Patent Application
20170194535
This application claims priority from Korean Patent Application No. 10-2016-0001066 filed on Jan. 5, 2016, in the Korean Intellectual Property Office, the disclosure of which is incorporated herein by reference in its entirety.
1. Field
Apparatuses consistent with example embodiments relate to a white light emitting device and a display apparatus.
2. Description of Related Art
In general, white light emitting devices are manufactured through a method of combining a blue light emitting diode (LED) with a yellow phosphor, or combining the blue LED with a red phosphor and a green phosphor. White light emitting devices are commonly used as high efficiency light sources for display devices.
There is a demand for white light emitting devices that may cover a wide color gamut based on various color standards such as display control interface (DCI), national television system committee (NTSC), and BT.2020 in the field of display technology. New white light emitting devices having improved color reproducibility may be developed.
Example embodiments provide a white light emitting device and a display apparatus that may implement a high color reproduction.
According to example embodiments, a white light emitting device comprising a blue light emitting diode (LED) emitting first light having a dominant wavelength in a range of 440 nm to 460 nm, a first wavelength-conversion material disposed on a path of the emitted first light and converting a first portion of the emitted first light into green light, and a second wavelength-conversion material disposed on the path of the emitted first light and converting a second portion of the emitted first light into red light. The first wavelength-conversion material comprises a quantum dot comprising a core formed of a group III-V compound and a shell formed of a group II-VI compound, and the second wavelength-conversion material comprises a fluoride phosphor represented by empirical formula AxMFy:Mn4+, A being at least one selected from lithium (Li), sodium (Na), potassium (K), rubidium (Rb), and caesium (Cs), M being at least one selected from silicon (Si), titanium (Ti), zirconium (Zr), hafnium (Hf), germanium (Ge), and tin (Sn), and the empirical formula satisfying 2≦x≦3 and 4≦y≦7. The white light emitting device emits white light of which a color reproduction region covers 90% or more of a display control interface region in a CIE 1931 chromaticity diagram.
According to example embodiments, a white light emitting device includes a blue LED emitting first light having a dominant wavelength in a range of 440 nm to 460 nm, a green quantum dot disposed on a path of the emitted first light and converting a first portion of the emitted first light into second light having a peak wavelength in a range of 510 nm to 550 nm and having a full width at half maximum of 45 nm or less, and a red phosphor disposed on the path of the emitted first light and converting a second portion of the emitted first light into third light having a peak wavelength in a range of 610 nm to 635 nm and having a full width at half maximum of 30 nm or less.
According to example embodiments, a display apparatus includes an image display panel comprising a color filter layer comprising red, green, and blue color filters, and a backlight disposed on the image display panel and comprising light sources. Each of the light sources comprises a blue LED emitting first light having a dominant wavelength in a range of 440 nm to 460 nm. The display apparatus further includes a green quantum dot disposed on a path of the emitted first light and converting a first portion of the emitted first light into second light having a peak wavelength in a range of 510 nm to 550 nm and having a full width at half maximum of 45 nm or less, and a red phosphor disposed on the path of the emitted first light and converting a second portion of the emitted first light into third light having a peak wavelength in a range of 610 nm to 635 nm and having a full width at half maximum of 30 nm or less. Each of the light sources emits, through the color filter layer, fourth light of which a color reproduction region covers 90% or more of a display control interface region in a CIE 1931 chromaticity diagram.
According to example embodiments, a white light emitting device includes a blue LED emitting blue light, a quantum dot disposed on a path of the emitted blue light and converting a first portion of the emitted blue light into green light, and a fluoride phosphor disposed on the path of the emitted blue light and converting a second portion of the emitted blue light into red light.
With reference to
The blue LED 132 is disposed on an upper surface of the package body 101, and may include an epitaxially-grown semiconductor layer. The blue LED 132 may emit light having a dominant wavelength in a range of 440 nm to 460 nm. In example embodiments, the dominant wavelength of the blue LED 132 may be within a range of 444 nm to 450 nm.
The resin encapsulation portion 150 is disposed within the concave portion C. The resin encapsulation portion 150 includes a transparent resin 152, a green quantum dot 154, and a red phosphor 156. At least a portion of the emitted light may be converted into green light and red light, respectively. The green quantum dot 154 and the red phosphor 156 may be dispersed within the transparent resin 152 to be disposed on a path of light emitted by the blue LED 132. For example, the transparent resin 152 may be formed of epoxy, silicone, modified silicone, urethane, oxetane, acryl, polycarbonate, polyimide, or a combination thereof.
The green quantum dot 154 may include a quantum dot having a core formed of a group II-VI compound and a group III-V shell. For example, the green quantum dot 154 may include at least one quantum dot selected from CdSe/CdS, CdSe/ZnS, CdSe/ZnS, PbS/ZnS, and InP/GaP/ZnS. The quantum dot may satisfy wavelength conditions by adjusting a diameter thereof.
When the green quantum dot 154 is excited by light emitted by the blue LED 132, the green quantum dot 154 employed in example embodiments may generate an emission spectrum having a peak wavelength in a range of 510 nm to 550 nm and a full width at half maximum of 45 nm or less. In example embodiments, to further improve color reproducibility, the peak wavelength of the green quantum dot 154 may be within a range of 530 nm to 545 nm. In addition, the full width at half maximum of the green quantum dot 154 may be 40 nm or less.
The red phosphor 156 may include a fluoride phosphor represented by empirical formula AxMFy:Mn4+. In this case, A is at least one selected from lithium (Li), sodium (Na), potassium (K), rubidium (Rb), and caesium (Cs), M is at least one selected from silicon (Si), titanium (Ti), zirconium (Zr), hafnium (Hf), germanium (Ge), and tin (Sn), and the empirical formula satisfies 2≦x≦3 and 4≦y≦7. The fluoride phosphor may be used in an improved form, for example, adding a protective coating layer thereto, to compensate vulnerability thereof to moisture. A detailed description thereof will be described in
When the red phosphor 156 is excited by light emitted by the blue LED 132, the red phosphor 156 employed in example embodiments may generate an emission spectrum having a peak wavelength in a range of 610 nm to 635 nm and a full width at half maximum of 30 nm or less. In example embodiments, to further improve color reproducibility, the emission spectrum of the red phosphor 156 may have the full width at half maximum of 10 nm or less.
A color reproduction range (i.e., a color gamut) may be defined as an area of a region surrounded by coordinates, when color obtained through red, green, and blue color filters is marked by a region in a CIE 1931 chromaticity diagram. In the case of the color reproduction of the white light emitting device 100 satisfying the conditions of a phosphor, a color reproduction region thereof may be 90% or more of a display control interface (DCI) region in the CIE 1931 chromaticity diagram. Additionally, the color reproduction of the white light emitting device 100 may be 95% or more based on a national television system committee (NTSC) region.
The package body 101 may include a polymer resin facilitating an injection molding process. For example, the resin may be an opaque resin or a resin containing powder having a high degree of reflectivity (for example, Al2O3). Alternatively, the package body 101 may include a ceramic substrate. In this case, heat dissipation may be facilitated through the package body 101. In example embodiments, the package body 101 may be a printed circuit board having a wiring pattern formed thereon.
The pair of lead frames 111 and 112 are disposed on the package body 101, and are electrically connected to the blue LED 132 to apply driving power thereto. The lead frames 111 and 112 are electrically connected to the blue LED 132 by a wire W. Alternatively, in a case in which the blue LED 132 has a flip-chip structure, the blue LED 132 may be directly connected to the lead frames 111 and 112 by a conductive bump.
Hereinafter, a function and an effect of the present inventive concept will be described in detail with reference to example embodiments.
A white light emitting device was manufactured using an LED having a dominant wavelength of 446 nm as a blue LED and using green and red phosphors represented by CdSe/ZnS and K2SiF6:Mn4+, respectively. In addition, a wavelength conversion member was provided by combining green and red phosphors to obtain white light having the same color coordinates.
In Example Embodiment 1, the CdSe/ZnS phosphor employed as a green phosphor may be a green quantum dot having a ZnS shell and a CdSe core. Furthermore, photoluminescence excitation (PLE) and photoluminescence (PL) spectra thereof are illustrated in
With reference to
In Example Embodiment 1, the PLE and PL spectra of the K2SiF6:Mn4+ phosphor employed as a red phosphor are illustrated in
With reference to
In a similar manner to Example Embodiment 1, a white light emitting device was manufactured by providing a wavelength conversion member to obtain substantially the same white light as that of Example Embodiment 1, along with a blue LED chip of 446 nm, while the wavelength conversion member was formed in a manner different from Example Embodiment 1.
First of all, in the wavelength conversion member employed in Comparative Example 1, a β-SiAlON:Eu2+ phosphor having a peak wavelength of 540 nm and a full width at half maximum of 50 nm was used as a green phosphor, while a (Ca,Sr)AlSiN3:Eu2+ phosphor having a peak wavelength of 620 nm and a full width at half maximum of 80 nm was used as a red phosphor.
In the wavelength conversion member employed in Comparative Example 2, a CdSe/ZnS phosphor (a peak wavelength of 542 nm and a full width at half maximum of 32 nm) the same as that of Example Embodiment 1 was used as a green phosphor, while a CdSe/ZnS quantum dot having a peak wavelength of 631 nm and a full width at half maximum of 31 nm was used as a red phosphor by adjusting size thereof.
A PL spectrum of the white light emitting device, obtained from Comparative Examples 1 and 2 along with Example Embodiment 1, was measured as illustrated in
With reference to
With reference to chromaticity diagrams in
As such, the color reproduction of the white light emitting device according to Example Embodiment 1 are 98.01% based on a DCI color gamut and 102.65% based on an NTSC color gamut, higher than those of the white light emitting device in Comparative Examples 1 and 2. The white light emitting device according to Example Embodiment 1 may implement a color reproduction of 90% or more, in detail 95%, based on the DCI color gamut. In addition, it can be confirmed that the color reproduction of 95% or more, in detail 100%, may also be implemented in the NTSC color gamut.
In the meantime, it can be confirmed that in terms of luminance as well, the white light emitting device according to Example Embodiment 1 represents higher luminance than that of Comparative Example 2 in which green and red phosphors are implemented as a quantum dot. Because as in Comparative Example 2, a red quantum dot absorbs light in a green region, efficiency of converted green light is reduced, which may function as a reason therefor.
Color reproducibility may be significantly increased by using green and red phosphors satisfying conditions of a peak wavelength and a full width at half maximum and/or conditions of a phosphor composition, proposed in the present inventive concept.
Phosphors employed in Example Embodiment 1 may have different vulnerability, and a method for complementing the vulnerability may be used. For example, a green phosphor, a quantum dot, may have vulnerability to heat. Therefore, to complement the characteristics, a structural change in a light emitting device or a display apparatus may be considered (see
Because a fluoride phosphor used as a red phosphor may have vulnerability to moisture, an additional coating layer may be included to complement the characteristics. For example, the fluoride phosphor that may be employed in Example Embodiment 1 may be described with reference to
With reference to
1) A is at least one selected from Li, Na, K, Rb, and Cs;
2) M is at least one selected from Si, Ti, Zr, Hf, Ge, and Sn;
3) A compositional ratio (x) of A satisfies 2≦x≦3; and
4) A compositional ratio (y) of F satisfies 4≦y≦7.
The fluoride phosphor particle 10 represented by the empirical formula AxMFy:Mn4+ may include K2SiF6:Mn4+, K2TiF6:Mn4+, K2SnF6:Mn4+, Na2TiF6:Mn4+, Na2ZrF6:Mn4+, K3SiF7:Mn4+, K3ZrF7:Mn4+, and K3SiF5:Mn4+. The fluoride phosphor particle 10 may be excited by a wavelength of light form an ultraviolet region to a blue region to emit red light. For example, the fluoride phosphor particle 10 may provide a red phosphor absorbing excitation light having a peak wavelength in a range of 300 nm to 500 nm to emit light having a peak wavelength in a range of 610 nm to 635 nm.
In the case of the fluoride phosphor particle 10, a concentration of Mn4+, an activator, may be gradually reduced from a center 10C thereof to a surface 10S thereof. In the present specification, gradually reducing is defined as a concentration that is continuously reduced without a portion of the particle in which the concentration is uniformly maintained at a predetermined thickness or more. For example, the fluoride phosphor particle 10 may not have a uniform concentration of Mn4+ within a region thereof exceeding 10% of a particle size D1 in a direction from the center 10C of the particle to the surface 10S of the particle. An average reduction rate of Mn4+ concentration, for example, in an overall thickness of the fluoride phosphor particle 10, may be about 0.4 at. %/μm to about 0.8 at. %/μm. However, the concentration reduction rate, with respect to the overall thickness thereof, may not be uniform. For example, the reduction rate of Mn4+ concentration from the center 10C of the phosphor particle 10 to the surface 10S thereof may be within a range of about 0.1 at. %/μm to about 1.5 at. %/μm, depending on a region of the particle.
In addition, the Mn4+ concentration may be about 3 at. % to about 5 at. % in the center 10C of the fluoride phosphor particle 10, and may be about 1.5 at. % or less on the surface 10S of the fluoride phosphor particle 10. A difference in Mn4+ concentrations between the center 10C and the surface 10S of the fluoride phosphor particle 10 may be within a range of about 2 at. % to about 4 at. %. The particle size D1 of the fluoride phosphor particle 10 may be within a range of 5 μm to 25 μm.
Because the fluoride phosphor particle 10 according to example embodiments has a composition in which the Mn4+ concentration is reduced toward the surface 10S thereof, vulnerability of the fluoride phosphor particle 10 to moisture may be reduced and reliability thereof may be secured.
In other example embodiments, the fluoride phosphor particle may include fluoride containing Mn4+, while a coating layer surrounding the fluoride phosphor particle may include fluoride without Mn4+.
With reference to
The operations may be performed at room temperature, but the present inventive concept is not limited thereto.
First, a first raw material containing M may be added to a hydrofluoric acid solution in S110.
The first raw material may be at least one among HxMFy, AxMFy and MO2, and for example may be H2SiF6 or K2SiF6. The first raw material may be added to the hydrofluoric acid solution, and may be stirred for several minutes to allow the first raw material to appropriately dissolve therein.
Subsequently, the manganese compound may be added to the hydrofluoric acid solution in S120.
Thereby, a first solution containing the first raw material containing M and the manganese compound may be produced. The manganese compound may be a compound containing Mn4+, and for example may have a composition of AxMnFy. For example, the manganese compound may have a composition of K2MnF6 by way of example. In a similar manner to an operation in S110, the manganese compound may be provided to the hydrofluoric acid solution in which the first raw material is dissolved, and may be stirred to allow the manganese compound to sufficiently dissolve therein.
Although example embodiments illustrate a case in which the first raw material containing M and the manganese compound are sequentially added to the hydrofluoric acid solution, the first solution may be produced in a different order therefrom. For example, according to other example embodiments, the manganese compound may first be provided to the hydrofluoric acid solution, and the first raw material containing M may be provided thereto.
Subsequently, the hydrofluoric acid solution including the second raw material containing A may be provided to the first solution in S130.
In detail, a second solution including the second raw material containing A may be provided to the first solution. The second raw material may be AHF2, for example, KHF2, and may be in a saturated solution state or powder form.
As concentrations of respective raw materials approach a solubility limit of the hydrofluoric acid solution, an orange precipitate may be formed. The precipitate may be Mn4+-activated fluoride (AxMFy:Mn4+). For example, when H2SiF6 and KHF2 are used as the first and second raw materials, and K2MnF6 is used as a compound containing Mn4+, the precipitate may be fluoride represented by K2SiF6:Mn4+.
In S130, A+ and Mn4+ not reacting with the precipitates may remain in the solution.
An amount of the second raw material may be divided and added at an interval corresponding to a time for reaction thereof, and thus a particle size of fluoride may be controlled. An average particle size and particle size distribution may be controlled by adjusting at least one among an addition number, an addition amount, an addition interval, and the like. For example, when the second raw material is divided into four parts and provided, fluoride seeds may be formed by a primarily-added second raw material, the seeds may be grown by secondarily and thirdly added second raw materials, and precipitation of the grown seeds may be induced by a fourthly added second raw material.
Subsequently, the first raw material containing M may be added to the solution in S140.
The first raw material may be the same material as the material used in S110, but is not limited thereto. The first raw material may be at least one among HxMFy and AxMFy, and for example may be H2SiF6 or K2SiF6. The first raw material may be added to the solution, and may be stirred for several minutes to appropriately dissolve therein.
In S140, the added first raw material may react with A+ and Mn4+ remaining in the solution described above to allow the precipitate to grow. Thus, in a region formed in S140, a Mn4+ concentration may be relatively low. For example, in a case in which K2SiF6:Mn4+ is synthesized in S130, when a H2SiF6 solution is additionally supplied in S140, the H2SiF6 solution reacts with residual KHF2 and Mn4+ to create K2SiF6, which may be grown in a shell form on a surface of the fluoride formed in S130.
Although in example embodiments, a case in which the second raw material remains after S130 is illustrated, the first raw material may remain. In this case, the second raw material containing A may be additionally provided in S140, rather than the first raw material.
An amount of the first raw material provided in S140 may be smaller than that of the first raw material provided to the first solution in S110, and for example, a volume of the first raw material provided in S140 may be within a range equal to 15% to 25% of that of the first raw material provided to the first solution in S110.
Subsequently, the formed precipitate may be collected in S150.
The precipitate may be formed by having started to settle in S130, and Mn4+ remaining on a surface of the precipitate may also be collected, while the second raw material such as A+ may be almost entirely consumed in S140, and thus may not remain.
In S150, hydrofluoric acid may be removed, and the precipitate may be collected, and thus Mn4+ remaining in the hydrofluoric acid solution may be removed together therewith. Thus, because only a small amount of Mn4+ remaining on the precipitate surface may be used at the time of a reaction of a subsequent process, a Mn4+ concentration in a phosphor region grown subsequently may be further decreased.
Next, the first raw material containing M and the hydrofluoric acid solution may be added to the precipitate in S160. Thereby, a third solution may be produced.
The first raw material may be the same material as the material used in S110 and S140, but is not limited thereto.
The amount of the first raw material provided in S160 may be smaller than that of the first raw material provided to the first solution in S110, and for example, the volume of the first raw material provided in S160 may be within a range equal to 15% to 25% of that of the first raw material provided to the first solution in S110.
Subsequently, the hydrofluoric acid solution including the second raw material containing A may be provided to the third solution in S170.
For example, the second solution, a hydrofluoric acid solution including the second raw material containing A, may be re-provided to the third solution. The second solution may contain the same second raw material as that used in S130, but is not limited thereto. In S170, an amount of the second raw material may be divided and provided at an interval corresponding to a time for reaction thereof, and thus a particle size of a fluoride particle to be formed may be controlled.
The amount of the second raw material provided in S170 may be smaller than that of the second raw material provided to the first solution in S130, and for example, a weight of the second raw material provided in S170 may be within a range equal to 40% to 60% of that of the second raw material provided to the first solution in S130.
The second raw material may react with Mn4+ remaining together with the precipitate and the first raw material within the third solution, so that fluoride particles may be formed in a shell form on the fluorides of the precipitate. To be discernible from the precipitate formed in S150, a final phosphor particle formed in S170 may be referred to as a fluoride particle for convenience of explanation, but a fluoride phosphor according to example embodiments may include a fluoride material that is grown from the precipitate and is finally formed in S170, but is not limited to a name referred to in respective operations.
Subsequently, fluoride particles may be collected and washed in S180.
The washing process may be performed using a hydrofluoric acid solution and/or an acetone solution as a washing solution. The washing process may be performed by stirring the precipitate using, for example, about 49% of high concentration hydrofluoric acid aqueous solution, and thus, impurities present on the fluoride particles, residual first and second raw materials, and the like may be removed. In example embodiments, the washing process may also be performed a plurality of times using different cleansing solutions.
Then, a fluoride phosphor according to example embodiments of the present inventive concept may be obtained by drying washed fluoride particles. The fluoride particles may be selectively dried, and a heat treatment process thereof at a temperature of about 100° C. to about 150° C. may further be performed.
The fluoride phosphor in which a content of manganese is gradually reduced toward a surface thereof may be produced through the processes as described above. According to example embodiments, a manganese compound containing Mn4+ may be provided once in S120, the addition number and the addition amount of the first and second raw materials may be adjusted, and thus phosphor particles may be grown in an environment in which a Mn4+ concentration is continuously reduced.
With reference to
The fluoride particle 10a may be a core of the fluoride phosphor particle 50, and may have the same configuration as the fluoride phosphor particle 50 illustrated in
The organic materials 20 may be physically adsorbed onto a surface of the fluoride particle 10a to protect the fluoride particle 10a. The organic materials 20 may be materials having a hydrophobic tail. Thus, a surface of the fluoride phosphor particle 50 may have hydrophobicity to have further increased moisture resistance.
For example, the organic materials 20 may have at least one functional group between a carboxylic group (—COOH) and an amino group (—NH2), and may include an organic compound having carbon numbers 4 to 18. In detail, the organic materials 20 may be fatty acids, such as an oleic acid having a composition of C18H34O2. In this case, because a length of one organic material 20 may be several nanometers or less, a thickness D2 of a coating layer by the organic material 20 may also be within a range of several nanometers to tens of nanometers. For example, the thickness D2 of the coating layer may be 5 nm or less.
With reference to
The white light emitting device 100A includes a pair of lead frames 111 and 112 electrically connected to the blue LED 132 and the near ultraviolet LED 134, and a conductive wire W connecting the blue LED 132 and the near ultraviolet LED 134 to the lead frames 111 and 112.
Different from the white light emitting device 100 illustrated in
The red phosphor 156 employed in example embodiments may use fluoride phosphors illustrated in
In example embodiments, although the protective layer 140 is disposed on a lower surface of the resin encapsulation portion 150, for example, between the resin encapsulation portion 150 and the package body 101, the disposition of the protective layer 140 may be variously changed according to example embodiments. For example, the protective layer 140 may be disposed on both of an upper surface and the lower surface of the resin encapsulation portion 150, or may be disposed to encompass an entirety of the resin encapsulation portion 150.
With reference to
Because the green quantum dot 154 is a quantum dot vulnerable to heat, the green quantum dot 154 may be disposed to be spaced apart from the blue LED 132, a heat source, to prevent heat from deteriorating reliability thereof.
In example embodiments, the green quantum dot 154 may be included in a separately provided wavelength conversion film 160. The wavelength conversion film 160 includes a transparent resin 161 in which the green quantum dot 154 is dispersed. The transparent resin 161 may be formed of a material such as epoxy, silicone, modified silicone, urethane, oxetane, acryl, polycarbonate, polyimide, or a combination thereof.
The wavelength conversion film 160 may be disposed on a path of emitted light. In example embodiments, the wavelength conversion film 160 may be disposed to allow the resin encapsulation portion 150 to cover the package body 101.
In the structure, light emitted by the blue LED 132 may excite the red phosphor 156 in the resin encapsulation portion 150 and the green quantum dot 154 in the wavelength conversion film 160, and thus the white light emitting device 100B may obtain white light. Because the green quantum dot 154 may be disposed in the wavelength conversion film 160, the green quantum dot 154 may be disposed to be spaced apart from the blue LED 132, a heat source, thus maintaining reliability. The red phosphor 156 may use fluoride phosphors illustrated in
With reference to
A conductive pattern connected to the white light emitting devices 100b may be formed on the circuit board 510. Each of white light emitting devices 100b have a structure in which the blue LED 132 is directly mounted on the circuit board 510 in a chip-on-board (COB) scheme different from the case of the white light emitting device 100 illustrated in
With reference to
Each of the white light emitting devices 100c includes the blue LED 132 mounted in the concave portion C of the package body 125 and a resin encapsulation portion 150c encapsulating the blue LED 132. In the resin encapsulation portion 150c, the green quantum dot 154 and the red phosphor 156, satisfying the condition detailed in example embodiments, are dispersed.
With reference to
The backlight 1200 employed in example embodiments represents an example in which white light emitting devices (
A backlight 1500 illustrated in
As illustrated in
As illustrated in
In the structure, the green quantum dot may be disposed to be spaced apart from the light emitting device 100c, thus preventing heat from deteriorating reliability thereof. In addition, the red phosphor may be disposed in a separate package, thus allowing usage of the red phosphor not to be increased.
Different from example embodiments, the wavelength conversion sheet 1550 may be disposed on a different component. For example, the wavelength conversion sheet 1550 may be provided with additional light diffusion plate or light guide panel to be disposed thereon. In the same manner as example embodiments, the wavelength conversion sheet 1550 may be manufactured and used as a separate sheet, or may be provided in a form integrated with a different component such as a light diffusion plate.
In a manner similar to example embodiments, backlights 1600 and 1700 illustrated in
With reference to
Light emitted by the light emitting device 1605 or 1705 may be guided to an inner portion of the light guide panel 1640 or 1740 by the reflector 1620 or 1720. In the backlight 1600 illustrated in
In a manner similar to the wavelength conversion sheet 1550 described in
In the case that the wavelength conversion sheet 1650 or 1750 may only include the green quantum dot, the light emitting device 1605 or 1705 may have a shape including only the red phosphor 156 along with the blue LED 132 in a manner similar to an example illustrated in
A light source of a backlight according to example embodiments may not employ a light emitting device having a separate package body, but a COB-type light source portion illustrated in
With reference to
The backlight 2200 includes a bottom case 2210, a reflective plate 2220, a light guide panel 2240, and a light source portion 2230 provided on at least one side of the light guide panel 2240. The light source portion 2230 includes a printed circuit board 2001 and light emitting devices 2005. The light emitting device may be a white light emitting device according to example embodiments, or the light source portion illustrated in
In addition, in example embodiments, the backlight 2200 may be replaced by any one among the backlights 1200, 1500, 1600, and 1700, illustrated in
The optical sheets 2300 are disposed between the light guide panel 2240 and the image display panel 2400, and may include several types of sheets such as a diffusion sheet, a prism sheet, or a protective sheet.
The image display panel 2400 may display an image using light emitted through the optical sheets 2300. The image display panel 2400 includes an array substrate 2420, a liquid crystal layer 2430, and a color filter layer 2440. The array substrate 2420 may include pixel electrodes disposed in a matrix form, thin film transistors applying a driving voltage to the pixel electrodes, and signal lines allowing for operation of the thin film transistors.
The color filter layer 2440 may include a transparent substrate, a color filter, and a common electrode. The color filter layer 2440 may include filters allowing a wavelength of light to pass therethrough among white light emitted by the backlight 2200. The liquid crystal layer 2430 may be re-arranged by an electric field formed between the pixel electrodes and the common electrode to adjust a light transmitting rate. Light of which a light transmitting rate has been adjusted may pass through the color filter of the color filter layer 2440, thereby displaying an image. The image display panel 2400 may further include a driving circuit processing an image signal, and the like.
According to the display apparatus 2000 in example embodiments, a color reproduction implemented in light passing through the color filter may be significantly increased. A color reproduction region of the display apparatus may cover 90% or more of the DCI region in the CIE 1931 chromaticity diagram, and may also cover 95% or more based on the NTSC region.
As set forth above, according to example embodiments, a white light emitting device may implement colors having a high color gamut by combining a blue LED with a green phosphor and a red phosphor, satisfying the full width at half maximum and the peak wavelength described above. Furthermore, various types of display apparatuses that may cover 90% or more based on DCI may be provided.
While example embodiments have been shown and described above, it will be apparent to those skilled in the art that modifications and variations could be made without departing from the scope of the present inventive concept as defined by the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2016-0001066 | Jan 2016 | KR | national |
