Deep-red light thermally activated delayed fluorescent material and synthesizing method thereof, and electroluminescent device

Abstract

A deep-red light thermally activated delayed fluorescent material and a synthesizing method thereof, and an electroluminescent device are described. The deep-red light thermally activated delayed fluorescent material is a target compound reacted and synthesized by an electron donor and an electron acceptor. The target compound is a D-A molecular structure or a D-A-D molecular structure, wherein the electron acceptor is a planar electron acceptor with an ultra-low triplet state energy level, and a triplet state energy level of the target compound ranges from 1.0 to 2.0 eV. The synthesized deep-red light thermally activated delayed fluorescent material provides high electroluminescent performance, the synthesis efficiency thereof is improved, and the preparation of the highly efficient organic electroluminescent device is realized.

Claims

1. A deep-red light thermally activated delayed fluorescent material, which is a target compound reacted and synthesized by an electron donor and an electron acceptor, wherein the target compound is a D-A molecular structure or a D-A-D molecular structure, the D in the molecular structure is the electron donor, the A is the electron acceptor, the electron acceptor is a planar electron acceptor with an ultra-low triplet state energy level, and a triplet state energy level of the target compound ranges from 1.0 to 2.0 eV, wherein the electron acceptor is 4,8-dibromo-2,3,6,7,-tetracyanonaphthalene, and the electron donor includes at least one of phenoxazine, phenothiazine, and 3,6-dimethoxy-9,9-dimethyl acridine.

2. The deep-red light thermally activated delayed fluorescent material according to claim 1, wherein the D-A molecular structure of the deep-red light thermally activated delayed fluorescent material is: ##STR00012## wherein the D-A-D molecular structure of the deep-red light thermally activated delayed fluorescent material is: ##STR00013##

3. An electroluminescent device, comprising: a substrate layer; a hole transporting and injecting layer disposed on a side surface of the substrate layer; a luminescent layer disposed on a side surface of the hole transporting and injecting layer away from the substrate layer; an electron transporting layer disposed on a side surface of the luminescent layer away from the hole transporting and injecting layer; and a cathode layer disposed on a side surface of the electron transporting layer away from the luminescent layer; wherein a material of the luminescent layer is a deep-red light thermally activated delayed fluorescent material according to claim 1.

Description

DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a flowchart of a synthesizing method of a deep-red light thermally activated delayed fluorescent material according to an embodiment of the present disclosure;

(2) FIG. 2 is a flowchart of steps of preparing an electron acceptor according to an embodiment of the present disclosure;

(3) FIG. 3 is a photoluminescence spectrum of a synthesized compound according to an embodiment of the present disclosure in a toluene solution at room temperature; and

(4) FIG. 4 is a structural schematic diagram of an electroluminescent device according to an embodiment of the present disclosure.

(5) Some components are identified as follows:

(6) 1: substrate layer;

(7) 2: hole transporting and injecting layer;

(8) 3: luminescent layer;

(9) 4: electron transporting layer; and

(10) 5: cathode layer.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(11) Preferred embodiments of the present disclosure are described in detail below with reference to the accompanying drawings in order to explain technical details of the present disclosure to those skilled in the art so as to exemplify the disclosure. Those skilled in the art will more readily understand how to implement the disclosure. The present disclosure, however, may be embodied in many different forms of embodiments, and the scope of the present disclosure is not limited to the embodiments described herein. The description of the embodiments below is not intended to limit the scope of the disclosure.

(12) The directional terms described by the present disclosure, such as “upper”, “lower”, “front”, “back”, “left”, “right”, “inner”, “outer”, “side”, etc. are only directions by referring to the accompanying drawings. Thus, the used directional terms are used to describe and understand the present disclosure, but the scope of the present disclosure is not limited thereto.

(13) In figures, elements with similar structures are indicated with the same numbers. Components that are structurally or functionally similar are denoted by similar reference numerals. Moreover, size and thickness of each component shown in the drawings are arbitrarily shown for ease of understanding and description, and the disclosure does not limit the size and thickness of each component.

(14) When some components are described as “on” another component, the components may be placed directly on the another component; or may also be an intermediate component in which the component is placed on the intermediate component, and the intermediate component is placed on the another component.

Embodiment 1

(15) The present embodiment provides a deep-red light thermally activated delayed fluorescent material, which is a target compound reacted and synthesized by an electron donor and an electron acceptor, wherein the target compound is a D-A molecular structure or a D-A-D molecular structure. In the molecular structure, the D is the electron donor, the A is the electron acceptor. The electron acceptor is a planar electron acceptor with an ultra-low triplet state energy level, and a triplet state energy level of the target compound ranges from 1.0 to 2.0 eV. In the present embodiment, the electron acceptor is 4,8-dibromo-2,3,6,7,-tetracyanonaphthalene, and the electron donor is phenoxazine. The phenoxazine has a molecular formula of C.sub.12H.sub.9NO, and the 4,8-dibromo-2,3,6,7,-tetracyanophthalene and the phenoxazine is synthesized by a series of chemical reactions to synthesize a first target compound. A molecular structure of the first target compound is as follows:

(16) ##STR00003##

(17) A lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission are reduced through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield. The synthesized first target compound has a high thermally activated delayed fluorescence (TADF) ratio and photoluminescence quantum yield (PLQY).

(18) As shown in FIG. 1, the present embodiment further provides a synthesizing method for a deep-red light thermally activated delayed fluorescent material of the disclosure, and a synthetic route is shown as follows:

(19) ##STR00004##

(20) A specific step includes an electron acceptor preparation step. The electron acceptor preparation step includes a reaction solution preparation step of preparing a 200 mL to 300 mL two-necked flask, and 8 mmol to 12 mmol of 2,3,6,7-tetracyanonaphthalene, 60 mL to 100 mL of toluene, and 35 mmol to 40 mmol of liquid bromine. In this example, 2.28 g of 10 mmol of the 2,3,6,7-tetracyanonaphthalene is added into a 250 mL two-necked flask. Then, 80 mL of the toluene is added, and 2 mL of 39 mmol of the liquid bromine is dropped into the two-necked flask at room temperature, and the reaction was performed by thoroughly stirring at room temperature to obtain a mixed solution.

(21) In a filtration step, the first reaction solution is cooled to room temperature, the mixed solution is poured into a 200 mL suction bottle containing an ice water mixture, and the mixed solution is filtered by an air pump to reduce pressure in the suction bottle so that the mixed solution is filtered in the suction flask to obtain a gray-red solid.

(22) In an electron acceptor purification processing step, the gray-red solid is dissolved in dichloromethane, and the target compound is initially purified by a silica gel column chromatography to obtain an initial purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to the toluene is 3:1. Further, the initial purified product is purified by a recrystallization method to obtain the electron acceptor, which is 2.38 g of 4,8-dibromo-2,3,6,7-tetracyanophthalene and has a yield of 62%.

(23) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 8.93 (s, 2H).

(24) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4, 383.86; found (experimental value), 383.67.

(25) A result of elemental analysis is: Anal. Calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4: C 43.56, H 0.52, and N 14.51; found (experimental value): C 43.66, H 0.63, and N 14.35.

(26) In a reaction solution preparation step, a 50 mL-200 mL two-necked bottle, 0-10 mmol electron acceptor of 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 10 mmol -15 mmol electron donor of phenoxazine, 0-1 mmol palladium acetate, 1 mmol -2 mmol tri-tert-butylphosphine tetrafluoroborate, and 10 mmol -15 mmol sodium t-butoxide (NaOt-Bu). A molar ratio of the electron acceptor to the electron donor is 1:1 to 1:3.

(27) In the present embodiment, 1.92 g (5 mmol) of the electron acceptor 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 2.2 g (12 mmol) of the electron donor of phenoxazine, a catalyst of 90 mg (0.4 mmol) of palladium acetate, and 0.34 g (1.2 mmol) of tri-tert-butylphosphine tetrafluoroborate are placed in a 100 mL two-necked flask, and 1.16 g (12 mmol) of sodium t-butoxide (NaOt-Bu) is added into the 100 mL two-necked flask in a glove box, the reaction liquid is obtained. Because sodium t-butoxide (NaOt-Bu) reacts easily with water to release hydrogen, it is very dangerous. Therefore, it is stored in the glove box under an argon atmosphere, and it is also used under the argon atmosphere.

(28) In a target compound synthesis step, reaction conditions of the reaction solution are provided. 30 mL to 50 mL of water and deoxygenated toluene are added into the glove box to thoroughly react at a temperature of 100° C. to 200° C. to obtain a mixed solution. The mixed solution has a target compound formed by the reaction.

(29) In an extraction step, the mixed solution is cooled to a room temperature and poured into a 30 mL to 80 mL ice-water mixture. The target compound in the mixed solution is extracted multiple times with the dichloromethane to extract the target compound from the mixed solution.

(30) In a target compound purification treatment step, an organic phase is combined, and the target compound is initially purified by silica gel column chromatography using a developing solvent to obtain a primary purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to n-hexane is 1:1. The n-hexane is the solvent in the column chromatography step, and the target compound is isolated and purified to obtain a deep red powder of 1.47 g in a yield of 50%, and the deep red powder is further purified by a recrystallization method to obtain 1.1 g of the first target compound.

(31) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 9.34 (s, 2H), 7.14-7.06 (m, 4H), 7.01-7.96 (m, 12H).

(32) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd for C.sub.38H.sub.18N.sub.6O.sub.2, 590.12; found, 590.07.

(33) A result of elemental analysis is: Anal. Calcd for C.sub.38H.sub.18N.sub.6O.sub.2: C 77.28, H 3.07, and N 14.23; found: C 77.17, H 2.93, and N 14.02.

(34) The deep-red light thermally activated delayed fluorescent material reduces a lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s). The synthesizing method of the deep-red light thermally activated delayed fluorescent material synthesizes a series of deep-red light thermally activated delayed fluorescent materials with remarkable thermal activation delayed fluorescence characteristics through different coordination of functional groups, which has a high synthesis percentage. Among the synthesizing products, the thermally activated delayed fluorescent material has a high proportion in the entire synthesized products, and its photoluminescence quantum yield is high.

(35) Characteristic parameters of a first target compound are shown in Table 1 below.

(36) Table 1 shows the measured parameters such as the lowest singlet state (S1) and the lowest triplet state energy level (T1) of the first target compound:

(37) TABLE-US-00001 PL Peak S.sub.1 T.sub.1 □E.sub.ST HOMO LUMO Compound (nm) (eV) (eV) (eV) (eV) (eV) First target 650 1.91 1.74 0.17 −5.40 −3.58 compound

(38) A photoluminescence spectrum of the first target compound in a toluene solution at room temperature is shown in FIG. 3.

(39) As shown in FIG. 4, the present embodiment further provides an electroluminescent device comprising a substrate layer 1; a hole transporting and injecting layer 2 disposed on an upper surface of the substrate layer 1; a luminescent layer 3 disposed on an upper surface of the hole transporting and injecting layer 2; an electron transporting layer 4 disposed on an upper surface of the luminescent layer 3; and a cathode layer 5 disposed on an upper surface of the electron transporting layer 4, wherein a material of the luminescent layer 3 is a deep-red light thermally activated delayed fluorescent material, i.e., the first target compound.

(40) A 50 nm poly 3,4-ethylenedioxythiophene: polystyrene sulfonate (PEDOT:PSS) is spin-coated on a cleaned substrate layer 1 to obtain a hole transporting and injecting layer 2. A material of the substrate layer 1 is glass and conductive glass (ITO). A 40 nm deep-red light thermally activated delayed material is spin-coated on the hole transporting and injecting layer 2 to obtain a luminescent layer 3. A layer of 40 nm of 1,3,5-tris(3-(3-pyridyl)phenyl)benzene (Tm3PyPB) is evaporated on the luminescent layer 3 under high vacuum to obtain an electron transporting layer 4. Further, under high vacuum conditions, a layer of 1 nm lithium fluoride and 100 nm aluminum are evaporated on the electron transporting layer 4 to obtain a cathode layer 5, thereby finally forming a first electroluminescent device.

(41) A current-brightness-voltage characteristic of the device is performed by a Keithley source measurement system (Keithley 2400 Sourcemeter, Keithley 2000 Currentmeter) with a calibrated silicon photodiode. An electroluminescence spectrum is measured by a French JY company SPEX CCD3000 spectrometer. All measurements are done at room temperature in an atmosphere.

(42) A performance data of the first electroluminescent device is shown in Table 2 below.

(43) Table 2 shows measured parameters such as a highest brightness and a highest current efficiency of the first electroluminescent device:

(44) TABLE-US-00002 Electro- highest highest current Maximum external luminescent brightness efficiency quantum efficiency device (cd/m.sup.2) (cd/A) CIEx (%) First 8630 23.6 0.66 13.2 electro- luminescent device

(45) The electroluminescent device fabricated by deep-red light thermally activated delayed fluorescent material has a relatively high luminous efficiency and brightness, a high production efficiency, and a long service life.

(46) When a molar ratio of the electron acceptor to the electron donor is from 1:1 to 1:5, the synthesized molecular structure is a D-A molecular structure. The molecular structure is as follows:

(47) ##STR00005##

(48) The thermally activated delayed fluorescent material of the D-A molecular structure has a high proportion in the entire synthesized product, and its photoluminescence quantum yield is high but the performance is lower than a D-A-D structure. The D-A-D structure reduces the lowest singlet-triplet energy level difference of the target molecule and a near-infrared light emission, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield.

Embodiments of the Present Disclosure

Embodiment 2

(49) The present embodiment provides a deep-red light thermally activated delayed fluorescent material, which is a target compound reacted and synthesized by an electron donor and an electron acceptor, wherein the target compound is a D-A molecular structure or a D-A-D molecular structure. In the molecular structure, the D is the electron donor, the A is the electron acceptor. The electron acceptor is a planar electron acceptor with an ultra-low triplet state energy level, and a triplet state energy level of the target compound ranges from 1.0 to 2.0 eV. In the present embodiment, the electron acceptor is 4,8-dibromo-2,3,6,7,-tetracyanonaphthalene, and the electron donor is phenothiazine. The phenothiazine has a molecular formula of C.sub.12H.sub.9NS, and the 4,8-dibromo-2,3,6,7,-tetracyanophthalene and the phenothiazine is synthesized by a series of chemical reactions to synthesize a second target compound. A molecular structure of a second target compound is as follows:

(50) ##STR00006##

(51) A lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission are reduced through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield. The synthesized second target compound has a high TADF ratio and PLQY.

(52) As shown in FIG. 1, the present embodiment further provides a synthesizing method for a deep-red light thermally activated delayed fluorescent material of the disclosure, and a synthetic route is shown as follows:

(53) ##STR00007##

(54) A specific step including an electron acceptor preparation step. The electron acceptor preparation step includes a reaction solution preparation step of preparing a 200 mL to 300 mL two-necked flask, and 8 mmol to 12 mmol of 2,3,6,7-tetracyanonaphthalene, 60 mL to 100 mL of toluene, and 35 mmol to 40 mmol of liquid bromine. In this example, 2.28 g of 10 mmol of the 2,3,6,7-tetracyanonaphthalene is added into a 250 mL two-necked flask. Then, 80 mL of the toluene is added, and 2 mL of 39 mmol of the liquid bromine is dropped into the two-necked flask at room temperature, and the reaction was performed by thoroughly stirring at room temperature to obtain a mixed solution.

(55) In a filtration step, the first reaction solution is cooled to room temperature, the mixed solution is poured into a 200 mL suction bottle containing an ice water mixture, and the mixed solution is filtered by an air pump to reduce pressure in the suction bottle so that the mixed solution is filtered in the suction flask to obtain a gray-red solid.

(56) In an electron acceptor purification processing step, the gray-red solid is dissolved in dichloromethane, and the target compound is initially purified by a silica gel column chromatography to obtain an initial purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to the toluene is 3:1. Further, the initial purified product is purified by a recrystallization method to obtain the electron acceptor, which is 2.38 g of 4,8-dibromo-2,3,6,7-tetracyanophthalene and has a yield of 62%.

(57) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 8.93 (s, 2H).

(58) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4, 383.86; found (experimental value), 383.67.

(59) A result of elemental analysis is: Anal. Calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4: C 43.56, H 0.52, and N 14.51; found (experimental value): C 43.66, H 0.63, and N 14.35.

(60) In a reaction solution preparation step, a 50 mL-200 mL two-necked bottle, 0-10 mmol electron acceptor of 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 10 mmol -15 mmol electron donor of phenothiazine, 0-1 mmol palladium acetate, 1 mmol-2 mmol tri-tert-butylphosphine tetrafluoroborate, and 10 mmol-15 mmol sodium t-butoxide (NaOt-Bu). A molar ratio of the electron acceptor to the electron donor is 1:1 to 1:2.5.

(61) In the present embodiment, 1.92 g (5 mmol) of the electron acceptor 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 2.2 g (10 mmol) of the electron donor of phenothiazine. a catalyst of 90 mg (0.4 mmol) of palladium acetate, and 0.34 g (1.2 mmol) of tri-tert-butylphosphine tetrafluoroborate are placed in a 100 mL two-necked flask, and 1.16 g (12 mmol) of sodium t-butoxide (NaOt-Bu) is added into the a 100 mL two-necked flask in a glove box, the reaction liquid is obtained. Because sodium t-butoxide (NaOt-Bu) reacts easily with water to release hydrogen, it is very dangerous. Therefore, it is stored in the glove box under an argon atmosphere, and it is also used under the argon atmosphere.

(62) In a target compound synthesis step, reaction conditions of the reaction solution are provided. 30 mL to 50 mL of water and deoxygenated toluene are added into the glove box to thoroughly react at a temperature of 100° C. to 200° C. to obtain a mixed solution. The mixed solution has a target compound formed by the reaction.

(63) In an extraction step, the mixed solution is cooled to a room temperature and poured into a 30 mL to 80 mL ice-water mixture. The target compound in the mixed solution is extracted multiple times with the dichloromethane to extract the target compound from the mixed solution.

(64) In a target compound purification treatment step, an organic phase is combined, and the target compound is initially purified by silica gel column chromatography using a developing solvent to obtain a primary purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to n-hexane is 1:1. The n-hexane is the solvent in the column chromatography step, and the target compound is isolated and purified to obtain a deep red powder of 1.34 g in a yield of 43%, and the deep red powder is further purified by a recrystallization method to obtain 0.88 g of the second target compound.

(65) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are: .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 8.314 (s, 2H), 7.21-7.16 (m, 12H), 6.97-6.91 (m, 4H).

(66) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd for C.sub.38H.sub.18N.sub.6S.sub.2, 622.10; found, 622.07.

(67) A result of elemental analysis is: Anal. Calcd for C.sub.38H.sub.18N.sub.6S.sub.2: C 73.29, H 2.91, and N 13.50; found: C 73.19, H 2.93, and N 13.32.

(68) The deep-red light thermally activated delayed fluorescent material reduces a lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s). The synthesizing method of the deep-red light thermally activated delayed fluorescent material synthesizes a series of deep-red light thermally activated delayed fluorescent materials with remarkable thermal activation delayed fluorescence characteristics through different coordination of functional groups, which has a high synthesis percentage. Among the synthesizing products, the thermally activated delayed fluorescent material has a high proportion in the entire synthesized products, and its photoluminescence quantum yield is high.

(69) Characteristic parameters of the second target compound are shown in Table 3 below.

(70) Table 3 shows the measured parameters such as the lowest singlet state (S1) and the lowest triplet state energy level (T1) of the second target compound:

(71) TABLE-US-00003 PL Peak S.sub.1 T.sub.1 □E.sub.ST HOMO LUMO Compound (nm) (eV) (eV) (eV) (eV) (eV) Second target 668 1.86 1.60 0.26 −5.72 −3.42 compound

(72) A photoluminescence spectrum of the second target compound in a toluene solution at room temperature is shown in FIG. 3.

(73) As shown in FIG. 4, the present embodiment further provides an electroluminescent device comprising a substrate layer 1; a hole transporting and injecting layer 2 disposed on an upper surface of the substrate layer 1; a luminescent layer 3 disposed on an upper surface of the hole transporting and injecting layer 2; an electron transporting layer 4 disposed on an upper surface of the luminescent layer 3; and a cathode layer 5 disposed on an upper surface of the electron transporting layer 4, wherein a material of the luminescent layer 3 is a deep-red light thermally activated delayed fluorescent material, i.e., the second target compound.

(74) A 50 nm poly 3,4-ethylenedioxythiophene: polystyrene sulfonate (PEDOT:PSS) is spin-coated on a cleaned substrate layer 1 to obtain a hole transporting and injecting layer 2. A material of the substrate layer 1 is glass and conductive glass (ITO). A 40 nm deep-red light thermally activated delayed material is spin-coated on the hole transporting and injecting layer 2 to obtain a luminescent layer 3. A layer of 40 nm of 1,3,5-tris(3-(3-pyridyl)phenyl)benzene (Tm3PyPB) is evaporated on the luminescent layer 3 under high vacuum to obtain an electron transporting layer 4. Further, under high vacuum conditions, a layer of 1 nm lithium fluoride and 100 nm aluminum are evaporated on the electron transporting layer 4 to obtain a cathode layer 5, thereby finally forming a first electroluminescent device.

(75) A current-brightness-voltage characteristic of the device is performed by a Keithley source measurement system (Keithley 2400 Sourcemeter, Keithley 2000 Currentmeter) with a calibrated silicon photodiode. An electroluminescence spectrum is measured by a French JY company SPEX CCD3000 spectrometer. All measurements are done at room temperature in an atmosphere.

(76) A performance data of the second electroluminescent device is shown in Table 4 below.

(77) Table 4 shows measured parameters such as a highest brightness and a highest current efficiency of the second electroluminescent device:

(78) TABLE-US-00004 Electro- highest highest current Maximum external luminescent brightness efficiency quantum efficiency device (cd/m.sup.2) (cd/A) CIEx (%) Second 5789 28.9 0.68 14.7 electro- luminescent device

(79) The electroluminescent device fabricated by deep-red light thermally activated delayed fluorescent material has a relatively high luminous efficiency and brightness, a high production efficiency and a long service life.

(80) When a molar ratio of the electron acceptor to the electron donor is from 1:1 to 1:3, the synthesized molecular structure is a D-A molecular structure. The molecular structure is as follows:

(81) ##STR00008##

(82) The thermally activated delayed fluorescent material of the D-A molecular structure has a high proportion in the entire synthesized product, and its photoluminescence quantum yield is high but the performance is lower than a D-A-D structure. The D-A-D structure reduces the lowest singlet-triplet energy level difference of the target molecule and a near-infrared light emission, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield.

Embodiment 3

(83) The present embodiment provides a deep-red light thermally activated delayed fluorescent material, which is a target compound reacted and synthesized by an electron donor and an electron acceptor, wherein the target compound is a D-A molecular structure or a D-A-D molecular structure. In the molecular structure, the D is the electron donor, the A is the electron acceptor. The electron acceptor is a planar electron acceptor with an ultra-low triplet state energy level, and a triplet state energy level of the target compound ranges from 1.0 to 2.0 eV. In the present embodiment, the electron acceptor is 4,8-dibromo-2,3,6,7,-tetracyanonaphthalene, and the electron donor is 3,6-dimethoxy-9,9-dimethyl acridine. The 4,8-dibromo-2,3,6,7,-tetracyanophthalene and the 3,6-dimethoxy-9,9-dimethyl acridine is synthesized by a series of chemical reactions to synthesize a second target compound. A molecular structure of the third target compound is as follows:

(84) ##STR00009##

(85) A lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission are reduced through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield. The synthesized second target compound has a high TADF ratio and PLQY.

(86) As shown in FIG. 1, the present embodiment further provides a synthesizing method for a deep-red light thermally activated delayed fluorescent material of the disclosure, and a synthetic route is shown as follows:

(87) ##STR00010##

(88) A specific step include an electron acceptor preparation step. The electron acceptor preparation step includes: a reaction solution preparation step of preparing a 200 mL to 300 mL two-necked flask, and 8 mmol to 12 mmol of 2,3,6,7-tetracyanonaphthalene, 60 mL to 100 mL of toluene, and 35 mmol to 40 mmol of liquid bromine. In this example, 2.28 g of 10 mmol of the 2,3,6,7-tetracyanonaphthalene is added into a 250 mL two-necked flask. Then, 80 mL of the toluene is added, and 2 mL of 39 mmol of the liquid bromine is dropped into the two-necked flask at room temperature, and the reaction was performed by thoroughly stirring at room temperature to obtain a mixed solution.

(89) In a filtration step, the first reaction solution is cooled to room temperature, the mixed solution is poured into a 200 mL suction bottle containing an ice water mixture, and the mixed solution is filtered by an air pump to reduce pressure in the suction bottle so that the mixed solution is filtered in the suction flask to obtain a gray-red solid.

(90) In an electron acceptor purification processing step, the gray-red solid is dissolved in dichloromethane, and the target compound is initially purified by a silica gel column chromatography to obtain an initial purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to the toluene is 3:1. Further, the initial purified product is purified by a recrystallization method to obtain the electron acceptor, which is 2.38 g of 4,8-dibromo-2,3,6,7-tetracyanophthalene and has a yield of 62%.

(91) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are: .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 8.93 (s, 2H).

(92) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4, 383.86; found (experimental value), 383.67.

(93) A result of elemental analysis is: Anal. Calcd (theoretical value) for C.sub.14H.sub.2BrN.sub.4: C 43.56, H 0.52, and N 14.51; found (experimental value): C 43.66, H 0.63, and N 14.35.

(94) In a reaction solution preparation step, a 50 mL-200 mL two-necked bottle, 0-10 mmol electron acceptor of 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 10 mmol-15 mmol electron donor of 3,6-dimethoxy-9,9-dimethyl acridine, 0-1 mmol palladium acetate, 1 mmol-2 mmol tri-tert-butylphosphine tetrafluoroborate, and 10 mmol-15 mmol sodium t-butoxide (NaOt-Bu). A molar ratio of the electron acceptor to the electron donor is 1:1 to 1:2.

(95) In the present embodiment, 1.92 g (5 mmol) of the electron acceptor 4,8-dibromo-2,3,6,7-tetracyanonaphthalene, 2.2 g (8 mmol) of the electron donor of 3,6-dimethoxy-9,9-dimethyl acridine, a catalyst of 90 mg (0.4 mmol) of palladium acetate, and 0.34 g (1.2 mmol) of tri-tert-butylphosphine tetrafluoroborate are placed in a 100 mL two-necked flask, and 1.16 g (12 mmol) of sodium t-butoxide (NaOt-Bu) is added into the 100 mL two-necked flask in the glove box, the reaction liquid is obtained. Because sodium t-butoxide (NaOt-Bu) reacts easily with water to release hydrogen, it is very dangerous. Therefore, it is stored in glove box under an argon atmosphere, and it is also used under the argon atmosphere.

(96) In a target compound synthesis step, reaction conditions of the reaction solution are provided. 30 mL to 50 mL of water and deoxygenated toluene are added into the glove box to thoroughly react at a temperature of 100° C. to 200° C. to obtain a mixed solution. The mixed solution has a target compound formed by the reaction.

(97) In an extraction step, the mixed solution is cooled to a room temperature and poured into a 30 mL to 80 mL ice-water mixture. The target compound in the mixed solution is extracted multiple times with the dichloromethane to extract the target compound from the mixed solution.

(98) In a target compound purification treatment step, an organic phase is combined, and the target compound is initially purified by silica gel column chromatography using a developing solvent to obtain a primary purified product. In the silica gel column chromatography method, a volume ratio of the dichloromethane to n-hexane is 1:1. The n-hexane is the solvent in the column chromatography step, and the target compound is isolated and purified to obtain a deep red powder of 1.41 g in a yield of 37%, and the deep red powder is further purified by a recrystallization method to obtain 1.2 g of the second target compound.

(99) Results of a nuclear magnetic resonance spectrum and a carbon spectrum are: .sup.1H NMR (300 MHz, CD.sub.2Cl.sub.2, δ): 8.34 (s, 2H), 7.23-7.17 (m, 4H), 6.83 (s, 4H), 6.69 (d, J=6.9 Hz, 4H), 3.70(s, 12H), 1.69(s, 12H).

(100) A result of mass spectral is: MS (El) m/z: [M].sup.+ calcd for C.sub.48H.sub.38N.sub.6O.sub.4, 762.30; found, 762.07.

(101) A result of elemental analysis is: Anal. Calcd for C.sub.48H.sub.38N.sub.6O.sub.4: C 75.57, H 5.02, N 11.02; found: C 75.48, H 4.93, N 10.82.

(102) The deep-red light thermally activated delayed fluorescent material reduces a lowest singlet-triplet state energy level difference of a target molecule and a near-infrared light emission through a clever molecular design, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s). The synthesizing method of the deep-red light thermally activated delayed fluorescent material synthesizes a series of deep-red light thermally activated delayed fluorescent materials with remarkable thermal activation delayed fluorescence characteristics through different coordination of functional groups, which has a high synthesis percentage. Among the synthesizing products, the thermally activated delayed fluorescent material has a high proportion in the entire synthesized products, and its photoluminescence quantum yield is high.

(103) Characteristic parameters of the third target compound are shown in Table 5 below.

(104) Table 5 shows the measured parameters such as the lowest singlet state (S1) and the lowest triplet state energy level (T1) of the third target compound:

(105) TABLE-US-00005 PL Peak S.sub.1 T.sub.1 □E.sub.ST HOMO LUMO Compound (nm) (eV) (eV) (eV) (eV) (eV) Third target 680 1.83 1.77 0.06 −5.09 −3.25 compound

(106) A photoluminescence spectrum of the third target compound in a toluene solution at room temperature is shown in FIG. 3.

(107) As shown in FIG. 4, the present embodiment further provides an electroluminescent device comprising a substrate layer 1; a hole transporting and injecting layer 2 disposed on the upper surface of the substrate layer 1; a luminescent layer 3 disposed on an upper surface of the hole transporting and injecting layer 2; an electron transporting layer 4 disposed on an upper surface of the luminescent layer 3; and a cathode layer 5 disposed on an upper surface of the electron transporting layer 4, wherein a material of the luminescent layer 3 is a deep-red light thermally activated delayed fluorescent material, i.e., the third target compound.

(108) A 50 nm poly 3,4-ethylenedioxythiophene: polystyrene sulfonate (PEDOT:PSS) is spin-coated on a cleaned substrate layer 1 to obtain a hole transporting and injecting layer 2. A material of the substrate layer 1 is glass and conductive glass (ITO). A 40 nm deep-red light thermally activated delayed material is spin-coated on the hole transporting and injecting layer 2 to obtain a luminescent layer 3. A layer of 40 nm of 1,3,5-tris(3-(3-pyridyl)phenyl)benzene (Tm3PyPB) is evaporated on the luminescent layer 3 under high vacuum to obtain an electron transporting layer 4. Further, under high vacuum conditions, a layer of 1 nm lithium fluoride and 100 nm aluminum are evaporated on the electron transporting layer 4 to obtain a cathode layer 5, thereby finally forming a first electroluminescent device.

(109) A current-brightness-voltage characteristic of the device is performed by a Keithley source measurement system (Keithley 2400 Sourcemeter, Keithley 2000 Currentmeter) with a calibrated silicon photodiode. An electroluminescence spectrum is measured by a French JY company SPEX CCD3000 spectrometer. All measurements are done at room temperature in an atmosphere.

(110) A performance data of the third electroluminescent device is shown in Table 6 below.

(111) Table 6 shows measured parameters such as a highest brightness and a highest current efficiency of the second electroluminescent device:

(112) TABLE-US-00006 Electro- highest highest current Maximum external luminescent brightness efficiency quantum efficiency device (cd/m.sup.2) (cd/A) ClEx (%) Third 1.83 1.77 0.06 −5.09 electro- luminescent device

(113) The electroluminescent device fabricated by deep-red light thermally activated delayed fluorescent material has a relatively high luminous efficiency and brightness, a high production efficiency and a long service life.

(114) When a molar ratio of the electron acceptor to the electron donor is from 1:1 to 1:2, the synthesized molecular structure is a D-A molecular structure. The molecular structure is as follows:

(115) ##STR00011##

(116) The thermally activated delayed fluorescent material of the D-A molecular structure has a high proportion in the entire synthesized product, and its photoluminescence quantum yield is high but the performance is lower than a D-A-D structure. The D-A-D structure reduces the lowest singlet-triplet energy level difference of the target molecule and a near-infrared light emission, so that the target molecule has a fast reverse intersystem crossing constant (the constant value ranges from 1×10.sup.4/s to 1×10.sup.7/s) and a high photoluminescence quantum yield.

(117) The description above is merely preferred embodiments of the present disclosure. It is noted that, for one skilled in the art, many changes and modifications to the described embodiment can be carried out without departing from the principles of the disclosure and these changes and modifications should also be considered as protection scope of the present disclosure.