.5 IC6H13—O——CO—C3H7K 82E 121.8 A 147 IC6H13—O——CO—C4H9K 109E 116 A 149.6 IC6H13—O——CO—C5H11K 120.5A 145.3 IC6H13—O——CO—C6H13K 124.5A 145.2 IC6H13—O——CO—C7H15K 123A 142.5 IC6H13—O——CO—C8H17K 113. 5A 141.2 IC6H13—O——CO—C9H19K 110.2A 139.5 IC7H15—O——CO—CH3K 99E 136 IC7H15—O——CO—C2H5K 98E 146.8 A 163.7 IC7H15—O——CO—C3H7K 87E 120.2 A 145.2 IC7H15—O——CO—C4H9K 106E 110 A 147 IC7H15—O——CO—C5H11K 112.5A 142.3 IC7H15—O——CO—C6H13K 123A 138 IC7H15—O——CO—C7H15K 126.5A 139.7 IC7H15—O——CO—C8H17K 119A 138.7 IC7H15—O——CO—C9H19K 114A 134.7 IC8H17—O——CO—CH3K 96E 136.5 IC8H17—O——CO—C2H5K 104E 144.8 A 161.8 IC8H17—O——CO—C3H7K 96E 118.9 A 142.9 IC8H17—O——CO—C4H9K 106.5E 107 A 145.7 IC8H17—O——CO—C5H11K 104A 140 IC8H17—O——CO—C6H13K 116A 140.3 IC8H17—O——CO—C7H15K 125A 138.5 IC8H17—O——CO—C8H17K 124.5A 137.4 IC8H17—O——CO—C9H19K 124.5A 134.9 IC9H19—O——CO—CH3K 104.2E 135 IC9H19—O——CO—C2H5K 112E 144.3 A 160 IC9H19—O——CO—C3H7K 103.5E 118.2 A 141 IC9H19—O——CO—C4H9K 101E 106.4 A 143.9 IC9H19—O——CO—C5H11K 106A 138.5 IC9H19—O——CO—C6H13K 112.8A 139 IC9H19—O——CO—C7H15K 124A 136 IC9H19—O——CO—C8H17K 124.5A 135.4 IC9H19—O——CO—C9H19K 128.5A 132.8 IC10H21—O——CO—CH3K 103E 132 IC10H21—O——CO—C2H5K 92E 143.4 A 157.5 IC10H21—O——CO—C3H7K 90E 117.5 A 138.8 IC10H21—O——CO—C4H9K 97E 106 A 141.2 IC10H21—O——CO—C5H11K 101.9A 136.6 IC10H21—O——CO—C6H13K 108.7A 137 IC10H21—O——CO—C7H15K 110.5A 134 IC10H21—O——CO—C8H17K 118A 133.3 IC10H21—O——CO—C9H19K 123.5A 130.9 IC11H23—O——CO—CH3K 110.5E 130.6 IC12H25—O——CO—CH3K 109.8E 129.9 IC12H25—O——CO—C2H5K 95.5E 139.3 A 151.5 IC12H25—O——CO—C3H7K 105.5E 115.5 A 134.8 IC12H25—O——CO—C4H9K 102E 105 S 115 A 141 IC12H25—O——CO—C5H11K 98A 132.5 IC12H25—O——CO—C6H13K 105A 131 IC12H25—O——CO—C7H15K 108.5A 129.7 IC12H25—O——CO—C8H17K 112.5A 129.8 IC12H25—O——CO—C9H19K 115.5A 127.4 IC14H29—O——CO—CH3K 112.1E 123.2 BC16H33—O——CO—CH3K 116.8E 122.5 IC4H9—O———CO—CH2CO—C4H9K 126.1A 155.4 IC6H13—O——CO—CH2—CO—C2H5K 108.6E 128.1 A 175.2 IC8H17—O——CO—CH2—CO—CH3K 108.7E 140.7 A 176.5 IC8H17—O——CO—CH2—CO—C2H5K 101E 124.3 A 173.1 IC8H17—O——CO—CH2—CO—C4H9K 110.2A 152.5 IC8H17—O——CO—CH2—CO—C8H17K 125.3A 137 IC9H19—O——CO—CH2—CO—CH3K 104.5E 141 A 175.5 IC10H21—O——CO—CH2—CO—CH3K 100.5E 137.4 A 173.8 IC10H21—O——CO—CH2—CO—C2H5K 98.5E 123.4 A 168.3 IC11H23—O——CO—CH2—CO—CH3K 108.5E 135.6 A 172 IC11H23—O——CO—CH2—CO—C2H5K 105.1E 123.7 A 166.8 IC12H25—O——CO—CH2—CO—CH3K 105E 135 A 167.5 IC12H25—O——CO—CH2—CO—C2H5K 95.8E 120 A 161.5 IC12H25—O——CO—CH2—CO—C3H7K 112.5E 103.3 A 147 IC12H25—O——CO—CH2—CO—C4H9K 105.2A 133.8 IC12H25—O——CO—CH2—CO—C12H25K 124.4A 125.8 IC14H29—O——CO—CH2—CO—C2H5K 106A 120.5 A 158.5 IC16H33—O——CO—CH2—CO—CH3K 118.9E 139.1 A 162 IC18H37—O——CO—CH2—CO—CH3K 121.7E 137 A 157.8 IC18H37—O——CO—CH2—CO—C2H5K 113E 114.5 A 150.7 ICH3—O——COO—C6H13K 61.7E 45.4 IC2H5—O——COO—C3H7K 102S 103 IC3H7—O——COO—C3H7K 105S 107 IC4H9—O——COO—C3H7K 97A 113.5 IC4H9—O——COO—C4H9K 93E 92 A 102 IC5H11—O——COO—C2H5K 114.5A 123.5 IC5H11—O——COO—C3H7K 80A 106.5 IC5H11—O——COO—C6H13K 63.7E 63.3 B 68.4 A 85.4 IC5H11—O——COO—C7H15K ?E 59 B 65 A 81 IC5H11—O——COO—C12H25K 70.4E 54.4 A 70.6 IC6H13—O——COO—CH3K 124E 132 B 139 A 139 IC6H13—O——COO—C2H5K 81E 92 B 97 A 119 IC6H13—O——COO—C3H7K 80E 67 B 74 A 107 IC6H13—O——COO—C4H9K 58B 64 A 92 IC6H13—O——COO—C5H11K 83B 58 A 90 EC6H13—O——COO—C6H13K 79B 57.5 A 86 EC6H13—O——COO—C7H15K 76B 57 A 84 EC6H13—O——COO—C8H17K 74B 56 A 82 IC6H13—O——COO—C9H19K 71B 55 A 80 IC6H13—O——COO—C10H21K 59B 54.5 A 78 IC7H15—O——COO—CH3K 124E 127 B 133 A 133 IC7H15—O——COO—C2H5K 52E 88 B 94 A 111 IC7H15—O——COO—C3H7K 78E 54 B 64 A 102 IC7H15—O——COO—C4H9K 62C 59 A 89 IC7H15—O——COO—C5H11K 79C 50 A 87 EC7H15—O——COO—C6H13K 86C 60 A 84 EC7H15—O——COO—C7H15K 86C 55 A 82 EC7H15—O——COO—C8H17K 76A 80 IC7H15—O——COO—C9H19K 69A 78 IC7H15—O——COO—C10H21K 69A 76 IC8H17—O——COO—CH3K 117E 126 B 132 A 132 IC8H17—O——COO—C2H5K 75E 88 B 96 A 112 IC8H17—O——COO—C3H7K 83B 64 A 101 IC8H17—O——COO—C4H9K 56C 56 A 86 IC8H17—O——COO—C5H11K 66C 55 A 88 EC8H17—O——COO—C6H13K 72C 56 A 82 EC8H17—O——COO—C7H15K 87C 46 A 83 EC8H17—O——COO—C8H17K 80A 80 IC8H17—O——COO—C9H19K 79A 80 IC8H17—O——COO—C10H21K 75A 79 IC8H17—O——COO—C11H23K 74A 79 IC8H17—O——COO—C12H25K 78A 76 IC8H17—O——COO—C13H27K 77A 76 IC8H17—O——COO—C14H29K 80A 74 IC8H17—O——COO—C15H31K 77A 74 IC8H17—O——COO—C16H33K 83A 72 IC8H17—O——COO—C17H35K 81A 72 EC8H17—O——COO—C18H37K 80A 70 EC8H17—O——COO—C19H39K 81A 69 EC9H19—O——COO—CH3K 124E 123 B 129 A 129 IC9H19—O——COO—C2H5K 78E 81 B 91 A 106 IC9H19—O——COO—C3H7K 67B 63 A 99 IC9H19—O——COO—C4H9K 64C 56 A 86 IC9H19—O——COO—C5H11K 62C 55 A 86 EC9H19—O——COO—C6H13K 71C 57 A 83 EC9H19—O——COO—C7H15K 84C 54 A 82 EC9H19—O——COO—C8H17K 86C 36 A <84 EC10H21—O——COO—CH3K 122E 117 B 124 A 124 IC10H21—O——COO—C2H5K 71E 80 B 90 A 104 IC10H21—O——COO—C3H7K ?B 67.9 A 99 IC10H21—O——COO—C4H9K 54C 49 A 82 IC10H21—O——COO—C5H11K 66C 53 A 82 IC10H21—O——COO—C6H13K 60C 67 A 84 IC10H21—O——COO—C7H15K 74C 66 A 80 EC10H21—O——COO—C8H17K 83C 67 A 78 EC10H21—O——COO—C9H19K 86C 52 A ? EC10H21—O——COO—C10H21K 85C 54 A ? EC12H25—O——COO—CH3K 122.5S 124 IC12H25—O——COO—C2H5K 80.5S 102.5 IC12H25—O——COO—C3H7K 71S 97 IC12H25—O——COO—C6H13K 69G 57.8 C 67.5 A 80 IC12H25—O——COO—C7H15K 77G 72 C 74 A 81 IC12H25—O——COO—C8H17K 76.3C 72.6 A 80 IC14H29—O——COO—C6H13K 68G 58.8 C 68.2 A 81 IC14H29—O——COO—C7H15K 71.2C 72.5 A 82.5 IC14H29—O——COO—C8H17K 76C 74.5 A 80.5 IC16H33—O——COO—C2H5K 88B 82 A 94 IC16H33—O——COO—C3H7K 80B 46 A 89 EC16H33—O——COO—C4H9K 78A 79 IC16H33—O——COO—C5H11K 79G 40 A 81 EC16H33—O——COO—C6H13K 75G 60 A 78 EC16H33—O——COO—C7H15K 77G 72 A 80 IC16H33—O——COO—C8H17K 74G 76 A 78 IC16H33—O——COO—C9H19K 83G 78 A 80 IC16H33—O——COO—C10H21K 83G 77 A 78 EC16H33—O——COO—C11H23K 86G 72 A 79 EC16H33—O——COO—C12H25K 89G 64 A 77 EC16H33—O——COO—C13H27K 91G 40 A 78 EC18H37—O——COO—C2H5K 72B 55 A 87 EC18H37—O——COO—C3H7K 83A 86 IC9H19—O——OOC—CHCl—CHMe—CH31K 80S 62.5 C* 68 A 82.5 IC10H21—O——OOC—CHCl—CHMe—CH31K 82C* 69 A 81 IC11H23—O——OOC—CHCl—CHMe—CH3SK 86A 85 IC12H25—O——OOC—CHCl—CHMe—CH31K 92A 85 IC7H15—O——OOC—CHCl—CHMe—CH32K ?G 70.2 C 72.4 A 82 IC5H11—O——OOC—CHCl—CHMe—C2H53K ?C* 55 A 64 BC6H13—O——OOC—CHCl—CHMe—C2H53K 47S 48 C* 51.5 A 61 IC7H15—O——OOC—CHCl—CHMe—C2H53K 55C* 55 A 62 IC8H17—O——OOC—CHCl—CHMe—C2H53K 48S 36 C* 56 A 66 IC9H19—O——OOC—CHCl—CHMe—C2H53K 52C* 53.5 A 65 IC10H21—O——OOC—CHCl—CHMe—C2H53K 50C* 43 A 49 UC12H25—O——OOC—CHCl—CHMe—C2H53K 62C* 66 A 67 IC14H29—O——OOC—CHCl—CHMe—C2H53K 66A 68 IC8H17—O——OOC—CHCl—CHMe—C2H55K ?C* 59 A 60 IC6H13—O——OOC—CHBr—CHMe—CH3SK 64C* 67 IC8H17—O——OOC—CHBr—CHMe—CH3SK 35C* 48 A 56 IC10H21—O——OOC—CHBr—CHMe—CH3SK 55C* 57 A 68 IC12H25—O——OOC—CHBr—CHMe—CH3SK 69A 70 IC6H13—O——OOC—CHBr—CHMe—C2H53K ?C* 55 BC8H17—O——OOC—CHBr—CHMe—C2H53K 20C* 42 A 53 IC10H21—O——OOC—CHBr—CHMe—C2H53K ?C* 49 A 58 BC12H25—O——OOC—CHBr—CHMe—C2H53K ?C* 47 A 59 BC8H17—O——OOC—CHMe—CHMe—C2H53K 48 I* 36 C* 53 A 64 IC8H17—O——OCOO—CH2—CHCl—CHMe—C2H53K 43C* 50 I2(C2H5—OOC)—CH—C6H12—O——O—CHMe—C6H13SK −20X 19 IC5H11—COO——CO—CHMe—C2H5SK ?S 15 S 32 A 57 IC8H17—COO——CO—CHMe—C2H5SK 47.8A 65.1 IC13H27—COO——CO—CHMe—C2H5SK 69.4A 66.7 IC7H15—COO——COO—CHMe—C2H5RK 46.7C* 22.4 A 44.6 IC8H17—COO——COO—CHMe—C2H5RK 56.2C* 26.4 A 45.6 IC18H37—O——COO—C4H9K 83A 78 IC18H37—O——COO—C5H11K 83A 79 IC18H37—O——COO—C6H13K 84G 50 A 76 EC18H37—O——COO—C7H15K 82G 67 A 78 EC18H37—O——COO—C8H17K 84G 75 A 76 EC18H37—O——COO—C9H19K 80G 77 A 78 IC18H37—O——COO—C10H21K 84G 75 A 78 EC18H37—O——COO—C11H23K 81G 56 A 78 EC18H37—O——COO—C12H25K 88A 78 EC5H11—O——COS—C6H13K 91L 121 A 149.5 IC5H11—O——OOC—C5H11K ?E 97.7 B 106 IC8H17—O——OOC—C9H19K 87G 107 F 108.5 IC8H17—O——OOC—C11H23K 78G 105 F 108.5 IC8H17—O——OOC—C13H27K 82G 104 F 108 IC7H15—NH——NH—C7H15K 96.8C 93 N 103.8 IC8H17—NH——NH—C8H17K 99I 98.1 C 110 N 110.4 IC9H19—NH——NH—C9H19K 93.8I 102 C 112.8 IC10H21—NH——NH—C10H21K 97.1I 108.8 C 116.8 IC11H23—NH——NH—C11H23K 95.4F 92.8 I 109.9 C 117 IC12H25—NH——NH—C12H25K 96.4I 113.5 C 117.8 IC16H33—NH——NH—C16H33K 103I 115.8 IC18H37—NH——NH—C18H37K 105.2I 114.6 ICH3—O—C2H4—O——O—C2H4—O—CH3K 127K 139 IC2H5—O—C2H4—O——O—C2H4—O—C2H5K 75K 118 IC6H13—OCOO—C2H4—O——O—C2H4—OCOO—C6H13K 83S 109 IC7H15—OCOO—C2H4—O——O—C2H4—OCOO—C7H15K 77S 85 IC8H17—OCOO—C2H4—O——O—C2H4—OCOO—C8H17K 83S 88 ICH3—OCOO—C6H12—O——O—C6H12—OCOO—CH3K 107S 159 IC2H5—OCOO—C6H12—O——O—C6H12—OCOO—C2H5K 98S 166 IC3H7—OCOO—C6H12—O——O—C6H12—OCOO—C3H7K 95S 157 IC4H9—OCOO—C6H12—O——O—C6H12—OCOO—C4H9K 90S 170 IC5H11—OCOO—C6H12—O——O—C6H12—OCOO—C5H11K 89S 150 IC6H13—OCOO—C6H12—O——O—C6H12—OCOO—C6H13K 89S 168 IC7H15—OCOO—C6H12—O——O—C6H12—OCOO—C7H15K 85S 150 IC8H17—OCOO—C6H12—O——O—C6H12—OCOO—C8H17K 88S 172 IC9H19—CO——CO—C9H19K 149.3C 147.6 IC10H21—CO——CO—C10H21K 141S 142 IC5H11—CO——OOC—C5H11K 87.5E 91 B 111.5 A 140 IC2H5—CO——NHOC—C3H7K 233S 225 IC2H5—OOC——COO—C2H5K 114X <? UCH3—OOC——OOC—C4H9K 86.5S 112 L 116 IC2H5—OOC——OOC—C4H9K 96L 100 IC3H7—OOC——OOC—C4H9K 59.8B 63.3 A 81 IC4H9—OOC——OOC—C4H9K 80.3S 63.4 L 69.4 A 74.4 IC5H11—OOC——OOC—C4H9K 49.7S 52.8 L 55.4 A 70.2 IC6H13—OOC——OOC—C4H9K 49.1L 58.7 A 68.4 IC7H15—OOC——OOC—C4H9K 47.3L 52.8 A 66.8 IC7H15—OOC——OOC—C5H11K 50B 80.5 A 83 IC7H15—OOC——OOC—C7H15K 57B 76.5 A 79 IC8H17—OOC——OOC—C4H9K 61.4L 52.3 A 68.6 IC8H17—OOC——OOC—C7H15K 52B 70.5 A 76 IC8H17—OOC——OOC—C9H19K 49B 82 A 85 IC9H19—OOC——OOC—C4H9K 49.5B 48.4 A 51.8 IC10H21—OOC——OOC—C4H9K 68.4A 60.2 IC10H21—OOC——OOC—C5H11K 55B 65 A 58 IC10H21—OOC——OOC—C9H19K 82.5B 77.5 A 81 IC11H23—OOC——OOC—C4H9K 59.5A 82.8 IC8H17—COO——COO—CH2—CHMe—O—CH31K 49.6A 48.3 IC8H17—COO——COO—CH2—CHMe—O—C3H71K 28I* 21.1 A 44.2 IC8H17—COO——COO—CH2—CHMe—O—C6H131K 7A 39.7 IC9H19—COO——COO—CH2CHMe—O—CH31K 35.8A 52.8 IC9H19—COO——COO—CH2—CHMe—O—C3H71K 33.1I* 28 A 50 IC9H19—COO——COO—CH2—CHMe—O—C6H131K 35.7A 44.4 IC10H21—COO——COO—CH2—CHMe—O—CH31K 53A 54.4 IC10H21—COO——COO—CH2—CHMe—O—C3H71K 39.8I* 32.1 A 49.6 IC10H21—COO——COO—CH2—CHMe—O—C6H131K 38.9A 46.3 IC11H23—COO——COO—CH2—CHMe—O—CH31K 47A 58 IC11H23—COO——COO—CH2CHMe—O—C3H71K 47A 58 IC11H23—COO——COO—CH2—CHMe—O—C6H131K 47.1A 48.4 IC13H27—COO——COO—CH2—CHMe—O—C3H71K 58.2A 60.4 ICH3—COO——OOC—CH3K 163X <? IC5H11—COO——OOC—C5H11K 117S 118 IC6H13—COO——OOC—C6H13K 105S 118 IC7H15—COO——OOC—C7H15K 95S 122 IC8H17—COO——OOC—C8H17K 95S 121 IC9H19—COO——OOC—C9H19K 98S 122 IC5H11—COO——OOC—CHMe—CHMe—O—CH31K 47C* 55 IC6H13—COO——OOC—CHMe—CHMe—O—CH31K 23S 31 C* 39 IC7H15—COO——OOC—CHMe—CHMe—O—CH31K 37C* 46 IC8H17—COO——OOC—CHMe—CHMe—O—CH31K 38C* 47 IC8H17—COO——OOC—CHMe—CHMe—O—C4H91K 47S 49 C* 56 ICH3—OCOO——OCOO—CH3K 148X <? IC2H5—OCOO——OCOO—C2H5K 96X <? IC4H9—COO—N═CMe——CMe═N—OOC—C4H9K 111A 121 IC8H17—COO—N═CMe——CMe═N—OOC—C8H17K 104A 132 IC8H17—O—CHMe—C6H131K ?IC7H15—OOC—CHMe—C2H51K 28.5S 57.3 IC9H19—O——C2H4—COO—CHMe—C6H131K 72.4N* 145.9 UC12H25—O——CO—CHMe—C3H72K 47A 49 IC6H13—O——COO—CHMe—C2H51K 43A 38 UC8H17—O——COO—CHMe—C2H5SK 64.5C* 30 A 53 IC9H19—O——COO—CHMe—C6H131K ?C* ? N* ? UC8H17—O——COO—CHMe—CH3K 75C 41 A 69 IC8H17—O——COO—CHMe—C2H52K 67C 31 A 50 IC8H17—O——COO—CHMe—C3H72K 43C 26 A 36 IC8H17—O——COO—CHMe—C4H92K 49A 34 EC8H17—O——COO—CHMe—C5H112K 61A 30 EC8H17—O——COO—CHMe—C6H132K 57A 37 EC8H17—O——COO—CHMe—C7H152K 61A 37 EC6H13—O——COO—CH2—CHCl—CHMe—CH31K 46C* 15 A 15 UC8H17—O——COO—CH2—CHCl—CHMe—CH31K 34C* 34 A 54 IC9H19—O——COO—CH2—CHCl—CHMe—CH31K 39C* 44 A 58 IC10H21—O——COO—CH2—CHCl—CHMe—CH31K 36C* 45 A 58 IC11H23—O——COO—CH2—CHCl—CHMe—CH31K 55C* 49 A 60 IC12H25—O——COO—CH2—CHCl—CHMe—CH31K 52C* 47 A 61 IC13H27—O——COO—CH2—CHCl—CHMe—CH31K 57A 61 IC6H13—O——COO—CH2—CHCl—CHMe—C2H53K 31C* 10 A 40 IC7H15—O——COO—CH2—CHCl—CHMe—C2H53K 75C* 39 A 56 IC8H17—O——COO—CH2—CHCl—CHMe—C2H53K 15S 16 C* 32 A 50 IC9H19—O——COO—CH2—CHCl—CHMe—C2H53K 27C* 40 A 53 IC10H21—O——COO—CH2—CHCl—CHMe—C2H53K 39C* 41 A 54 IC11H23—O——COO—CH2—CHCl—CHMe—C2H53K 35C* 42 A 55 IC12H25—O——COO—CH2—CHCl—CHMe—C2H53K 40C* 43 A 57 IC13H27—O——COO—CH2—CHCl—CHMe—C2H53K 45C* 47 A 60 IC8H17—O——COO—CHMe—COO—CHMe—C6H133K 42A 21 IC8H17—O——OOC—CHMe—C2H51K 69.4C* 84.4 IC10H21—O——OOC—CHMe—C2H5SK 74.8H 75.8 C* 79.4 A 83.2 IC11H23—O——OOC—CHMe—C2H51K 70C* 72 IC12H25—O——OOC—CHMe—C2H51K 68C* 69 IC14H29—O——OOC—CHMe—C2H51K 84A 81.4 IC7H15—O——OOC—CHF—CHMe—CH3SK 89S 105 A 107 IC8H17—O——OOC—CHF—CHMe—CH3SK 95S 103 N* 109 IC8H17—O——OOC—CHF—CHMe—C2H53K ?C* ? IC10H21—O——OOC—CHF—CHMe—C2H53K ?IC12H25—O——OOC—CHF—CHMe—C2H53K 61A 72 IC8H17—O——OOC—CHF—CHMe—C2H55K 84C* 86 A 94 IC12H25—O——OOC—CHF—CHMe—C2H55K 71C* 81 A 93 IC6H13—O——OOC—CHCl—CHMe—CH31K ?G* 77.6 A 83.3 IC7H15—O——OOC—CHCl—CHMe—CH31K 72H 64 G* 71 C* 73 A 81.5 IC8H17—O——OOC—CHCl—CHMe—CH31K 76S 66 C* 71 A 83 IC8H17—COO——COO—CHMe—C3H71K 46.2A 38.4 IC8H17—COO——COO—CHMe—C4H91K 29.6A 32.6 IC8H17—COO——COO—CHMe—C5H111K 37A 31.9 IC8H17—COO——COO—CHMe—C6H131K 34.3A 26.3 IC8H17—COO——COO—CHMe—C7H151K 34A 26 IC9H19—COO——COO—CHMe—C2H5RK 31.3J* 21.1 C* 35.2 A 48.9 IC10H21—COO——COO—CHMe—C2H5RK 44.6J* 31.1 C* 36.9 A 48.5 IC11H23—COO——COO—CHMe—C2H5RK 41.2J* 38.6 C* 41.2 A 50.5 IC12H25—COO——COO—CHMe—C2H5RK 43.5J* 41.3 A 50 IC13H27—COO——COO—CHMe—C2H5RK 49.8J* 46.7 A 52.7 IC6H13—COO——COO—CH2—CHCl—CHMe—CH31K 46C* 15 A 45 IC8H17—COO——COO—CH2—CHCl—CHMe—CH31K 37I* 10 C* 40 A 54 IC9H19—COO——COO—CH2—CHCl—CHMe—CH31K ?C* ? IC10H21—COO——COO—CH2—CHCl—CHMe—CH31K 36C* 45 A 58 IC6H13—COO——COO—CH2—CHCl—CHMe—C2H53K 31C* 10 A 40 IC8H17—COO——COO—CH2—CHCl—CHMe—C2H53K 36S 13 C* 36 A 49 IC10H21—COO——COO—CH2—CHCl—CHMe—C2H53K 36C* 41 A 52 IC8H17—COO——COO—CH2—CHCl—CHMe—C2H55K 6C* 37 A 47 IC8H17—COO——COO—CH2—CH(OMe)—CHMe—CH3RK 25S 10 C* 19 A 39 IC8H17—COO——COO—CH2—CH(OMe)—CHMe—C2H53K 38C* 18 A 37 IC8H17—COO——OOC—CHCl—CHMe—CH31K 66S 85 C* 95 IC9H19—COO——OOC—CHCl—CHMe—CH31K 68S 82 C* 91 A 92 IC6H13—COO——OOC—CHCl—CHMe—C2H53K 36S 51 C* 67 IC7H15—COO——OOC—CHCl—CHMe—C2H53K ?C* ? IC8H17—COO——OOC—CHCl—CHMe—C2H53K 41S 49 C* 71 IC10H21—COO——OOC—CHCl—CHMe—C2H53K 48S 53 C* 80 IC6H13—COO——OCOO—CH2—CHCl—CHMe—C2H53K 53S 49 IC8H17—COO——OCOO—CH2—CHCl—CHMe—C2H53K 48S 46 C* 53 IC9H18—COO——OCOO—CH2—CHCl—CHMe—C2H53K 54S 54 C* 56 IC8H17—OCOO——CO—CHMe—C2H5SK 47.3A 41.6 ICH3—OCOO——COO—CHMe—C6H131K <20IC9H19—OCOO——COO—CH2—CHCl—CHMe—CH31K 66C* 36 IC9H19—OCOO——OOC—CHCl—CHMe—CH31K 50I* 55 C* 58 IC8H17—OCOO——OOC—CHCl—CHMe—C2H53K 29C* 29 A 41 IC9H19—OCOO——OOC—CHCl—CHMe—C2H53K 25I* 27 C* 43 IC8H17—OCOO——OOC—CHCl—CHMe—C2H55K 22I* 25 C* 37 IC9H19—OCOO——OOC—CHCl—CHMe—C2H55K 15I* 25 C* 39 IC8H17—CO—CH═CH—COO—CH2—CHMe—CH3K 68.5N 43 IC7H15—OOC—CH2—CHMe—C2H5SK 40.4S 68.7 IC8H17—O——O—CH2—CHMe—C2H5SK 70.2S 83.7 H 86 IC10H21—O——O—CH2—CHMe—C2H5SK 78H 78.3 C* 80.3 IC12H25—O——O—CH2—CHMe—C2H5SK 75.3S 73.9 H 77.4 C* 78.9 A 79.8 IC8H17—O——CO—CH2—CHMe—C2H5SK 70.4C* 68.3 A 98.3 IC12H25—O——CO—CH2—CHMe—C2H52K 74A 86 IC4H9—O——COO—CH2—CHMe—C2H5SK 55.5S 73.8 IC5H11—O——COO—CH2—CHMe—C2H5SK 57.5A 85.3 IC6H13—O——COO—CH2—CHMe—C2H5SK 48A 66 IC7H15—O——COO—CH2—CHMe—C2H5SK 41.5C* 43 A 64.2 IC8H17—O——COO—CH2—CHMe—C2H5SK 49.2C* 44 A 65.9 IC9H19—O——COO—CH2—CHMe—C2H5SK 60C* 38 A 64.4 IC10H21—O——COO—CH2—CHMe—C2H5SK 48.2C* 41.2 A 66.2 IC11H23—O——COO—CH2—CHMe—C2H5SK 40C* 50 A 63 UC12H25—O——COO—CH2—CHMe—C2H5SK 53.2C* 39 A 63.8 IC13H27—O——COO—CH2—CHMe—C2H5SK 50C* 51 A 64 UC14H29—O——COO—CH2—CHMe—C2H5SK 61.1A 61.7 IC6H13—O——COO—CH2—CHCl—CH2—CHMe—CH31K 36C* 4 A 30 IC8H17—O——COO—CH2—CHCl—CH2—CHMe—CH31K 35S 0 C* 30 A 40 IC9H19—O——COO—CH2—CHCl—CH2—CHMe—CH31K 50C* 36 A 45 IC10H21—O——COO—CH2—CHCl—CH2—CHMe—CH31K 28C* 40 A 47 IC11H23—O——COO—CH2—CHCl—CH2—CHMe—CH31K 35A 47 IC12H25—O——COO—CH2—CHCl—CH2—CHMe—CH31K 48C* 42 A 48 IC8H17—O——OOC—CH2—CHMe—C2H5SK 56.2S 91.8 C* 94.8 IC10H21—O——OOC—CH2—CHMe—C2H5SK 65.7H 63.4 C* 83.9 A 99.8 IC14H29—O——OOC—CH2—CHMe—C2H5SK 77.5C* 83.4 A 89.5 IC5H11—O——OOC—CHCl—CH2—CHMe—CH31K ?E 62.9 L 71.3 A 74.5 IC6H13—O——OOC—CHCl—CH2—CHMe—CH31K 71C* 65 A 74 IC7H15—O——OOC—CHCl—CH2—CHMe—CH31K 54C* 57 A 67.5 IC8H17—O——OOC—CHCl—CH2—CHMe—CH31K 64C* 56.5 A 67 IC9H19—O——OOC—CHCl—CH2—CHMe—CH31K 67C* 54 A 66.5 IC2H5—OOC——OOC—CHMe—O—CH2—CHMe—C2H53K ?IC7H15—COO——CH2—CHMe—C2H5SK 30B 66 IC4H9—COO——O—CH2—CHMe—C2H5SK 86B 85 IC9H19—COO——O—CH2—CHMe—C2H51K ?B 117 IC6H13—COO——COO—CH2—CHMe—C2H5SK 22.4C* 18.4 A 51.9 IC7H15—COO——COO—CH2—CHMe—C2H5SK 33.7C* 33.1 A 57.1 IC8H17—COO——COO—CH2—CHMe—C2H5SK 35.9C* 41.8 A 59.7 IC9H19—COO——COO—CH2—CHMe—C2H5SK 34.2C* 47.4 A 61.6 IC10H21—COO——COO—CH2—CHMe—C2H5SK 43.9C* 49.6 A 62.3 IC11H23—COO——COO—CH2—CHMe—C2H5SK 45C* 50.4 A 63.8 IC12H25—COO——COO—CH2—CHMe—C2H5SK 41.2C* 50.5 A 63.6 IC13H27—COO——COO—CH2—CHMe—C2H5SK 52.9C* 51.1 A 64.8 IC15H31—COO——COO—CH2—CHMe—C2H5SK 60.9A 64.2 IC6H13—COO——COO—CH2—CHCl—CH2—CHMe—CH31K 34C* 4 A 30 IC8H17—COO——COO—CH2—CHCl—CH2—CHMe—CH31K 35S 0 C* 30 A 40 IC10H21—COO——COO—CH2—CHCl—CH2—CHMe—CH31K 28C* 40 A 46 IC8H17—COO——COO—CH2—CH(OMe)—CH2—CHMe—CH31K 31.7A 31.7 IC9H19—COO——COO—CH2—CH(OMe)—CH2—CHMe—CH31K 38.2A 37.2 IC10H21—COO——COO—CH2—CH(OMe)—CH2—CHMe—CH31K 41.5A 43.4 IC12H25—COO——COO—CH2—CH(OMe)—CH2—CHMe—CH31K 51.7A 39.8 EC8H17—COO——OOC—CHCl—CH2—CHMe—CH31K 55S 55 C* 68 A 70 IC9H19—COO——OOC—CHCl—CH2—CHMe—CH31K 54S 55 C* 68 A 71 IC8H17—OCOO——CH2—CHMe—C2H5SK 36.8C* 24.5 N* 27 IC6H13—OCOO——O—CH2—CHMe—C2H5SK 49C* 48 IC8H17—OCOO——O—CH2—CHMe—C2H5SK 55C* 47 N* 49.5 IC9H19—OCOO——O—CH2—CHMe—C2H5SK 59C* 46 N* 49 IC8H17—OCOO——OOC—CHCl—CH2—CHMe—CH31K 20I* 22 C* 34 IC9H19—OCOO——OOC—CHCl—CH2—CHMe—CH31K 0I* 21 C* 35 IC7H15—O——C2H4—CHMe—C2H5SK 14.1S 54 S 64.9 IC8H17—O——C2H4—CHMe—C2H5SK 43S 57.9 H 62.5 C* 65.1 IC9H19—O——C2H4—CHMe—C2H5SK 58.4S 49.9 H 59 C* 62.7 A 63.5 IC10H21—O——C2H4—CHMe—C2H5SK 47.3S 51 H 53.6 C* 58.9 A 82.9 IC12H25—O——CO—C2H4—CHMe—CH3K 98A 113 IC8H17—O——COO—C2H4—CHMe—C2H5SK 59C* 58 A 72 IC9H19—O——COO—C2H4—CHMe—C2H51K 41S 45 C* 53 A 67 UC10H21—O——COO—C2H4—CHMe—C2H51K 45S 53 C* 67 A 74 IC8H17—O——OOC—C2H4—CHMe—C2H51K ?G* 92.5 A 93 IC8H17—CO——OOC—C2H4—CHMe—C2H51K 74.2A 112 UC9H19—CO——OOC—C2—H4CHMe—C2H51K ?S 68 C* 99.8 A 114.2 UC8H17—O——COO—C2H5—CHMe—C2H51K 38G* 62.2 A 68 IC8H17—O——COO—C2H4—CHMe—C2H4—CHMe—CH31K 45C* 48 A 58 IC9H18—O——COO—C2H4—CHMe—C3H6—CHMe—CH31K 53A 54 IC12H25—O——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 50C* 47 A 53 IC7H15—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 24.2B 41.3 A 65.7 IC8H17—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 36.6J* 38.5 C* 43.9 A 55 IC9H19—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 40.9J* 39.8 C* 51.5 A 56.4 IC10H21—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 45.3J* 42.9 C* 53.5 A 56.9 IC11H23—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 51.2J* 46.6 C* 55.9 A 56.5 IC12H25—COO——COO—C2H4—CHMe—C3H6—CHMe—CH3SK 57.8A 55.5 IC10H21—O—C4H8—CHMe—C3H72K 22C 60.5 IC10H21—O—C5H10—CHMe—C2H42K 26.5C 69.5 IC8H17—O——OOC—CHF—C6H131K ?C* ? IC5H11—O——OOC—CHCl—C2H51K 103.5G* 107 IC6H13—O——OOC—CHCl—C2H51K 96H 87 G* 103 A 107 IC7H15—O——OOC—CHCl—C2H51K 91.5H 80 G* 92 F* 96 A 104 IC8H17—O——OOC—CHCl—C2H51K 98H 71 G* 91 F* 95 A 104 IC9H19—O——OOC—CHCl—CH3SK ?G* <? IC9H19—O——OOC—CHCl—C2H51K 100G* 85 F* 96 A 102.5 IC10H21—O——OOC—CHCl—C2H51K 100G* 82 F* 95 A 101 IC12H25—O——OOC—CHCl—C2H51K 96G* 74 F* 95 A 100 IC9H19—COO——OOC—CHCl—C2H51K 123S 132 IC8H17—OCOO——OOC—CHCl—C2H51K 62I* 70 C* 80 IC8H17—COO—CH2—CHCl—CH31K 38.5A 34 IC5H11—O——COO—CH2—CHCl—CH3RK 80A 92.5 IC6H13—O——COO—CH2—CHCl—CH3RK 73A 86.4 IC7H15—O——COO—CH2—CHCl—CH3RK 79A 86.7 IC8H17—O——COO—CH2—CHCl—CH3RK 77.5A 86.2 IC9H19—O——COO—CH2—CHCl—CH3RK 84A 86.7 IC10H21—O——COO—CH2—CHCl—CH3RK 82.8A 87 IC12H25—O——COO—CH2—CHCl—CH3RK 85.5A 86.1 IC10H21—O——OOC—CH2—CHCl—CH31K 96S 95 S 108 IC8H17——O——COO—CH2—CHCl—CH31K 61.3E 30.5 B 69.7 A 90.2 IC8H17—COO——COO—CH2—CHCl—C2H5SK 25C* 22 A 56 IC9H19—COO——COO—CH2—CHCl—CH31K 48.4A 80 IC8H17—COO——COO—C2H4—CHCl—CH3SK 50.4J* 53.2 I* 53.2 A 65 IC9H19—COO——COO—C2H4—CHCl—CH3SK 53.8J* 57.4 A 67.5 IC10H21—COO——COO—C2H4—CHCl—CH3SK 58.4J* 60.3 A 68.2 IC11H23—COO——COO—C2H4—CHCl—CH3SK 66.2J* 63.7 A 69.3 IC13H27—COO——COO—C2H4—CHCl—CH3SK 70.6A 69.6 IC4H9—O——CO—CHBr—CH32K 97A 103 IC5H11—O——CO—CHBr—CH32K 91A 99 IC6H13—O——CO—CHBr—CH32K 85A 99 IC7H15—O——CO—CHBr—CH32K 78A 103 IC8H17—O——CO—CHBr—CH32K 84A 103 IC9H19—O——CO—CHBr—CH32K 80A 103 IC10H21—O——CO—CHBr—CH32K 71A 103 IC12H25—O——CO—CHBr—C3H72K 95A 78 IC3H7—CF3K 97N −80 EC3H7—O—CF3K 92N −60 EC5H11—S—CF3K 31N −80 EC5H11—O—CH2—CF3K 107N −30 EC5H11—CO—CF3K 13N −40 EC4H9—O——C6F13K 86S 104 IC7H15—O——CF3K 69B 114.5 IC8H17—O——CF3K 115N −20 EC4H9—O——S—CF3K 82N −40 EC8H17—O——COO—CH2—C6F13K 85C 109 A 119 IC8H17—O——COO—C2H4—C4F9K 108C 112 IC8H17—O——COO—C2H4—C6F13K 114C125 A 127 IC8H17—O——COO—C2H4—C8F17K 122C 132 A 141 IC8H17—O——COO—C2H4—C10F21K 141A 152 ICH3—NH——C6F13K 142S 168 IC2H5—NH——C6F13K 122S 174 IC3H7—NH——C6F13K 110S 134 IC4H9—NH——C3F7K 117S 123 IC4H9—NH——C8F13K 107S 145 IC5H11—NH——C3F7K 108S 111 IC5H11—NH——C6F13K 108S 133 IC8H17—NH——C6F13K 115S 113 IC8H17—OOC——O—C2H4—C6F13K ?C ? A ? IC9H19—COO——CF3K 63.3E 74 B 108.3 ICH3—CHMe—CH2—CHCl—COO——O—CH2—C7F151K 88A 98 IC2H5—CHMe—CH2—O——O—C11H23—OOC—CH═CH2SK 62A 69 IC2H5—CHMe—CH2—OOC——O—C8H16—O—CH═CH2SK 37.6C* 30.2 A 53.3 IC2H5—CHMe—CH2—OOC——O—C2H4—OOC—CH═CH2SK 53A 49 IC2H5—CHMe—CH2—OOC——O—C6H12—OOC—CH═CH2SK 28C* 13 A 36 IC2H5—CHMe—CH2—OOC——O—C10H20—OOC—CH═CH2SK 48C* 42 A 54 IC2H5—CHMe—CH2—OOC——O—C12H24—OOC—CH═CH2SK 54.8A 43.7 IC2H5—CHMe—CH2—OOC——O—C6H12—CH═CH2SK 20C* 29 A 53 IC2H5—CHMe—CH2—OOC——OOC—C5H10—CH═CH2SK 44.5C* 41.7 A ? IC2H5—CHF—COO——OOC—CHF—C2H53K ?S 162.1 S 167 IC3H7—CHF—COO——OOC—CHF—C3H73K 102.4S 131.5 IC6H13—CHF—CH2—O——O—C4H8—C4F91K ?S 47 S 87 S 91 S 97 C* 112 A 130 ICH3—CHCl—COO——OOC—CHCl—CH33K 132.7S 182.4 S 163.3 IC2H5—CHCl—COO——OOC—CHCl—C2H53K 82.8S 83 S 102.2 ICH3—CHCl—COO——O—C4H9—CH═CH21K 99E 112.5 B 118 ICH3—CHCl—COO——O—C9H18—CH═CH21K 112A 108 IC8F17—C11H22—O——COO—CH2—CF3K 95S 82 A 113 IC8F17—C11H22—O——COO—CH2—C7F15K 103C 115 IH2C═CH—CH2—OOC—C5H10—O——COO—C5H10—O—CH2—CH═CH2K 78IH2C═CH—C4H9—O——O—C4H8—CH═CH2K 51.2S 119.5 IC5H11—C:::C——C:::C—C5H11K 67.5S 86 IC7H15—C:::C——C:::C—C7H15K ?S 73 ICH3—OOC——O—C9H18—CH═CH2K 95E 118 ICH3—OOC——OOC—C8H18—CH═CH2K 82IC2H5—OOC—CHMe—OOC——O—C8H16—CH═CH21K 48A 39 UC6H13—O——O—C9H18—CH═CH2K 102S 102 S 105 IC5H11—C:::C—HK 56.4S 82.7 IC5H11—C:::C—CH3K 60.5S 83.4 ICH3—O——OOC—C:::C—C:::C—C10H21K 54N 86 ICH3—O——O—C6H12—OOC—CH(—CH2—C:::C—H)2K 75S 106 ICH3—O——OOC—C2H5—C:::C—HK 92N 68.1 ICH3—O——OOC—C8H16—C:::C—HK 76.7N 85.6 IC2H5—CHMe—CHF—CH2—OOC——O—C11H22—O—CH═CH23K 48.5S 32 C* 34.7 A 54.3 IC2H5—CHMe—CHCl—CH2—OOC——O—C2H4—O—CH═CH23K 58.2IC2H5—CHMe—CHCl—CH2—OOC——O—C6H12—O—CH═CH23K 40C* 26.5 A 55 IC2H5—CHMe—CHCl—CH2—OOC——O—C8H16—O—CH═CH23K 39C* ? A 51.3 IC2H5—CHMe—CHCl—CH2—OOC——O—C11H22—O—CH═CH23K 41.9C* 21 A 38.3 IC6H13—CHMe—O——O—CH2—CH═CH21K 77S 56 IC2H5—CHMe—CHCl—COO——O—CH2—CH═CH23K 91IC2H5—CHMe—CHCl—COO——O—C6H12—CH═CH23K 41C* 35 A 51 IC2H5—CHMe—CHCl—COO——O—C9H18—CH═CH23K 49C* 33 A 52 IC2H5—CHMe—CHCl—COO——O—C9H18—CH═CH23K 36C* 48 A 58 IC2H5—CHMe—CH2—COO—CH2—CHMe—C2H46K −4N* −70 EC2H5—CHMe—CH2—COO—CH2—C7F151K 72A 101 IC2H5—CHMe—CH2—O——COO—CH2—C7F151K ?H 96 A 115 IC3H7—O—CF2—HK 84N −30 EC3H7—S—CF2—HK 58N −70 EC7H15—SO—CF2—H2K 72N −70 EC7H15—SO2—CF2—HK 50N −110 EC8H17—O——O—CF2—HK 104N 20 EC8H17—O——COO—CHCF3—C6H131K 45.5E 69 A 74 IC8H17—OCOO——OOC—CH2—CHCF3—C4H91K ?S 5 S 25 IC8H17—O——COO—C2H4—CHCF3—C4H91K 42A 35 IC5H11—CH═CH2K 122N 51.5 UC8H17—OOC—CH═CH—C5H11K 36E 59 B 66 N 75 ICH3—O——O—C11H22—O—CH═CH2K 95IC4H9—O——COO—C4H8—OOC—CH═CH2K ?S 55 IC8H17—O——OOC—C4H8—OOC—CH═CH2K 84.1S 91.7 IC8H17—O——OOC—C2H4—CHMe—CH2—OOC—CH═CH21K 48.7S 73.9 IC8H17—O—CH2—CH═CH—C5H11K 75E 93 ICH3—O——O—C6H12—O—CH2—CH═CH2K 101N 98 IC6H13—O——O—C6H12—O—CH2—CH═CH2K 100S 99 ICH3—O——O—C2H4—O—C2H4—O—C2H2—O—CH2—CH═CH2K 73X 83 IC4H9—OOC—CHMe—OOC——O—C8H18—O—CH2—CH═CH21K 10A 20 ICH3—O——OOC—C3H6—CH═CH2K 70N 76 IC2H5—C4H8—CH═CH2K ?B 26.3 IC4H9—C4H8—CH═CH2K 24.4B 38.5 IC2H5—C6H12—CH═CH2K 9.4B 28.2 IC4H9—C6H12—CH═CH2K −24.6B 42.4 ICH3—O——O—C6H12—CH═CH2K 96E 108 IC6H13—O——O—C6H12—CH═CH2K 113S 112 ICH3—OOC——O—C6H12—CH═CH2K 103E 123 S 127 ICH3—O——O—C8H16—CH═CH2K 81E 108 ICH3—O——OOC—C8H16-CH═CH2K 75N 79 I


[0030] The liquid crystalline charge transfer materials of the present invention are useful for a variety of applications such as optical sensors, electro-luminescent elements, photoconductors, spacial optical modulators and thin-film transistors.

[0031] The liquid crystalline charge transfer materials of the present invention can attain high mobility of electric charges, and prevent the formation of structural traps. Therefore, optical sensors having high-speed responsibility can be mentioned as a primary application of these materials. Secondarily, the materials of the present invention are excellent in charge transferability, and they themselves are fluorescent, so that they can be used for charge transfer layers in electro-luminescent elements which can be produced with the mobility maintaining high. Moreover, the materials of the invention are such that orientation in an electric field and photoconductivity can be switched at the same time. Therefore, they can be used for image-displaying elements.

[0032] FIGS. 1 to 4 are views for illustrating typical examples of the application of the charge transfer materials of the present invention to electro-luminescent elements. The simplest structure of the elements is shown in FIG. 1, in which a luminescent layer (charge transfer layer) 10, 14 is formed as a single layer, and sandwiched between a cathode (transparent electrode) 13 provided on a transparent substrate 15′ and an anode 13′ provided on a substrate 15. Reference numeral 16 indicates a spacer. Only when the charge transfer material has both charge transferability and fluorescence like the liquid crystalline charge transfer materials of the present invention, it is possible to produce an electro-luminescent element having the above structure. In this case, in order to obtain strong luminescence, it is preferable that a material having a low work function be selected as a material for forming the cathode which acts as an electron injector and that a material having a work function which is equal to or greater than the work function of the cathode be selected for forming the anode.

[0033] Examples of materials for forming the anode generally include ITO, indium oxide, tin oxide (doped with antimony, arsenic, or fluorine), Cd2SnO4, zinc oxide, copper iodide, alkaline or alkaline earth metals such as sodium, potassium, magnesium and lithium, sodium-potassium alloys, magnesium-indium alloys, magnesium-silver alloys, aluminum, gold, silver, gallium, indium and copper, and those materials which are used for forming the cathode.

[0034] A material for forming the luminescent layer or charge transfer layer is composed of a charge transfer material and a luminescent material. The charge transfer material is preferably an electron-hole transfer material, a mixture of electron-hole transfer materials, or a mixture of an electron transfer material and a hole transfer material. However, in the case where luminescence at the surface of the electrode is utilized, a material which transfers only electrons or holes may also be used. Since the charge transfer materials of the present invention themselves are fluorescent, it is not necessary to use any luminescent material in the present invention; however, such a material may also be used along with the materials of the invention.

[0035] Further, in the case of an electro-luminescent element having a structure as shown in FIGS. 3 or 4, the thickness of a luminescent layer (luminescent material) 10 is so made that the transfer of electrons or holes will not be impeded. The thickness of the luminescent layer is preferably from 0.2 to 15 μm; and it can be adjusted by scattering spacer particles in the luminescent material, or by a sealer to be provided around the periphery of the cell.

[0036] FIGS. 5 to 7 are views for illustrating typical examples of the application of the charge transfer materials of the present invention to optical sensors. An optical sensor is composed of electrodes 13, 13′, and a liquid crystalline charge transfer material 14 of the present invention. For optical sensors, such a property that the value of electric current changes when light is applied to the charge transfer materials can be utilized.

[0037]
FIG. 8 is a view for illustrating a typical example of the application of the charge transfer materials of the present invention to image-displaying elements. An image-displaying element is composed of a transparent substrate 15 such as a glass plate, a transparent electrode 13 made from ITO (indium titanium oxide) or the like, a charge-generating layer 14′ which generates carriers correspondingly to light applied to this layer, a liquid crystalline charge transfer material 14 of the present invention and a counter electrode (gold electrode) 13′, which are successively laminated in the mentioned order. When light is applied image-wise (input image) to the lower part (transparent substrate) of the element, molecules in the liquid crystalline charge transfer material are oriented correspondingly to the light applied, and carriers flow toward the counter electrode (gold electrode) 13′. By optically reading this orientation of molecules in the liquid crystal, the input image can be reproduced. If the above liquid crystal is highly smectic, the orientation of molecules in the liquid crystal is maintained for a long time, and the input information can thus be maintained for a long time.

[0038]
FIG. 9 is a view for illustrating an example of the application of the liquid crystalline charge transfer materials of the present invention to a charge transfer layer 14 in an image-recording device. While applying voltage to upper and lower electrodes 13 and 13′ as shown in FIG. 9, light is applied pattern-wise to the upper part of the device. In a charge-generating layer 14′, carriers are generated pattern-wise; and charges transferred by the charge transfer layer 14 are discharged in the space 19, and reach the surface of an information-recording layer 11.

[0039] The information-recording layer is a liquid crystal-polymer composite layer consisting of a smectic liquid crystal and a polymer. Molecules in the liquid crystal are oriented pattern-wise by an electric field produced by accumulated charges, and accumulated. Optical reading can thus be conducted.

[0040]
FIG. 10 also shows an information-recording device. Application of voltage and that of light are conducted in the same manner as in the case of the information-recording device shown in FIG. 9. Charges generated (image) are accumulated on the upper surface of a dielectric layer 20, and optical reading can thus be conducted.

[0041] Further, the liquid crystalline charge transfer materials of the present invention can also be used for a spacial optical modulator as schematically shown in FIG. 11. Moreover, they can also be used as an active layer in a thin-film transistor. For example, as shown in FIG. 12, the above-described liquid crystalline material can be used by providing it on a substrate on which a source electrode, a drain electrode and a gate electrode have been arranged.

[0042] The present invention will now be explained more specifically by referring to the following Examples. However, the present invention is not limited by these examples.


EXAMPLE A1

[0043] 4-Heptyloxybiphenylcarbonic acid (manufactured by Teikoku Chemical Industries Co., Ltd., Japan) and 7-hydroxy-4-methylcumarin (synthesized in accordance with the description in J. Chem. Soc. Chem. Commun., (2) 225-226, 1995) were dissolved in 4-pyridinyl phenol, and dehydration condensation was then carried out at 90° C. by using 1,3-dicyclohexylcarbodiimide to synthesize 7-hydroxy-6-(4-heptyloxybiphenylcarboxy)-4-methylcumarin.


EXAMPLE A2

[0044] Two glass substrates, each having thereon an ITO electrode (surface resistance: 100 to 200 Ω/□) formed by means of vacuum deposition were bonded with the ITO electrodes facing each other, a gap being provided between the substrates by using spacer particles, thereby obtaining a cell. Into this cell, the 7-hydroxy-6-(4-heptyloxybiphenylcarboxy)-4-methylcumarin obtained in Example A1 was injected under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell, luminescence originating from the above compound was observed.


EXAMPLE A3

[0045] A glass substrate on which an ITO electrode (surface resistance: 100 to 200 Ω/□) had been provided by means of vacuum deposition, and a glass substrate on which an Ag electrode (specific resistance: 1 Ω/cm or less, film thickness: 3,000 Å) had been provided were bonded with the electrodes facing each other, a gap being provided between the substrates by using spacer particles, thereby obtaining a cell. Into this cell, a liquid crystalline material which was the compound obtained in Example A1 was injected under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE A4

[0046] A cell having the structure shown in FIG. 2 was made by using a liquid crystalline material which was the compound obtained in Example A1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE A5

[0047] A cell having the structure shown in FIG. 3 was made by using a liquid crystalline material which was the compound obtained in Example A1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE A6

[0048] A cell having the structure shown in FIG. 4 was made by using a liquid crystalline material which was the compound obtained in Example A1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE B1

[0049] Two glass substrates, each having thereon an ITO electrode (surface resistance: 100 to 200 Ω/□) formed by means of vacuum deposition were bonded with the ITO electrodes facing each other, a gap being provided between the substrates by using spacer particles, thereby obtaining a cell. Into this cell, benzthiazole liquid crystal (2-(4′-heptyloxyphenyl)-6-dodecylbenzothiazole, Crystal-90° C.-SmA-100° C.-Iso.) was injected under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell, luminescence originating from the above compound was observed.


EXAMPLE B2

[0050] A glass substrate on which an ITO electrode (surface resistance: 100 to 200 Ω/□) had been provided by means of vacuum deposition, and a glass substrate on which an Ag electrode (specific resistance: 1 □/cm or less, film thickness: 3,000 Å) had been provided were bonded with the electrodes facing each other, a gap being provided between the substrates by using spacer particles, thereby obtaining a cell. Into this cell, a liquid crystalline material which was the compound obtained in Example B1 was injected under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE B3

[0051] A cell having the structure shown in FIG. 2 was made by using a liquid crystalline material which was the compound obtained in Example B1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE B4

[0052] A cell having the structure shown in FIG. 3 was made by using a liquid crystalline material which was the compound obtained in Example B1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.


EXAMPLE B5

[0053] A cell having the structure shown in FIG. 4 was made by using a liquid crystalline material which was the compound obtained in Example B1, where the liquid crystalline material was injected into the cell under the condition of 110° C. When a direct current electric field of 250 V was applied to this cell in a dark room, luminescence originating from the above liquid crystalline material was observed.

Claims
  • 1. A liquid crystalline charge transfer material having the following structure (A) containing a fluorescent skeletal structure Y, and the core Z of a liquid crystal: 38
  • 2. The liquid crystalline charge transfer material according to claim 1, wherein Z has a structure represented by Z1 or Z1-Z2-Z3, in which Z1 and Z3 are (6π electron system aromatic ring)1, (10π electron system aromatic ring)m or (14π electron system aromatic ring)n (where 1, m and n are an integer of 0 to 4, provided that 1+m+ n=1 to 4), and Z2 is —CH═CH—, —C≡C—, —N═N—, —CH═N— or —COO— group, or Z1 and Z3 are directly combined with each other.
  • 3. The liquid crystalline charge transfer material according to claim 1, wherein Y is selected from radicals of metal chelate compounds, polycyclically condensed or conjugated aromatic hydrocarbons, diphenylethylene derivatives, triphenylamine derivatives, diaminocarbazole derivatives, bisstyryl derivatives, benzothiazole derivatives, benzoxazole derivatives, aromatic diamine derivatives, quinacridone compounds, perylene compounds, oxadiazole derivatives, cumarin compounds and anthracene derivatives.
  • 4. An electro-luminescent element containing in its driving path at least one material set forth in claim 1.
  • 5. An electro-luminescent element whose charge transfer part and luminescent part are made from at least one material set forth in claim 1.
  • 6. An electro-luminescent element which contains in its driving path at least one material set forth in claim 1 and whose charge transfer part and luminescent part are composed of a single layer.
  • 7. An optical sensor containing in its driving path at least one material set forth in claim 1.
  • 8. A photoconductor containing in its driving path at least one material set forth in claim 1.
  • 9. An image-displaying element containing in its driving path at least one material set forth in claim 1.
  • 10. A spacial optical modulator containing in its driving path at least one material set forth in claim 1.
  • 11. A thin-film transistor containing in its driving path at least one material set forth in claim 1.
  • 12. A liquid crystalline charge transfer material having the following skeletal structure (B) containing the fluorescent core Y of a liquid crystal: 39
  • 13. The liquid crystalline charge transfer material according to claim 12, wherein Y is (6π electron system aromatic ring)1, (10π electron system aromatic ring)m or (14π electron system aromatic ring)n (where 1, m and n are an integer of 0 to 4, provided that 1+m+n=1 to 4), and the aromatic rings may be combined through —CH═CH—, —C≡C—, —N═N—, —CH═N— or —COO— group.
  • 14. The liquid crystalline charge transfer material according to claim 12, wherein Y is selected from radicals of metal chelate compounds, polycyclically condensed or conjugated aromatic hydrocarbons, diphenylethylene derivatives, triphenylamine derivatives, diaminocarbazole derivatives, bisstyryl derivatives, benzothiazole derivatives, benzoxazole derivatives, aromatic diamine derivatives, quinacridone compounds, perylene compounds, oxadiazole derivatives, cumarin compounds and anthracene derivatives.
  • 15. An electro-luminescent element containing in its driving path at least one material set forth in claim 12.
  • 16. An electro-luminescent element whose charge transfer part and luminescent part are made from at least one material set forth in claim 12.
  • 17. An electro-luminescent element which contains in its driving path at least one material set forth in claim 12 and whose charge transfer part and luminescent part are composed of a single layer.
  • 18. An optical sensor containing in its driving path at least one material set forth in claim 12.
  • 19. A photoconductor containing in its driving path at least one material set forth in claim 12.
  • 20. An image-displaying element containing in its driving path at least one material set forth in claim 12.
  • 21. A spacial optical modulator containing in its driving path at least one material set forth in claim 12.
  • 22. A thin-film transistor containing in its driving path at least one material set forth in claim 12.
Priority Claims (2)
Number Date Country Kind
316654/1997 Nov 1997 JP
316656/1997 Nov 1997 JP