Patent Description:
USA patent No. <CIT>, describes the directional thermal emitter of electromagnetic radiation based on two-dimensional (2D) array of heavily doped semiconductor structures formed on the solid substrate surface with a thin layer of noble metal added to fill the array troughs. Proposed device generates highly directional radiation at specified wavelengths via thermal excitation of surface plasmon polaritons (SPPs), which are polarization waves of free electron plasma propagating at metal-dielectric interface, on a metal surface side, where the radiation of selected mode is highly directional in the angle defined by dispersion law of the SPP. Silicon and indium arsenide semiconductors are used for fabrication of rectangular shape 2D structures, required for generation of SPP quasiparticles. Drawback of proposed method is a design complexity, proposed shape of 2D structures, which fabrication requires precise procedures, a stacking of various materials, such as IV group semiconductors for SPP excitation and noble metals to maximize light reflectivity, and last but not least, the excited SPPs radiate in different angles according to the dispersion law. The fabrication, exploitation and even reliability of the device face many problems due to these specific requirements. Moreover, the spatial coherence of SPP quasiparticles is small because the damping factor of electron or hole plasma oscillations is large. Even more, it degrades with semiconductor doping and especially under heavily doping regime when it is required doping values as large as <NUM><NUM>cm-<NUM>. The application of proposed method is narrow, the integration in one system a few of various wavelength emitters, where each radiate beam in a different angle, is complicated. USA patent application No. <CIT>, describes the thermal IR emission device based on the surface phonon-polaritons (SPhPs) excited in the array of nano-scale polar semiconductor material structures arranged on the substrate. In this case, the damping factor of SPhP oscillations is considerably smaller in comparison to their counterparts SPPs. Therefore, the quality factor (linewidth) of SPhPs device emission is much higher (narrower) with acceptable emission power levels even at moderate temperatures. However, method propose the usage of complex designs employing multi-layer material stacks of the ferroelectrics, heater materials, which utilize complex electrical current drive through the heater and its heat dissipation, and materials changing phase from a "metallic" to a "dielectric" state, where each has individual requirements on functionality and specific physical properties such as high heat conductivity, transparency in the IR region, etc. All these make the fabrication and exploitation of the IR emission device very complex, limit its practical application. Moreover, the operation frequency range of the device is narrow, limited by oscillation frequencies of the TO and LO phonons of undoped polar semiconductor with additional requirement for IR transparency, and the excited SPhPs radiate in different angles according to the dispersion law.

USA patent application No. <CIT>, which describes the spectrally-selective metamaterial emitter based on the SPPs excitation in the array of concentric rings designed to convert heat energy into a highly directional beam. The emitter is integrally formed on the surface of a solid substrate, forming concentric circular ridges and intervening concentric circular grooves which separate the ridges by the same period. When the metamaterial emitter is heated to the operating temperature (e.g., <NUM>), surface plasmons radiation of thermal energy is highly directional (i.e., <NUM>% of the emitted radiant energy is within <NUM>° of perpendicular to the planar outward-facing surface), narrow band (i.e., the full-width at half maximum of the emitted radiant energy is within <NUM>% of the peak emission wavelength), and a its peak emission wavelength is roughly equal to the grating period (i.e., the peak emission wavelength is within <NUM>% of the grating period).

The method proposes to form a "multiplexed" pattern of overlapping concentric rings, where multiplexing of spectrally-selective metamaterial emitters is performed in order to increase spectral bandwidth and maximize radiant energy concentration to the photo-voltaic (PV) cell. Emitter and method for emitting radiant energy have limited applications because the concentration and mixing of adjacent narrowband spectra are done with the aim to maximize emitter performance in a wide spectrum range.

Used metals for the excitation of SPPs possess large damping factors which result in a small value of the spatial coherence of the polaritons. Proposed device is developed for photo-voltaic applications where the thermal energy of broadband excess heat is converted into electricity by passing the in-band photons to an associated target photo-voltaic cell. However, such device is not suitable in the spectroscopy, imaging, secure communication, big-data transfer, and similar applications.

Even more, all-metal construction of the metamaterial emitter is designed to operate at high temperatures, from <NUM> to <NUM>° K, and that limits practical applications of the device. Moreover, the usage of refractory metals (e.g., Rhenium, Tantalum or Tungsten) and their alloys, used usually in high-performance jets and rocket engines, rises emitter cost which limits number of applications.

Closest analogue is <NPL>, investigating the radiation properties of hybrid surface plasmon phonon polaritons (SPPhPs) excited in heavily doped n-type gallium nitride (GaN) gratings discovered to radiate transverse magnetic (TM) polarized electromagnetic waves in the angle defined by the dispersion law of SPPhPs. It was discovered that doped GaN semiconductor characterized by oscillation frequencies of transverse TO and longitudinal LO optical phonons and free charge carrier plasma with respective oscillation damping factors can be used for the excitation of hybrid SPPhP modes in the surface relief grating made of a linear shape and of a period, filling factor, and depth of <NUM>, <NUM> %, and <NUM> respectively (<NPL>). A year later, a comprehensive investigation of different period but the same <NUM> % filling factor gratings revealed the dispersion characteristics of hybrid SPPhPs, radiation of which was found in a narrowband spectrum range demonstrating experimental values of the angular broadening and the linewidth to be as small as <NUM> deg and <NUM>-<NUM>, respectively. The narrowest linewidth of the emission peak was found always near the TO phonon frequency demonstrating similar quality factor values independently from change in grating period. Meanwhile, the coherence length was found to be dependent on the period as the propagation losses of hybrid SPPhP modes showed a tendency to accumulate with the decrease of period values.

The known spectrally selective and directional thermal emitter of electromagnetic radiation comprises a solid substrate made of a polar semiconductor material, which is characterized by a transverse TO and longitudinal LO optical phonons, described by respective oscillation frequencies νTO and νLO, wavelengths λTO and λLO, and damping factors ΓTO and ΓLO, which volume is doped with free charge carriers of one type, electrons or holes, with an oscillation frequency of free carrier plasma, νP, which is higher than oscillation frequency of a longitudinal optical phonons νLO, and on a surface of which integrally is formed a surface grating of ridges (<NUM>) of a width W and grooves (<NUM>) periodically arranged with a period P at a depth h, wherein h is in a range of λTO/<NUM> to λTO/<NUM>, so that the surface hybrid plasmon-phonon polaritons to radiate transverse magnetic (TM) polarized electromagnetic waves at the frequencies νosc which with the wavevector are connected by a relationship kosc= 2πνosc.

The use of the known emitter is limited, because in this emitter is uncontrolled excitation of different modes, their radiate in different angles not the one, and possess large propagation losses resulting in poor spectral quality and increased angular broadening of SPPhP radiation. Moreover, not optimal shape and periodic grove parameters as well as arrangement of the surface-relief gratings result in deterioration of beam quality and power therefore limit applications of known method.

This invention aims to increase number of practical applications of spectrally selective thermal emitters, simplifying and simultaneously reducing the fabrication cost, increasing reliability, and achieving sustainable usage of wasted thermal energy.

This is achieved by the proposed spectrally selective and directional thermal emitter of electromagnetic radiation according to claims <NUM>-<NUM>.

The proposed emitter generates in normal direction a quasi-monochromatic, coherent beam enhanced by the excitation of hybrid polaritons employing integral solid-state solutions. Such emitter is useful for thermo-photoelectric, bio-sensor, chemical-sensor, etc. applications where compact solution for narrowband (quasi-monochromatic) and directive (coherent) emission driven by heat and electrical current sources is needed in the spectrum range from <NUM> THz till <NUM> THz.

The emitter may also radiate at other frequencies, however, its radiation is weak at all non-optimized frequencies. Therefore proposed spectrally selective thermal emitter radiates only in normal direction, which is convenient in number of applications such as, information exchange, powering of devices from wasted thermal radiation, recycling and utilization of thermal energy, information consolidation and allocation, data transfer, contactless irradiation and concentration of thermal energy, spectroscopic imaging and spectroscopy.

The hybrid polaritonic (HP) emitter is proposed to fabricate of polar semiconductor material in a form surface grating, where different sign but the same frequency hybrid polariton modes are used to generate the beam in normal direction with a small angular broadening and narrow spectral linewidth, the operation frequency is selected from the range of νTO-<NUM>ΓTO to νLO+<NUM>%, where the deviation of <NUM>% from νLO frequency is for a case of n-GaN grating with νP/νLO ≥ <NUM>.

Since according to the claimed invention, the grating filling factor is ranging from <NUM> % to <NUM>% value, the propagation losses of the hybrid polaritons in polar semiconductor material grating are considerably smaller in comparison to those found for gratings with the filling factor of <NUM> %.

The invention describes the selectable frequency source emitting thermal energy coherently in one, perpendicular direction as the result of the excitation and constructive interaction of the hybrid surface plasmon-phonon polaritons (hybrid polaritons - HPs) in the surface grating. Proposed HP device can be fabricated of a heavily doped polar semiconductor, such as GaN, AIN, SIC, InSb, GaAs, etc., material in which the interaction of photons (light) with material phonons and plasmons produces the quasiparticles - hybrid-polaritons, which oscillations damping factor is significantly reduced due to hybridization phenomenon of polaritons, described in our previous research.

Parameters of phonons and electrons for several commercially available polar semiconductors are summarized in Table <NUM>. Volume doping of selected polar semiconductor material is needed to be of such size that the oscillation frequency of free charge plasma, νP, should be higher than the LO phonon frequency, νLO, in that material. For example, volume doping of the GaN material, possessing the transfer TO phonons with frequency of <NUM>-<NUM> and the longitudinal LO phonons with frequency of <NUM>-<NUM>, is required with donor impurities to the level of electron density of <NUM>. 37E+<NUM>-<NUM> and <NUM>. 50E+<NUM>-<NUM> in order to fulfill condition νP = νLO and νP ≈ <NUM>νLO, respectively. This principle can be applied to all polar semiconductors, which are listed in Table <NUM> and others, which are considered to use in the development of the HP device for a specific spectrum range (see column "Range <NUM>" in Table <NUM>), without deterioration of the linewidth and the spatial coherence length values, which are determined by material TO and LO phonon oscillation frequencies, νTO and νLO, and damping factors, ΓTO and ΓLO, and oscillation parameters of the free charge plasma, νP and ΓP, respectively.

Cross section view of one-dimensional periodic grating, used for the excitation of surface polaritons, is shown in <FIG>. Hybrid polaritons will be generated in the surface grating, when the grating <NUM> is fabricated of the polar semiconductor material which volume is doped with free charge carriers of one type, electrons or holes, up to the level of such size that the oscillation frequency of charge plasma, νP, is higher than the oscillation frequency of longitudinal optical phonons, νLO, i.e. νP/νLO > <NUM>. Geometrical parameters of the grating: the period, the width of ridge <NUM> and the depth of groove <NUM> are labeled as P, W, and h respectively. Excited hybrid polaritons radiate electromagnetic waves at the specific frequency νosc with the wavevector kosc, in the direction, angle of which φ is measured from normal vector <NUM> to the surface. In case of one-dimensional grating, the polaritons radiate light of transverse magnetic (TM) polarization, ETM, which electric field component is oriented perpendicular to the grating grooves. Background thermal radiation is also observed in transverse electric (TE) polarization, ETE, with light electric field component oriented parallel to the substrate surface and the grating grooves. Periodic shallow groove structures of selected period and filling factor, FF = W/P, are integrally fabricated on the surface of polar semiconductor by using an UV photolithography procedures followed by reactive ion etching with aim for a small surface roughness and small number of fabrication defects as it has been demonstrated in our previous research. Optimal groove depth for polaritons excitation in n-GaN grating is approximately of <NUM>, corresponding to λTO/ <NUM>, where λTO is the wavelength of TO phonons. For other polar semiconductors, the optimal groove depth can be further adjusted modeling numerically a hybrid polariton dispersion by RCWA (Rigorous Coupled Wave Analysis) method. It is known that in case of undoped SiC semiconductor, the optimal groove depth for the excitation of surface polaritons is λ / <NUM>, which is about twice less than used in case of a heavily doped polar semiconductors for the excitation of the hybrid polaritons.

Polaritons are waves propagating at air/material or material/material interface and possessing an electromagnetic filed amplitude decay in the normal direction to the interface with maximum field value at the interface. Such surface waves (evanescent waves) interact with periodic profile of the grating and radiate to a free space at the angle φ and at the frequency νosc, values of which are found by solving the dispersion equation for hybrid polaritons: <MAT> wherein ε<NUM> and εs are the complex dielectric functions of materials possessing positive (air) and negative (polar semiconductor in the Reststrahlen band) values of real part of complex numbers, respectively, M is the mode number which is an integer (M = <NUM>, <NUM>,. In case of isotropic approximation, the complex dielectric function of polar semiconductor is defined by the phonon and plasmon parameters: <MAT> wherein ε∞ is the high frequency dielectric constant of polar semiconductor material. The first term of this equation describes the contribution of phonon oscillations and the second the contribution of free charge plasma oscillations to the dielectric function of material, where the plasmon oscillation frequency, νp, is proportional to the density, N, and the effective mass, m*, of free charge carriers as <MAT>, where c is the speed of light in vacuum c = <NUM> × <NUM><NUM> (cm/s). It is worth to note that when φ = <NUM>, the equation (<NUM>) is valid for two modes with the same frequency but opposite sign, i.e. M = -<NUM> or M = +<NUM>, M = -<NUM> or M = +<NUM>, etc. Therefore, two polariton modes with positive and negative sign of the same frequency can be generated in the grating fabricated of polar semiconductor material, here a positive sign indicates polariton propagation towards direction of the light Poynting vector, while a negative sign - its backward propagation.

Equations (<NUM>)-(<NUM>) are generalized and can be applied describing hybrid polaritons in different polar semiconductor materials, characterized by phonon and plasmon oscillation frequencies and damping factors, which numerical values depend on the selected material nature, production and processing technology. The performance of the HP emitter is found by the use of sample made of n-GaN crystal, which phonon and plasmon parameters are obtained experimentally and are summarized in Table <NUM>. All characteristics of the HP emitter are measured numerically by using the RCWA method, which provides a good quantitative description of the experimental results of shallow n-GaN gratings with different period as it has been demonstrated in our previous research.

<FIG> shows the dependence of the HP emitter frequency, νosc, and the amplitude, Am, calculated as the difference between the TM and TE polarization emissivities, on the grating period at the emission angle φ=<NUM> deg. The numerical solution of Equation (<NUM>), in a case of a flat polar semiconductor surface, i.e. without taking into account the propagation losses of hybrid polaritons in the grating, is shown by the corresponding dotted lines for the first, M±<NUM>, and second, M±<NUM>, order modes. The result differs from that obtained by the RCWA method, especially in the higher frequency region, where the dotted lines deviate significantly from the zone center where the emissivity is highest (black-gray color). It worse to note that such emitter is suitable to generate the frequencies from νTO to <NUM> %, i.e. νTO ≤ νosc ≤ <NUM> νLO or νTO ≤ νosc ≤ <NUM> νTO. It should be noted also that the maximum frequency range in which the HP emitter operates can be adjusted by varying the density of free charge carriers in the volume of polar semiconductor material as discussed above. For gratings made of various polar semiconductor materials, the operating frequency range from νTO-2ΓTO to <NUM> νLO is given in column "Range <NUM>" of Table <NUM>.

<FIG> shows the frequency and radiation angle characteristic of the fundamental harmonics of the HP emitter using the grating with fixed filling factor and period to values of FF=<NUM> and P<NUM>=<NUM>, respectively. The numerical solutions of Equation (<NUM>) for each M =+<NUM> and M =-<NUM> modes are shown by dotted lines. It is seen that in one, normal direction, when φ=<NUM> deg, the frequencies of both modes coincide and are equal to νosc=<NUM>-<NUM>, fosc=<NUM> THz (intersection point of the lines).

<FIG> shows the angular characteristics <NUM>, <NUM>, and <NUM> of the fundamental harmonics at the selected frequency fosc=<NUM> THz of the HP emitter radiation, which were found for the filling factor FF = <NUM> gratings of the period P<NUM> of <NUM>, <NUM>, and <NUM>, respectively. It demonstrates that the hybrid polaritons emit polarized light in the normal direction, φ=<NUM> degrees, in a narrow range of angles (<NUM>, solid line), i.e. the angular broaderning of the beam, Δφ, is found to be less than <NUM> degrees.

<FIG> reveals the dependence of M±<NUM> modes amplitude, Am characteristic <NUM>, and the emission direction, angle φ characteristic <NUM>, on the grating period, P. It is seen that by changing the lattice period from <NUM> iki <NUM>, the modes M±<NUM> emission angle changes from ±<NUM> to <NUM> deg, the amplitude decreases, and in a vicinity of the angle φ=<NUM> deg, the amplitude suddenly increases due to a constructive interaction between two modes. It is worth to note that at the limit of φ=<NUM> deg and P=<NUM>, the shape of angular emission characteristic <NUM> of the HP emitter (see <FIG>) becomes symmetric with the angular broadening at full width half maximum and the coherence length values being down to Δφ=<NUM> deg and up to Lsc=<NUM>λosc, respectively. When the periodicity is further increased in the range of P values between <NUM> and <NUM>, the modes M±<NUM> split, their emission anlge deviates from the normal direction, angular characteristics become more asymmetric, and their amplitudes decrease. Thus, the condition of the same frequency and direction for both M±<NUM> (or higher order) modes is fulfilled only at the emission angle of φ=<NUM> deg, under this condition the total emission amplitude of the HP emitter is enhanced by the constructive interaction between two modes possessing the same frequency but an opposite sign.

The propagation losses of the hybrid polaritons, ΓPL, are smallest near the frequency of the TO phonons, νosc≈νTO, and, in case of symmetric n-GaN gratings, their value is ΓPL=<NUM>-<NUM>, as it has been found in our previous research. These propagation losses of hybrid polaritons must be evaluated and taken into account in the development and application of the HP emitter. Here we propose to reduce propagation and radiation losses of hybrid polaritons by the optimization of grating filling factor value and/or by the usage of higher order polariton harmonics.

<FIG> shows the dependence of the oscillation frequency of the HP emitter radiating in normal direction, νosc, on the grating period, P, at various filling factor values at the fundamental and second order harmonics. The dependence of the numerical solution of equation (<NUM>) on the grating period is shown by a gray dashed line labeled as "Light line".

The results in <FIG> reveal how the spectral quality, Q, (the linewidth normalized to the operation frequency, Δνosc/νosc) of the emitter radiation depends on the variation of the grating period in the range from <NUM> to <NUM> for same grating filling factors and mode numbers, which are listed in <FIG>. , while data in <FIG> reveal respective dependences for the amplitude, Am, of the HP emitter radiation.

The results demosntrate that at FF=<NUM>, the spectral quality of the first and second modes of hybrid polyarithon radiation in all frequency range under consideration is higher than that found for the gratings with filling factor of <NUM>%, which are not covered by the subject-matter of the claims, described in our previous research. There is a practical interest in the frequency range from νTO-ΓTO to νTO+<NUM>%, where the propagation losses of hybrid polaritons in the grating are small and where polaritons emit a high spectral quality beam with Q values up to <NUM> or even higher due to the constructive interaction between the same frequency, opposite sign modes radiating in normal direction. This frequency range for different materials is indicated in column "Range <NUM>" of Table <NUM>.

It should be noticed that the spectral quality of the radiated beam can be also improved by choosing a higher mode number. For example, in case of M±<NUM>, the spectral quality of radiated beam is also high due to smaller polariton propagation losses in the grating with FF=<NUM> (see <FIG>) Obtained quality facetor values are higher than that found in case of fundamental modes in the grating with FF=<NUM>, which emission amplitude remains higher up to <NUM> times (see <FIG>). The examples with FF=<NUM> or FF=<NUM> are not covered by the subject-matter of the claims.

The dependence of the fundamental harmonic of the HP emitter operation frequency on the filling factor is shown in <FIG>. These results reveal that, when the grating filling factor, FF, is in the range of <NUM> to <NUM>, which is not covered by the subject-matter of the claims, selecting the mode number and the period, one has to take into account also the frequency νosc dependence on the period P, which is shown in <FIG>. When the filling factor is <NUM>, which is not covered by the subject-matter of the claims, the spectral linewidth is limited to value of Δν ≈ <NUM>-<NUM> due to significant propagation losses of hybrid polaritons, found in our previous research. In this case, the parameters of the radiated beam of the HP emitter, based on n-GaN grating with νP ≈ <NUM>. 5νLO, for various operation frequencies, raging from νTO-2ΓTO to νTO+<NUM>%, are summarized in Table <NUM>.

However, the propagation losses of hybrid polariton modes in the grating are significantly reduced by selecting the filling factor of the range <NUM> to <NUM> as required by the claimed invention. In this case, <FIG> and <FIG> reveal that the HP emitter radiation frequency νosc is inversely proportional to the period P or emitted wavelength λosc is approximately equal to P. Such the emitter will radiate narrow spectral line, high spectral quality beam with large coherence length and small angular broadening if its operation frequency, νosc, is from the range of νosc ≈ νTO±ΓTO, where the excited hybrid polariton oscillations in polar semiconductor possess very small values of the damping factor.

In case of FF=<NUM>, the highest spectral quality (Q = <NUM>), the narrowest spectral linewidth (Δν=<NUM>-<NUM>), the highest coherence (Lsc = <NUM> λosc) with the smallest angular broadening (Δφ = <NUM> deg) of the radiated beam of the emitter first harmonic is found at the frequency νosc=<NUM>-<NUM>. Meanwhile, when the second harmonic of the HP emitter is selected for operation, maximum values of the respective parameters of radiated beam are found to be of Q = <NUM>, Δν=<NUM>-<NUM>, Lsc= <NUM> λosc, and Δφ = <NUM> deg at the νosc=<NUM>-<NUM>. The parameters of the radiated beam of the HP emitter, based on n-GaN grating with νP ≈ <NUM>. 5νLO, for various oscillation frequencies ranging from νTO-<NUM>ΓTO to νTO+<NUM>% of the first and second harmonics are summarized in Table <NUM> and Table <NUM>, respectively.

In case of larger filling factor value, FF=<NUM>, which is not covered by the subject-matter of the claims, maximum values of the respective parameters of the radiated beam of the emitter first harmonic are found to be only of Q = <NUM>, Δν=<NUM>-<NUM>, Lsc = <NUM> λosc ir Δφ = <NUM> deg, at the νosc=<NUM>-<NUM>, due to high propagation losses of hybrid polaritons in the grating. The results of the HP emitter for other frequencies, raging from νTO-2ΓTO to νTO+<NUM>%, are summarized in Table <NUM>.

It should be noted that the results in <FIG> are also plotted on normalized scales, where the HP emitter frequency is normalized to the TO phonon frequency, νTO, and the grating period is normalized to the wavelength, λTO. Since equations (<NUM>)-(<NUM>) are generalized and apply to any polar semiconductor, described by the corresponding phonon and free charge plasma parameters, the n-GaN results in <FIG> can be directly used in the production of HP emitter for different frequencies. This is demonstrated in Table <NUM>, where other polar semiconductor, such as SiC, AIN, InP, GaAs, InAs, InSb, or the like materials are selected for grating production, without altering the quality and directivity characteristics of the radiated beam of hybrid polaritons.

<FIG> shows the electromagnetic field plot of the first harmonic TM component of the HP emitter with the grating period P<NUM>=<NUM> and filling factor FF=<NUM> operating at the frequency νosc = <NUM>-<NUM>. It is seen that in case of maximum coherence, the field profile is no longer evanescent, indeed a constructive interaction of surface waves of the same frequency is observed found, resulting in lower HP propagation losses and intense radiation in normal direction.

<FIG> shows the electromagnetic field plot of the second harmonic TM component of the HP emitter with the grating period P<NUM>=<NUM> and filling factor FF=<NUM> operating at the frequency νosc = <NUM>-<NUM>.

Thus, the results in both <FIG> reveal that the radiation profiles are symmetric with respect to the center of the ridge <NUM> and the groove <NUM> of the grating without a difference first or second or higher order modes are excited. Therefore, we propose to define and use the axis of symmetry in the HP emitter design.

The design of the HP emitter grating with radial symmetry <NUM> with respect to the axis <NUM>, which extends through the center of the ridge <NUM>, is shown in <FIG>. Radial symmetry is obtained rotating an one-dimensional grating by <NUM> degrees around the axis of symmetry <NUM>, which optionally can be placed either in the center of a ridge <NUM> or center of a groove <NUM>, forming an array of concentric rings as seen in <FIG>.

Such HP emitter with radial symmetry is used to radiate only one selected frequency modes of all polarizations in normal direction, along the axis of symmetry <NUM>, with small angular broaderning of radiated beam due to the constructive interaction of HPs on the surface grating.

The power supply of the HP emitter is implemented by using material own thermal and electrical conductivities, which values are high due to the sufficient free charge density in a volume of dopped polar semiconductor. In the proposed emitter, the hot <NUM> and cold <NUM> electrodes are pressed, welded, glued, or otherwise connected to the back side of the HP emitter substrate at the center <NUM> and the edge of the outer diameter <NUM> of grating zones, respectively. The powering may be realized by heating from the hot plate, that raises the temperature of the HP emitter to that which is suitable for explotation of the polar semiconductor material, and/or by basing electric current, the amplitude of which can be further modulated in the frequency range of <NUM>-<NUM>, with the maximum value being limited by the heat capacity of the device and by the resistance of thermal contact. The thickness of the polar semiconductor material, h<NUM>, also influences the modulation rate, and it should be at least <NUM> in a case of n-GaN to ensure an optical transparency not larger than <NUM>% for all frequencies ranging from <NUM>-<NUM> to <NUM>-<NUM>.

An outer diameter of the HP emitter with radial symmetry should be the same as the coherence length of the hybrid polaritons, LSC. In addition, Breg mirrors <NUM> can be integrated at a maximum distance equal to LSC value measuring from the center <NUM> across the entire perimeter of HP emitter, in order to increase the selection of HP modes, in analogy to one used in laser or resonator systems based on standard mirror approach. If the outer diameter of the radial HP emitter is smaller than the size of LSC, then the usage of the Breg mirrors <NUM> allows the reduction of material amount and surface area required for the fabrication of a single emitter without detoriation of spectral quality and angular broaderning of the radiated beam.

Bragg mirror for polaritons is composed of a relief structure of different periodicity, depth, and filing factor processed on the same surface of the semiconductor material as the grating, and/or made of metal that is used for connection of electric current and/or heat electrodes to the HP emitter powering zones <NUM> and <NUM>.

<FIG> shows the HP emitter <NUM> whose radiation is detected by a small diameter sensor <NUM>. Back side view of the emitter substrate shows zones where "hot" <NUM> and "cold" <NUM> electrodes can be connected, while the Bragg mirror <NUM> over an entire perimeter of the emitter is seen in a top view. In this case, the sensor works as a spatial element whose diameter D defines the field of view angle, Δφdet, for collection of the HP emitter radiation, described by the coherence length, LSC, and beam broadening angle, Δφ. Optimum condiction is when both spatial angles are equal, i.e.. If the field of view angle is too large, then the detector will measure background radiation not related to coherent radiation of the HP emitter, resulting in a reduction of the signal to noise ratio. Such a design, when it is necessary to select the diameter of the sensor and/or the distance to the HP emitter in order to fulfill the condition Δφdet= Δφ, may not always be convenient.

<FIG> shows the HP emitter <NUM> whose radiation is detected by a sensor <NUM> of any shape with dimensions larger than a real experimental field of view angle, Δφdet. For this, it is proposed to use a non-radiating pinhole, PH, <NUM> as a spatial filter defining the field of view angle, Δφdet, which is used to transmit the coherent beam and block background radiation unrelated to the emitter coherent radiation. In this case, the best beam quality of the HP emitter is achieved when the outer diameter of the emitter is equal to the coherence length LSC and the aperture PH defines the field of view angle, Δφdet, to be equal to the beam broadening angle, Δφ.

<FIG> shows the design of the HP emitter with radial symmetry <NUM> assembled in a radial shape metal holder <NUM>,<NUM>,<NUM> with an axis <NUM>, in which the emitter is fixed by mean of an annular clamp <NUM>. Power is provided using good electrical and thermal conductivities of the polar semiconductor substrate, provided by free-charge carriers. The HP device is powered either by electrical current or thermal heating from the element with hot <NUM> and cold <NUM> electrodes, separated by an insulator <NUM> and clamped to the polar semiconductor substrate in the central <NUM> and outer zones <NUM> by an annular clamp <NUM>. In this way, the metal clamp <NUM> is used to fix the HP emitter grating in the holder and as a cold electrode for power supply. Spatial filtering of the coherent beam is done by a non-radiating pinhole PH <NUM> which is additionally fixed in the holder by means of a ring-shaped clamp <NUM> above the grating.

It is worth to note that the increase of the HP emitter temperature increases the power of coherent beam proportionally to the change of temperature. The fabricated HP emitter of n-GaN can operate at +<NUM> or even higher temperatures limited by the melting temperature of the material (+<NUM> ° C) and/or a possible increase of the damping factor of phonon oscillations, which has not been observed under laboratory conditions up to <NUM>. Unique physical and chemical properties of the GaN make the HP emitters, fabricated of this semiconductor, suitable for the applications in various chemical activity liquids, gases, or environments with high radioactivity, in a wide range of temperatures, <NUM>-<NUM>.

<FIG> shows the arrangement of few HP emitters <NUM>, <NUM>, <NUM>, each with radial symmetry <NUM>, <NUM> and a non-radiating pinhole filter <NUM>, <NUM>, in the corners of an equilateral triangle in order to form a primitive cell. Larger area is filled translating such cell in a plane of the required size and shape, the power radiated in normal direction from each HP emitter pixel is measured by single large-area detector. Such the design of multi-pixel HP emitters allows the increase of total emission power in proportion to the number of pixels. Densest filling of multi-pixel HP emitters is achieved in an equilateral triangular design, resulting in maximum coherent radiation power which is possible to obtain from an unit area.

Claim 1:
Spectrally selective and directional thermal emitter of electromagnetic radiation comprising a solid substrate made of a polar semiconductor material (<NUM>), which is characterized by transverse TO and longitudinal LO optical phonons, described by respective oscillation frequencies νTO and νLO, wavelengths λTO and λLO, and damping factors ΓTO and ΓLO, which volume is doped with free charge carriers of one type, electrons or holes so, that a volume doping of the material is such, that an oscillation frequency of free carrier plasma, νP, is higher than the oscillation frequency of longitudinal optical phonons νLO, and on a surface of which integrally is formed a surface grating of ridges (<NUM>) of a width W and grooves (<NUM>) periodically arranged with a period P at a depth h, wherein h is in a range of λTO/<NUM> to λTO/<NUM>, wherein excited hybrid surface plasmon-phonon polaritons radiate transverse magnetic (TM) polarized electromagnetic waves at the frequencies νosc, which with the wavevector are connected by a relationship kosc= 2πνosc, in an angle φ, defined as the inclination angle between the direction of wavevector kosc and a normal direction (<NUM>) of the surface grating, wherein the surface grating formed integrally with solid substrate (<NUM>) is configured so, that to fulfill parameter set as follows:
- an operation frequency νosc of hybrid surface plasmon-phonon polaritons is in a frequency range from νTO-2ΓTO to <NUM> νLO depending on a polariton mode number M, the period P and a filling factor FF, wherein FF=W/P, of the surface grating,
- a radiation of said operation frequency νosc is in the normal direction (<NUM>) when the angle φ=<NUM> ,
- the hybrid surface plasmon-phonon polaritons, being of a opposite sign but the same M=±<NUM>, M=±<NUM>, or higher mode number, interact in the surface grating constructively,
characterised in that the filling factor FF is in the range from <NUM> % to <NUM> %.