EP3973574A1 - Optoelectronic device comprising light-emitting diodes - Google Patents

Abstract

The present invention concerns an optoelectronic device (10) comprising at least first and second light-emitting diodes (DEL) each comprising a first, p-type semiconductor portion (30) and a second, n-type semiconductor portion (26), an active region (28) comprising multiple quantum wells between the first and second semiconductor portions, a conductive layer (38) covering the side walls (34) of the active region (28) and at least a part of the first semiconductor portion and an insulating layer (36) inserted between the side walls (34) of the active region (28) and at least a part of the conductive layer. The device comprises means for controlling the conductive layer of the first light-emitting diode independently of the conductive layer of the second light-emitting diode.

Description

DESCRIPTION

Light-emitting diode optoelectronic device

The present patent application claims the priority of the French patent application FR19 / 05332 which will be considered as forming an integral part of the present description.

Technical area

The present application relates to an opto-electronic device, in particular a display screen or an image projection device, comprising light-emitting diodes, based on semiconductor materials, and their manufacturing processes.

Prior art

A pixel of an image corresponds to the unitary element of the image displayed by the optoelectronic device. When the optoelectronic device is a color image display screen, it generally comprises for the display of each pixel of the image at least three components, also called display sub-pixels, which each emit light radiation. substantially in one color (eg, red, green, and blue). The superposition of the radiations emitted by these three display sub-pixels provides the observer with the colored sensation corresponding to the pixel of the displayed image. In this case, the display pixel of the optoelectronic device is called the set formed by the three display sub-pixels used for displaying one pixel of an image. Each display subpixel can include at least one light emitting diode.

[0003] It may be advantageous to simultaneously produce several light-emitting diodes by the same steps of the same manufacturing process, in particular for reasons of cost. Active areas of light emitting diodes will then emit electromagnetic radiation at the same wavelength. To obtain display subpixels emitting electromagnetic radiation at different wavelengths, one possibility is to cover certain light emitting diodes with a layer of phosphors suitable for converting the electromagnetic radiation emitted by the light emitting diode into electromagnetic radiation. at a different wavelength. However, it can be difficult to get the desired colors precisely. In addition, the cost of phosphors can be high.

[0004] There is therefore a need for an optoelectronic device with light-emitting diodes comprising display sub-pixels emitting electromagnetic radiation at different wavelengths in which the use of phosphors is reduced or even eliminated.

[0005] Furthermore, for certain applications, there is a need to control the switching on and off of a light-emitting diode without modifying the voltage applied between the electrodes of the light-emitting diode.

Summary of the invention

[0006] Thus, an object of an embodiment is to at least partially overcome the drawbacks of optoelectronic devices comprising light-emitting diodes described above.

[0007] Another object of an embodiment is to reduce, or even eliminate, the use of phosphors.

Another object of an embodiment is to be able to produce simultaneously by common steps several light-emitting diodes suitable for emitting electromagnetic radiation at different wavelengths.

[0009] Another object of an embodiment is that the optoelectronic devices can be manufactured on an industrial scale and at low cost.

[0010] For this purpose, one embodiment provides an optoelectronic device comprising at least first and second light-emitting diodes each comprising a first P-type doped semiconductor portion and a second N-type doped semiconductor portion, an active area comprising wells multiple quantum between the first and second semiconductor portions, a conductive layer covering the side walls of the active area and at least part of the first semiconductor portion and an insulating layer interposed between the side walls of the active area and at least part of the conductive layer, the device comprising means for controlling the conductive layer of the first light-emitting diode independently of the conductive layer of the second light-emitting diode, the optoelectronic device comprising, for each of the first and second light-emitting diodes, a first conductive pad electrically coupled to the first semiconductor portion, a second conductive pad electrically coupled to the second semiconductor portion, and a third conductive pad electrically coupled to the conductive layer.

[0011] According to one embodiment, for each of the first and second light-emitting diodes, the active area comprises multiple quantum wells.

[0012] According to one embodiment, for each active zone, the composition of the quantum well closest to the first semiconductor portion is different from the composition of the quantum well closest to the second semiconductor portion.

[0013] According to one embodiment, for each active zone, each quantum well comprises a ternary compound with first, second and third chemical elements. The mass concentrations of the first chemical element in quantum wells are identical. The mass concentrations of the second chemical element of quantum wells are the same, and the mass concentration of the third chemical element of the quantum well closest to the first semiconductor portion is different from the mass concentration of the third chemical element of the quantum well closest to the second semiconductor portion.

[0014] According to one embodiment, the difference between the mass concentration of the third chemical element of the quantum well closest to the first semiconductor portion and the mass concentration of the third chemical element of the quantum well closest to the second semiconductor portion is greater than 10 percentage points.

[0015] According to one embodiment, the first chemical element is an element from group III.

[0016] According to one embodiment, the first chemical element is gallium.

According to one embodiment, the second chemical element is an element of group V.

[0018] According to one embodiment, the second chemical element is nitrogen.

[0019] According to one embodiment, the third chemical element is an element from group III. [0020] According to one embodiment, the third chemical element is indium.

[0021] According to one embodiment, each light-emitting diode has a "mesa" structure.

[0022] According to one embodiment, for each light-emitting diode, the second semiconductor portion is in the form of a wire.

[0023] According to one embodiment, each light-emitting diode further comprises, between the active area and the first semiconductor portion, an electron blocking layer. According to one embodiment, the first and second conductive pads are electrically insulated from the conductive layer.

[0024] One embodiment also provides for a method of emitting light from an optoelectronic device as defined above, comprising the application of a first electrical voltage between the first and second semiconductor portions of each of the first and second light emitting diodes, applying a second electrical voltage between the conductive layer and the first semiconductor portion of the first light emitting diode, and applying a third electrical voltage between the conductive layer and the first semiconductor portion of the second diode electroluminescent, the third electric voltage being different from the second electric voltage.

Brief description of the drawings

These characteristics and advantages, as well as others, will be explained in detail in the following description of particular embodiments given without limitation in relation to the accompanying figures, among which: [0026] FIG. 1 represents an embodiment of an optoelectronic device comprising light emitting diodes;

[0027] FIG. 2 represents another embodiment of an optoelectronic device;

FIG. 3 represents another embodiment of an optoelectronic device;

FIG. 4 represents an embodiment of a light emitting diode used to carry out simulations;

[0030] FIG. 5 represents curves of the evolution of the internal quantum efficiency of the light-emitting diode of FIG. 4 as a function of the surface density of the current passing through the light-emitting diode;

[0031] FIG. 6 represents curves of the evolution of the energy conversion efficiency of the light-emitting diode of FIG. 4 as a function of the surface density of the current passing through the light-emitting diode;

[0032] FIG. 7 represents the curves of the evolution of the surface density of the current passing through the light-emitting diode of FIG. 4 as a function of the anode-cathode voltage applied to the light-emitting diode;

[0033] FIG. 8 represents curves for the evolution of the rate of radiative recombinations in the active zone of the light-emitting diode of FIG. 4;

[0034] FIG. 9 represents curves of the evolution of the valence band energy in the active zone of the light-emitting diode of FIG. 4; [0035] FIG. 10 represents a curve of the evolution of the concentration of holes in the active zone of the light-emitting diode of FIG. 4;

FIG. 11 represents an evolution curve of the rate of radiative recombinations in the active zone of the light-emitting diode of FIG. 4;

[0037] Figure 12 is similar to Figure 10;

Figure 13 is similar to Figure 11;

[0039] FIG. 14 illustrates a step of an embodiment of a method of manufacturing the optoelectronic device of FIG. 1;

[0040] FIG. 15 illustrates another step of the method;

[0041] FIG. 16 illustrates another step of the method;

[0042] FIG. 17 illustrates another step of the method;

[0043] FIG. 18 illustrates another step of the method;

[0044] FIG. 19 illustrates another step of the method;

FIG. 20 illustrates another step of the method;

[0046] FIG. 21 illustrates a step of an embodiment of a method of manufacturing the optoelectronic device of FIG. 2;

FIG. 22 illustrates another step of the method;

[0048] FIG. 23 illustrates another step of the method;

FIG. 24 illustrates another step of the method;

[0050] FIG. 25 illustrates another step of the method;

[0051] FIG. 26 illustrates another step of the method;

FIG. 27 illustrates another step of the method;

[0053] FIG. 28 illustrates another step of the method; [0054] FIG. 29 illustrates a step of an embodiment of a method of manufacturing the optoelectronic device of FIG. 3;

FIG. 30 illustrates another step of the method;

FIG. 31 illustrates another step of the method;

[0057] FIG. 32 illustrates another step of the method;

[0058] FIG. 33 illustrates another step of the method;

FIG. 34 illustrates another step of the method;

[0060] FIG. 35 illustrates another step of the method; and

[0061] FIG. 36 illustrates another step of the method.

Description of embodiments

The same elements have been designated by the same references in the various figures and, moreover, as is usual in the representation of electronic circuits, the various figures are not drawn to scale. In particular, the structural and / or functional elements common to the different embodiments may have the same references and may have identical structural, dimensional and material properties. In addition, only the elements useful for understanding the present description have been shown and are described. In particular, the structure of a light emitting diode is well known to those skilled in the art and is not described in detail.

In the following description, when reference is made to qualifiers of relative position, such as the terms "upper", "lower", etc., reference is made to the orientation of the figures or to a optoelectronic device in a normal position of use. Unless otherwise indicated, the terms "substantially", "about", "approximately" and "on the order of" mean "to within 10%", preferably to "within 5%". In addition, the region of the light emitting diode from which the majority of the electromagnetic radiation supplied by the light emitting diode is emitted is called the "active area" of a light emitting diode. Unless otherwise specified, when referring to two elements connected together, it means directly electrically connected without intermediate elements other than conductors, and when referring to two elements connected or coupled together, it means that these two elements may be connected or be electrically connected or electrically coupled through one or more other elements. In addition, it is considered here that the terms "insulator" and "conductor" mean respectively "electrically insulating" and "electrically conductive".

Figure 1 is a sectional view, partial and schematic, of an embodiment of an optoelectronic device 10 adapted to the emission of light. According to one embodiment, the optoelectronic device 10 comprises at least two electronic circuits 12 and 14. The first circuit 12 comprises light emitting diodes LEDs. The second circuit 14 comprises electronic components, not shown, in particular transistors, used for controlling the light-emitting diodes of the first circuit 12. The first circuit 12 is fixed to the second circuit 14, for example by molecular bonding or by a connection of the "type". Flip-Chip ", in particular a" Flip-Chip "process by balls or by microtubes. The first circuit 12 is called an optoelectronic circuit in the remainder of the description and the second circuit 14 can be an integrated circuit and is called a control circuit or control chip in the remainder of the description. The optoelectronic device 10 is intended, in operation, to emit light upwards. The optoelectronic circuit 12 comprises, from top to bottom in FIG. 1:

a substrate 16, for example an insulating substrate, at least partially transparent to the electromagnetic radiation emitted by the light-emitting diodes and which delimits an emission face 18 of the optoelectronic device 10, the substrate 16 possibly not being present;

a semiconductor layer 20 doped with a first type of conductivity, at least partially transparent to the electromagnetic radiation emitted by the light-emitting diodes DEL;

- lateral insulation trenches 22 which extend over the entire thickness of the semiconductor layer 20 and which delimit portions of substrate 24 in the semiconductor layer 20, three portions of substrate 24 being shown in FIG. 1, the trenches d side insulation 22 may not be present;

- for each portion of substrate 24, at least one light-emitting diode LED, each light-emitting diode LED comprising an upper semiconductor portion 26 in contact with the corresponding substrate portion 24, an active area 28, and a lower semiconductor portion 30, the active area 28 being interposed between the upper semiconductor portion 26 and the lower semiconductor portion 30, the lower semiconductor portion 30 comprising a lower face 32 on the side opposite to the active zone 28, the stack comprising the upper semiconductor portion 26, the active zone 28 and the lower semiconductor portion 30 forming an island delimited by side walls 34 and the lower face 32; - for each light-emitting diode LED, an insulating layer 36 covering the portion of substrate 24 around the light-emitting diode LED and covering the side walls 34 of the light-emitting diode LED;

- for each light-emitting diode LED, a conductive layer 38, called the gate hereafter, covering the insulating layer 36;

- for each light-emitting diode LED, an insulating layer 40 covering the gate 38 and part of the lower face 32 of the lower semiconductor portion 30, the insulating layer 40 possibly not being present; and

- for each light-emitting diode LED, a first conductive pad 42 in contact with the corresponding substrate portion 24, a second conductive pad 44 in contact with the lower face 32 of the lower semiconductor portion 30 and a third conductive pad 46 in contact with the grid 38.

The control chip 14 comprises, on the side of the optoelectronic circuit 12, for each light-emitting diode LED, three conductive pads 48, 50, 52, the conductive pad

48 being connected to the conductive pad 42, the conductive pad 50 being connected to the conductive pad 44 and the conductive pad 52 being connected to the conductive pad 46. In the case where the control chip 14 is attached to the optoelectronic circuit 12 by molecular bonding, the conductive pads 48, 50, 52 may be in contact with the conductive pads 42, 44,

46. In the case where the control chip 14 is attached to the optoelectronic circuit 12 by a connection of the "flip chip" type, solder balls or microtubes can be interposed between the conductive pads 42, 44, 46 and the conductive pads 48, 50, 52. In the embodiment shown in Figure 1, each light emitting diode LED is said to be of the "mesa" type, that is to say it comprises a stack of flat layers which has been etched to form an island.

Figure 2 is a sectional view, partial and schematic, of another embodiment of an optoelectronic device 55 adapted to the emission of light. The optoelectronic device 55 comprises all the elements of the optoelectronic device 10 shown in FIG. 1, with the difference that the substrate 16 is not present and each light-emitting diode LED is of the axial type, that is to say that the semiconductor portions lower and upper 26 and 30 were made in the form of wires. In FIG. 2, two light-emitting diodes LEDs have been shown for each portion of substrate 24, the associated conductive pad 44 being connected to the lower semiconductor portions 30 of each of the two light-emitting diodes DEL.

Figure 3 is a sectional view, partial and schematic, of another embodiment of an optoelectronic device 60 adapted to the emission of light. The optoelectronic device 60 comprises all the elements of the optoelectronic device 10 shown in FIG. 1, with the difference that the substrate 16 and the semiconductor layer 20 are not present. Further, the light emitting diodes LEDs are divided into groups of at least two light emitting diodes LEDs, and, for each light emitting diode LED, the upper semiconductor portion 26 has a wire shape, the active area 28 has at least partially a conical shape or frustoconical which widens out from the upper semiconductor portion 26, and the lower semiconductor portion 30 is common for the light emitting diodes LEDs of the same group. In addition, for each light-emitting diode LED, the conductive pad 42 is electrically connected to the upper semiconductor portion 26 by a conductive element 61.

Figure 4 is a sectional view, partial and schematic, more detailed of the light emitting diode LED. According to one embodiment, the active zone 28 is the layer from which is emitted the majority of the electromagnetic radiation supplied by the optoelectronic circuit 12. According to one embodiment, the active zone 28 comprises multiple quantum wells. It then comprises an alternation of first semiconductor layers 62, called quantum well layers, and of second semiconductor layers 64, called barrier layers, each quantum well layer 62 being made of a semiconductor material having a forbidden band less than that of the material forming the upper and lower portions 26, 30.

The semiconductor layers and portions 20, 26, 30,

62, 64 are, at least in part, formed from at least one semiconductor material. The semiconductor material is chosen from the group comprising III-V compounds, for example a III-N compound, II-VI compounds or semiconductors or compounds of group IV. Examples of Group III elements include gallium (Ga), indium (In) or aluminum (Al). Examples of III-N compounds are GaN, AIN, InN, InGaN, AlGaN or AlInGaN. Other elements of group V can also be used, for example, phosphorus or arsenic. Examples of Group II elements include Group IIA elements including beryllium (Be) and magnesium (Mg) and Group IIB elements including zinc (Zn), cadmium (Cd) and mercury ( Hg). Examples of Group VI elements include elements of Group VIA, including oxygen (O) and tellurium (Te). Examples of compounds II-VI are ZnO, ZnMgO, CdZnO, CdZnMgO, CdHgTe, CdTe or HgTe. Examples of materials group IV semiconductors are silicon (Si), carbon (C), germanium (Ge), silicon carbide alloys (SiC), silicon-germanium alloys (SiGe) or germanium carbide alloys (GeC) ). The semiconductor layers and portions 20, 26, 30, 62, 64 may include a dopant. By way of example, for III-V compounds, the dopant can be chosen from the group comprising a dopant of type P from group II, for example magnesium (Mg), zinc (Zn), cadmium (Cd) or mercury (Hg), a type P dopant of group IV, for example carbon (C), or a type N dopant of group IV, for example silicon (Si), germanium (Ge), selenium (Se), sulfur (S), terbium (Tb) or tin (Sn).

Each barrier layer 64 can be in the same material as that of the upper and lower portions 26, 30, in particular not intentionally doped. According to one embodiment, each quantum well layer 62 comprises the same III-V or II-VI compound as that forming the upper and lower portions 26, 30 and further comprises an additional element. According to one embodiment, when the upper and lower portions 26, 30 are made of GaN, each quantum well layer 64 can be of InGaN with a mass concentration of In of between 10% and 30%. The thickness of each quantum well layer 62 can be between 3 nm and 10 nm. The thickness of each barrier layer 64 can be between 3 nm and 50 nm.

According to one embodiment, the mass concentration of the additional element in the quantum well layer 64 closest to the upper semiconductor portion 26 is different from the mass concentration of the additional element in the quantum well layer. 64 closest to the lower semiconductor portion 30. According to one embodiment, the difference between the mass concentration of the additional element in the quantum well layer 64 closest to the upper semiconductor portion 26 and the mass concentration of the additional element in the quantum well layer 64 closest to the lower semiconductor portion 30 is greater to 10 percentage points.

According to one embodiment, the upper semiconductor portion 26 consists mainly of a III-N compound, for example gallium nitride, doped with a first type of conductivity, for example of type N. The dopant of type N can be silicon. The concentration of dopants in the upper semiconductor portion 26 may be between 10 ¹⁷ atoms / cm ³ and 5 * 10 ²⁰ atoms / cm ³ . According to one embodiment, the lower semiconductor portion 30 is, for example, at least partially produced in a III-N compound, for example gallium nitride. The portion 30 can be doped with the second type of conductivity, for example of type P. The concentration of dopants in the lower semiconductor portion 30 can be between 10 ¹⁷ atoms / cm ³ and 5 * 10 ²⁰ atoms / cm ³ . The lower semiconductor portion 30 may comprise a stack of at least two semiconductor layers 30 of the same material with different dopant mass concentrations, the layer furthest from the active zone 28 being the most doped.

Each optoelectronic device 10, 55, 60 may further comprise an electron blocking layer 66 interposed between the active area 28 and the P-type doped semiconductor portion 30, preferably in contact with the active area 28 and the P-type doped semiconductor portion 30 The electron blocking layer 66 ensures a good distribution of the electric carriers in the active zone 28 and reduces the diffusion of electrons towards the P-type doped semiconductor portion 30. The blocking layer electron 66 may be formed from a ternary alloy, for example gallium aluminum nitride (AlGaN) or indium aluminum nitride (AlInN). The thickness of the electron blocking layer 66 may be of the order of 20 nm

The conductive layer 38 preferably corresponds to a metal layer, for example made of aluminum, silver, copper, titanium, titanium nitride or zinc. The material forming the conductive layer 38 may be a conductive material and at least partially transparent to the radiation emitted by the light-emitting diode LED such as indium tin oxide (or ITO, acronym for Indium Tin Oxide), from l zinc oxide doped or not with aluminum or gallium, or graphene. The thickness of the conductive layer 38 can be between 0.5 µm and 10 µm

Each insulating layer 36, 40 can be made of a dielectric material, for example of silicon oxide (SZO ₂₎ , of silicon nitride (Si _x N _y , where x is approximately equal to 3 and y is approximately equal to 4, for example Si ₃ N ₄₎ , in silicon oxynitride (SiO _x N _y where x can be approximately equal to 1/2 and y can be approximately equal to 1, for example Si ₂ 0N ₂₎ , in oxide aluminum (AI ₂ O ₃₎ , or hafnium oxide (Hf0 ₂₎ The minimum thickness of the insulating layer 36 in the parts where it covers the side walls 34 of the light emitting diodes LEDs can be between 1 nm and 10 ym. The insulating layer 40 can be made of an organic material. By way of example, the insulating layer 36 is a silicone polymer, an epoxy polymer, an acrylic polymer or a polycarbonate, a white resin, a black resin or a transparent resin loaded, in particular with titanium oxide particles.

Each conductive pad 42, 44, 46, 48, 50, 52 can be at least in part made of a material chosen from the group comprising copper, titanium, tantalum, tungsten or their associated nitrides, nickel, gold, tin, aluminum and the alloys of at least two of these compounds.

According to one embodiment, at least some of the light-emitting diodes LEDs can be covered with a photoluminescent layer comprising suitable phosphors, when they are excited by the light emitted by the associated light-emitting diode LED, to emit light at a wavelength different from the wavelength of the light emitted by the associated light-emitting diode LED. Preferably, no light emitting diode LED is covered with a photoluminescent layer.

In the embodiments illustrated in Figures 2 and 3, each upper semiconductor portion 26 and optionally each lower semiconductor portion 30 has an elongated shape, for example cylindrical, conical or frustoconical, in a preferred direction including at least two dimensions , called minor dimensions, are between 5 nm and 2.5 ym, preferably between 50 nm and 2.5 ym, the third dimension, called major dimension, being greater than or equal to 1 time, preferably greater than or equal to 5 times and even more preferably greater than or equal to 10 times, the greater of the minor dimensions. In some embodiments, the minor dimensions may be less than or equal to about 1 µm, preferably between 100 nm and 1 µm, more preferably between 100 nm and 800 nm. In some embodiments, the height of each semiconductor portion 26 may be greater than or equal to 500 nm, preferably between 1 µm and 20 µm. The base of the upper semiconductor portion 26 has, for example, an oval, circular or polygonal shape, in particular triangular, rectangular, square or hexagonal. [0081] Simulations of the operation of a light emitting diode LED were carried out with the light emitting diode LED structure shown in FIG. 4. The light emitting diode LED had a structure of symmetry of revolution. Figure 4 is a sectional view of half of the light emitting diode LED, the ordinate axis corresponding to the axis of revolution of the light emitting diode LED. For the simulations, the semiconductor portions 26 and 30 of the light-emitting diode LED were cylinders with a circular base with a radius equal to 5 µm. The upper semiconductor portion 26 and the semiconductor layer 20 were made of N-type doped GaN with a dopant concentration equal to 10 ¹⁹ atoms / cm ³ . The lower semiconductor portion 30 was made of P-type doped GaN with a dopant concentration equal to 10 ¹⁹ atoms / cm ³ . The active area 28 comprised multiple quantum wells comprising an alternation of layers 62 of InGaN, each having a mass indium concentration of 16% and a thickness equal to 3 nm, and layers 64 of GaN, unintentionally doped, each having a thickness equal to 10 nm. The active zone 28 comprised five layers 62 of InGaN and six layers 64 of GaN, the layer of the active zone 28 closest to the lower semiconductor portion 30 and the layer of the active zone 28 closest to the upper semiconductor portion 26 being one of the barrier layers 64. The light emitting diode LED further comprised an electron blocking layer 66 made of AlGaN with a mass concentration of aluminum equal to 20%, having a thickness equal to 20 nm and located between the portion lower semiconductor 30 and the active zone 28. The insulating layer 36, when it was present in the simulations, was made of Si0 ₂ and had a thickness of 3 nm. The cathode C of the light emitting diode DEL was simulated by a first constant potential taken equal to 0 V applied to the face 32 of the lower semiconductor portion 30. The anode A of the light-emitting diode LED was simulated by a second constant potential which, unless otherwise specified, was equal to 2.5 V and which was applied to a wall of the substrate portion 24. The gate 38, when present in the simulations, was simulated by a third controllable potential applied to the insulating layer 36 on the side opposite to the side wall 34. For simulations in which the gate 38 is not present, the layer insulator 36 is considered to have infinite thickness.

For some simulations, it was simulated the presence of defects on the side walls 34 of the light-emitting diode LED causing an accumulation of electrons on the side walls 34 by a surface density QssD of non-radiative traps of the donor type and / or resulting in an accumulation of holes on the sidewalls 34 by a surface density QssA of acceptor-type traps A donor-type trap is electrically positive until it has trapped an electron and is electrically neutral when it has trapped an electron. electron. An acceptor-type trap is electrically neutral as long as it has not trapped an electron and exhibits a negative charge when it has trapped an electron. For these defects, when present, the surface density of the traps was 10 ¹⁷ atoms / cm ² , the average duration of recombination of the trap was 10 ^-11 s and the energy of the trap was equal to half of l energy from quantum wells.

FIG. 5 represents evolution curves C1 to C6 of the internal quantum efficiency IQE of the active zone 28 of the light-emitting diode LED, as shown in FIG. 4, as a function of the surface density of the current of power supply I supplied to the anode A and expressed in A / cm ² on a logarithmic scale. Internal quantum efficiency IQE is equal to the ratio between the number of photons created in the active zone 28 and the number of electrons crossing the active zone 28. The internal quantum efficiency is a number without unit which varies between 0 and 1.

FIG. 6 represents the evolution curves DI to D6 of the energy conversion efficiency WPE (acronym for Wall Plug Efficiency) of the light-emitting diode LED, as shown in FIG. 4, as a function of the surface density of the supply current I supplied to the anode A and expressed in A / cm ² on a logarithmic scale The energy conversion efficiency WPE is equal to the ratio between the optical power supplied by the light emitting diode and the power power consumed by the light emitting diode. Compared with the internal quantum efficiency IQE, the energy conversion efficiency WPE takes into account the efficiency of extracting light from the light-emitting diode LED, the efficiency of electric injection and the loss of energy between the incident electron and the photon created.

The curves C1 and DI were obtained without a grid and without traps. The curves C2 and D2 were obtained without a grid and with traps of the donor type. Curves C3 and D3 were obtained without a grid and with acceptor type traps. Curves C4 and D4 were obtained without a grid and with acceptor type traps and donor type traps. Curves C5 and D5 were obtained without traps and with the grid maintained at -2 V. Curves C6 and D6 were obtained with traps of the donor type and with the grid maintained at -2 V. Curves C7 and D7 have were obtained with acceptor type traps and with the grid maintained at -2 V.

As shown in the figure, each evolution curve C1 to C7 passes through a maximum before decreasing. Applying a negative voltage to the grid allows, in in the case where donor type traps are present, to increase the maximum value of the IQE and makes it possible, in the case where acceptor type traps are present, to keep the maximum value of the IQE and to postpone the decrease in the IQE.

FIG. 7 represents evolution curves E1 and E2 of the surface density of current I, expressed in A / cm ² according to a logarithmic scale, crossing the light-emitting diode as a function of the anode-cathode voltage VAC applied to the light-emitting diode LED. Curve E1 was obtained without traps and without grid. Curve E2 was obtained without traps and with the gate held at -2 V. The threshold voltage of the light emitting diode when the gate is set to -2 V is lower than the threshold voltage of the light emitting diode without gate. Therefore, when the anode-cathode voltage is constant, the intensity of the current flowing through the light-emitting diode and therefore the light power emitted by the light-emitting diode can be controlled by the voltage applied to the grid 38.

According to one embodiment, the optoelectronic device 10, 55, 60 comprises light-emitting diodes LEDs to which a substantially constant anode-cathode voltage is applied, and the extinction or ignition of each of these light-emitting diodes and / or the control of the light power emitted by each of these light-emitting diodes is carried out by controlling the voltage applied to the gate 38 of each of these light-emitting diodes. The voltage applied to the grid 38, which is to be modulated, is advantageously less than the anode-cathode voltage.

FIG. 8 represents, as a function of the position, of the evolution curves F1 to F4 of the radiative recombination rate TRR in the layers 62, 64 of the active zone 28 of the light emitting diode LED, only the four quantum well layers 62 closest to the upper semiconductor portion 26 of N-type doped GaN being shown, the leftmost quantum well layer 62 in FIG. 8 being the closest to the upper semiconductor portion 26 of N-type doped GaN. Curves F1 to F4 were obtained without traps and with an anode-cathode voltage of 2.5 V. Curve F1 was obtained with a gate voltage of 1 V. curve F2 was obtained with a gate voltage of 0 V. Curve F3 was obtained with a gate voltage of -1 V. Curve F4 was obtained with a gate voltage of -2 V. It appears that the InGaN layer 62 closest to the upper semiconductor portion 26 of N-type doped GaN is activated when the gate voltage decreases.

FIG. 9 represents evolution curves G1, G2, G3 and G4 of the energy of the valence band BV in the layers 62 and 64 of the active zone 28, in the electron blocking layer 66 and in the upper semiconductor portion 30 of the light-emitting diode DEL obtained under the same conditions respectively as the curves F1, F2, F3 and F4. The application of a negative voltage to the gate 38 causes a decrease in the potential barrier seen by the holes coming from the lower semiconductor portion 30 of P-type doped GaN.

FIG. 10 represents an evolution curve H of the concentration of CH holes, expressed in holes / cm ³ on a logarithmic scale, in the layers 62, 64 of the active zone 28 of the light-emitting diode DEL. Curve H was obtained without traps, with an anode-cathode voltage of 2.5 V and without a grid. As shown in this figure, in the absence of a gate, the concentration of holes decreases as one moves away from the semiconductor portion 30 of P-type doped GaN. FIG. 11 represents an evolution curve J of the rate of radiative recombination TRR, expressed in number of occurrences / cm ³ , in the layers 62, 64 of the active zone.

28, and in the electron blocking layer 66 of the light emitting diode LED. Curve H was obtained without traps, with an anode-cathode voltage of 2.5 V and without a grid. As shown in this figure, in the absence of a gate, only the quantum well 62 closest to the semiconductor portion 30 of P-type doped GaN is activated.

FIG. 12 represents an evolution curve K of the concentration of holes, expressed in holes / cm ³ on a logarithmic scale, in the layers 62, 64 of the active zone 28 of the light-emitting diode LED. The K curve was obtained without traps, with an anode-cathode voltage of 2.5 V and with a gate voltage of -2 V. As shown in this figure, in the presence of the gate 38 to which a voltage is applied. of -2 V, the hole concentration increases as one moves away from the semiconductor portion 30 of P-type doped GaN.

FIG. 13 represents an evolution curve L of the radiative recombination rate TRR, expressed in number of occurrences / cm ³ , in the layers 62, 64 of the active zone.

28 of the light emitting diode LED. Curve H was obtained without traps, with an anode-cathode voltage of 2.5 V and with a gate voltage of -2 V. As shown in this figure, in the presence of the gate 38 to which a voltage is applied. of -2 V, substantially only the quantum well 62 closest to the semiconductor portion 30 of P-type doped GaN is activated.

FIGS. 10 to 13 illustrate the fact that the quantum well or the activated quantum wells can be selected by controlling the voltage applied to the gate 38. According to one embodiment, at least two wells quantum cells of each light-emitting diode LED are adapted to emit electromagnetic radiation at different wavelengths, for example the quantum well closest to the semiconductor portion 26 and the quantum well closest to the semiconductor portion 30. This means that 'at least a first quantum well of each light emitting diode LED is adapted to emit a first electromagnetic radiation at a first wavelength and a second quantum well of each light emitting diode LED is adapted to emit a second electromagnetic radiation at a second length of wave different from the first wavelength. When the quantum wells are in InGaN, this can be obtained by forming these quantum wells with different mass concentrations of indium. For a first light emitting diode, the gate voltage of the first light emitting diode can be controlled to activate substantially only the first quantum well and, for a second light emitting diode, the gate voltage of the second light emitting diode can be controlled to activate substantially only the second quantum well. In this way, two light-emitting diodes of the same structure are obtained which emit electromagnetic radiation at different wavelengths.

Figures 14 to 21 are sectional views, partial and schematic, of structures obtained in successive steps of an embodiment of a method of manufacturing the optoelectronic device 10 shown in Figure 1. The method comprises the following steps:

1) formation on the support 16, for example by growth by epitaxy, of a stack comprising the semiconductor layer 20, a semiconductor layer 70 of the same composition as the upper semiconductor portion 26 previously described, semiconductor layers 72 of the same composition as the semiconductor layers 62, 64 of the active zone 28 described previously, a semiconductor layer 73 of the same composition as the electron blocking layer 66 described previously, and a semiconductor layer 74 of same composition as the lower semiconductor portion 30 described above (FIG. 14).

2) etching of the semiconductor layers 70, 72, 73 and 74 to define, for each light-emitting diode LED, the upper semiconductor portion 26, the active area 28, the electron blocking layer 66 and the lower semiconductor portion 30 (figure 15).

3) forming the side insulating trenches, not shown, in the semiconductor layer 20 and forming, for each light-emitting diode LED, the insulating layer 36 covering the semiconductor layer 20 and the side walls 34 of the island and not covering the face 32 of the island (figure 16).

[0100] 4) training, for each light-emitting diode

LED, the conductive layer 38 covering the insulating layer 36, that is to say covering the semiconductor layer 20 and the side walls 34 of the island and not covering the face 32 of the island, and formation of the insulating layer 40 covering the conductive layer 38 and the face 32 of each light-emitting diode LED (figure 17)

[0101] 5) etching of layers 36, 38 and 40 to expose part of face 32 of each light-emitting diode LED, part of conductive layer 20 and part of layer 38 (FIG. 18).

[0102] 6) forming the conductive pads 42, 44 and 46 for each light-emitting diode LED (FIG. 19). [0103] 7) fixing the optoelectronic device shown in FIG. 19 to the control circuit 14 (FIG. 20).

The method can comprise subsequent steps of removing the support 16 and cutting to delimit the optoelectronic devices 10.

[0105] FIGS. 21 to 28 are partial and schematic sectional views of structures obtained in successive steps of an embodiment of a method of manufacturing the optoelectronic device 55 shown in FIG. 2. The method comprises the following steps:

[0106] the) formation, on the support 16, of the semiconductor layer 20 and formation, for each portion of substrate 24, for example by epitaxial growth of at least two stacks each comprising the semiconductor portion 26 of wire form, the active zone 28 and the semiconductor portion 30 of wire form described above (FIG. 21), the electron blocking layer 66 not being shown. Examples of methods of growing semiconductor portions of wire form are described in US 9,245,948.

[0107] 2 ') forming the side insulating trenches, not shown, in the semiconductor layer 20 and forming, for each group of light-emitting diodes LEDs, the insulating layer 36 covering the semiconductor layer 20 and the side walls 34 of the wires (figure 22).

[0108] 3 ') formation, for each group of light-emitting diodes DEL, of the conductive layer 38 covering part of the insulating layer 36 (FIG. 23).

[0109] 4 ') forming, for each group of light-emitting diodes DEL, the conductive pad 46 in contact with the conductive layer 38 (FIG. 24). [0110] 5 ') formation of the insulating layer 40 (Figure 25).

[0111] 6 ') formation, for each light-emitting diode

LED, the conductive pad 44 in contact with the face 32 of each wire (Figure 26).

[0112] 7 ') formation, for each group of light-emitting diodes DEL, through insulating layers 40 and 36, of the conductive pad 42 in contact with the semiconductor layer 20 (FIG. 27).

[0113] 8 ') fixing the optoelectronic device shown in FIG. 27 to the control circuit 14 and removing the support 16 (FIG. 28).

Figures 29 to 36 are sectional views, partial and schematic, of structures obtained in successive steps of an embodiment of a method of manufacturing the optoelectronic device 60 shown in Figure 3. The method comprises the following steps:

[0115] 1 ") formation, on the support 16, of the semiconductor layer 20 and, for each group of light-emitting diodes LEDs, of at least two stacks, three stacks being shown, each comprising the semiconductor portion 26 of wire form, the active zone 28 of flared shape and formation of the semiconductor portion 30 in contact with the active zones 28 (FIG. 29), the electron blocking layer 66 not being shown.

[0116] 2 ") forming the lateral insulating trenches, not shown, in the semiconductor layer 20 and forming, for each group of light-emitting diodes LEDs, the conductive pad 42 in contact with the semiconductor layer 20 and the conductive pad 44 at the contact of face 32 (figure 30).

[0117] 3 ") fixing the optoelectronic device shown in Figure 30 to the control circuit 14 (Figure 31). [0118] 4 ") removal of the substrate 16 (Figure 32).

[0119] 5 ") formation, for each group of light-emitting diodes DEL, of the insulating layer 36 (FIG.

33).

[0120] 6 ") forming, for each group of light emitting diodes LEDs, an opening 82 in the insulating layer 36 to expose a part of the conductive layer 20, and forming the conductive layer 38 covering the insulating layer 36 and s 'extending into opening 82 (figure

34).

[0121] 7 ") formation, for each group of light-emitting diodes DEL, of the conductive pad 46 in contact with the conductive layer 38 in the opening 82 (FIG. 35).

[0122] 8 ") formation, for each group of light-emitting diodes DEL, of the conductive element 61 connecting the conductive pad 42 to the semiconductor portions 26 (FIG. 36).

Various embodiments and variants have been described. Those skilled in the art will understand that certain features of these various embodiments and variants could be combined, and other variants will be apparent to those skilled in the art. In particular, in the embodiments described above, the assembly comprising a gate 38 and the insulating layer 36 can be replaced by one or more metal portions forming one or more Schottky contacts with the materials of the quantum wells. In this case, the metallic portion or portions are in direct contact with the semiconductor materials of the quantum wells, without any insulation material placed between the semiconductor materials and the metallic material. To form such a Schottky contact, the metal used is preferably chosen from metals exhibiting a work of important output, such as for example tungsten whose work output is equal to about 6.1 eV, or platinum. The choice of metal used to form such Schottky contacts depends in particular on the semiconductor materials used. Finally, the practical implementation of the embodiments and variants described is within the abilities of those skilled in the art based on the functional indications given above.

Claims

1. Optoelectronic device (10; 55; 60) comprising at least first and second light-emitting diodes (LEDs) each comprising a first semiconductor portion (30) doped P type and a second semiconductor portion (26) doped N type, a active area (28) comprising multiple quantum wells between the first and second semiconductor portions, a conductive layer (38) covering the side walls (34) of the active area (28) and at least part of the first semiconductor portion and a insulating layer (36) interposed between the side walls (34) of the active area (28) and at least part of the conductive layer, the device comprising means for controlling the conductive layer of the first light-emitting diode independently of the conductive layer of the second light-emitting diode, the optoelectronic device comprising, for each of the first and second light-emitting diodes, a first pl ot conductor (44) electrically coupled to the first semiconductor portion, a second conductive pad (42) electrically coupled to the second semiconductor portion, and a third conductive pad (46) electrically coupled to the conductive layer.

2. An optoelectronic device according to claim 1, wherein, for each of the first and second light-emitting diodes (LEDs), the active area (28) comprises multiple quantum wells.

3. Optoelectronic device according to claim 2, in which, for each active area (28), the composition of the quantum well (62) closest to the first semiconductor portion (30) is different from the composition of the quantum well (62) closest to the second semiconductor portion (26).

4. An optoelectronic device according to claim 3, wherein, for each active area (28), each quantum well (62) comprises a ternary compound with first, second and third chemical elements, wherein the mass concentrations of the first chemical element of the quantum wells (62) are identical, in which the mass concentrations of the second chemical element of the quantum wells (62) are identical, and in which the mass concentration of the third chemical element of the quantum well (62) closest to the first semiconductor portion (30) is different from the mass concentration of the third chemical element of the quantum well (62) closest to the second semiconductor portion (26).

The optoelectronic device according to claim 4, wherein the difference between the mass concentration of the third chemical element of the quantum well (62) closest to the first semiconductor portion (30) and the mass concentration of the third chemical element of the quantum well ( 62) closest to the second semiconductor portion (30) is greater than 10 percentage points.

6. An optoelectronic device according to claim 4 or 5, wherein the first chemical element is an element of group III.

7. An optoelectronic device according to any one of claims 3 to 6, wherein the first chemical element is gallium.

8. An optoelectronic device according to any one of claims 3 to 7, wherein the second chemical element is a group V element.

9. An optoelectronic device according to any one of claims 3 to 8, wherein the second chemical element is nitrogen.

10. An optoelectronic device according to any one of claims 3 to 9, wherein the third chemical element is a group III element.

11. An optoelectronic device according to any one of claims 3 to 10, wherein the third chemical element is indium.

12. An optoelectronic device according to any one of claims 1 to 11, wherein each light emitting diode (LED) has a "mesa" structure.

13. An optoelectronic device according to any one of claims 1 to 12, wherein, for each light emitting diode (LED), the second semiconductor portion (26) is in the form of a wire.

14. An optoelectronic device according to any one of claims 1 to 13, wherein each light emitting diode (LED) further comprises, between the active area (28) and the first semiconductor portion (30), a layer (66) of electron blocking.

15. An optoelectronic device according to any one of claims 1 to 14, wherein the first and second conductive pads (44, 42) are electrically insulated from the conductive layer (38).

16. A method of light emission from an optoelectronic device (10; 55; 60) according to any one of claims 1 to 15, comprising applying a first electrical voltage between the first and second semiconductor portions (26, 30) of each of the first and second light emitting diodes (LEDs), applying a second electrical voltage between the conductive layer (38) and the first semiconductor portion (30) of the first light emitting diode and the application of a third electrical voltage between the conductive layer (38) and the first semiconductor portion (30) of the second light emitting diode, the third electric voltage being different from the second electric voltage.