USE OF A SPIN TRANSITION MATERIAL TO MEASURE AND/OR LIMIT THE TEMPERATURE OF ELECTRONIC/PHOTONIC COMPONENTS

Abstract

The invention relates to the use of a spin transition material to measure and/or limit the temperature in an electronic and/or photonic component, to methods for thermometrically measuring and/or limiting the overheating of components, as well as to electronic or photonic components comprising a film composed of said spin transition material.

Claims

1. An electronic or photonic component comprising a film deposited over all or part of said component, said film comprising a spin transition material, characterized in that the spin transition material has the following properties: a. said spin transition material has a spin transition temperature of between 40 and 100° C. with a hysteresis width less than 1° C., b. the stability of said spin transition temperature on cycling is greater than 10,000 thermal cycles with a reproducibility less than or equal to 1° C.; c. said material is sublimable.

2. The electronic or photonic component according to claim 1, wherein said spin transition material is [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2].

3. The electronic or photonic component according to claim 1, wherein said spin transition material is deposited in the form of a continuous and uniform thin layer with a thickness of between 10 nm and 10 μm, over at least part of its surface.

4. An electronic circuit or photonic device comprising at least one electronic or photonic component according to claim 1.

5. A method for preparing an electronic or photonic component according to claim 1, comprising the step of depositing said spin transition material by sublimation or spin coating on all or part of said electronic or photonic component.

6. (canceled)

7. A method for limiting the temperature in an electronic or photonic component and/or a circuit comprising an electronic or photonic component according to claim 1, below a temperature Tmax, wherein the temperature Tmax is equal to the spin transition temperature of said spin transition material, said method comprising: a. measuring a temperature increase of said electronic or photonic component and/or the circuit during its operation, wherein when said temperature reaches the value temperature Tmax, said spin transition material undergoes an endothermic spin transition toward a high-spin phase and absorbs all or part of the overheating energy, thereby limiting the temperature increase until transformation of said spin transition material toward the high-spin phase is complete.

8. A method for measuring a temperature increase beyond a temperature Tmax within an electronic or photonic component and/or a circuit comprising an electronic or photonic component as defined according to claim 1, wherein a spin transition temperature of the spin transition material is equal to the temperature Tmax, said method comprising: a. measuring at least one optical property of said material when said component and/or circuit is off, b. measuring the at least one optical property of said material when said component and/or circuit is on, c. identifying zones for which said at least one optical property varies following the spin transition of said spin transition material.

9. The method according to claim 8, wherein steps b) and c) are repeated at different base temperatures below the temperature Tmax, by increasing and/or decreasing the temperature of said component and/or circuit, and a map of the temperature of said electronic or photonic component and/or the circuit is established.

10. The method according to claim 8, wherein one or more optical are measured and are chosen from among optical index, the optical reflectivity and optical absorbency.

Description

FIGURES

[0044] FIG. 1 shows the evolution of optical properties of a thin film of [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2]200 nm thick as a function of temperature: (a) Optical absorption (λ equals 317 nm) as a function of the temperature measured after 4.1858 and 10,321 thermal cycles. These measurements demonstrate the high resilience of the material, the transition temperature of which remains invariant (ΔT<1° C.) after more than 10,000 thermal cycles (b) Optical reflectivity (λ=452 nm) measured on a thin film deposited on a glass substrate, showing a relative variation in reflectivity of −5.8% during the transition from the low-spin state to the high-spin state. (c) Variation in the optical index of the thin film (measured at λ=500 nm) as a function of temperature.

[0045] FIG. 2 shows a photograph of the electrical connector (on the left) and of the testing device used in example 1, consisting of a substrate (20×10 mm) made from silicon (in the upper right) or glass (in the lower right) on which 7 gold nanowires are developed.

[0046] FIG. 3 shows a scanning electron microscopy image of a gold nanowire (width: 1 μm, length: 80 μm, thickness: 50 nm).

[0047] FIG. 4 illustrates the thermometry measurements done on a nanowire of the testing device covered by a layer of [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2] 200 nm thick: (a) Reflectivity images (λ=452 nm) obtained by optical microscopy of the nanowire during operation on a glass substrate (traveled by an electric current of 4 mA) at different base temperatures (T.sub.a=30° C., 40° C. and 50° C.) and drawing of isothermal lines. (b) Map of temperatures obtained during the operation of the gold nanowire heated by Joule effect.

[0048] FIG. 5 illustrates the temperature limitation measurements of a gold nanowire of the testing device (glass substrate) covered by a layer of [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2] 900 nm thick: Evolution of ΔT.sub.wire, measured 30 μs after injection of the 20 mA electric current, as a function of the base temperature for the active compound (complex of Fe, [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2]) as well as for a similar, but inactive compound (complex of Zn, [Zn(HB(1,2,4-triazol-1-yl).sub.3).sub.2]).

[0049] FIG. 6 shows the temperature increase (ΔT.sub.wire) experienced by a gold nanowire (on a glass substrate) during the time following the sudden injection of a 20 mA electric current for 350 μs, for different base temperatures of the device.

[0050] The following examples non-limitingly illustrate the present invention.

EXAMPLES

[0051] 1. Preparation of the Material [0052] Said material is synthesized according to the protocol described in the article Chem. Ber., 1994, 127, 1379.

[0053] 2. Deposition on a Component [0054] The deposition of the thin film of [Fe(HB(1,2,4-triazol-1-yl).sub.3).sub.2] on the testing device was done by thermal evaporation in a PREVAC vacuum deposition chamber pressure of about 2×10.sup.−7 mbar. The powder of the compound was first purified by sublimation, then evaporated at 250° C. at a speed of 0.03 Å/s. The evaporation speed and the thickness of the film were monitored in situ by a quartz microbalance. The obtained films were next subject to a steam treatment, which allowed stable and uniform nanocrystalline films to be obtained [J. Mater. Chem. C, 2017, 5, 4419].

[0055] 3. Revelation of Thermometric Properties

[0056] As illustrated in FIG. 1, the transition of the material is accompanied by a significant change in the optical properties of the thin film, in particular of the optical absorbency (FIG. 1a), the optical reflectivity (FIG. 1b) or the optical index (FIG. 1c). This allows the use of different optical techniques to detect the spin transition.

[0057] This transition is also accompanied by a state change enthalpy (latent heat) of about 33 kJ/kg (endothermic transition during the passage from the low-spin state to the high-spin state (heating) and exothermic otherwise (cooling)). This latter property may therefore be used to significantly limit a temporary temperature increase.

[0058] As shown in FIG. 1a, the temperature and the transition properties of the thin films of said material are not significantly affected, even after more than 10,000 thermal cycles in ambient air.

[0059] A thermal map of an electronic circuit was done with a spatial resolution of the order of a micrometer through a series of optical reflectivity measurements. The experimental protocol consists in recording the image of the device covered with said material under optical microscopy (in reflectivity mode) before and after powering on the microcircuit.

[0060] As shown by FIG. 2, this experimental protocol was validated on a test device that consists of gold nanowires (width: 1 μm, length: 80 μm, thickness: 50 nm) developed by electronic lithography and photolithography on silicon or glass substrates. This entire device was covered with a thin film of said material 200 nm thick, deposited by thermal evaporation under vacuum. The injection of the 4 mA DC electric current, using a SourceMeter (Keithley 2611A) and a suitable connector, causes heating of the nanowire by Joule effect. Images of the device are recorded by reflectivity (λ=452 nm), before and after its operation, owing to an optical microscope (Olympus BX51) equipped with a ×50 objective (numerical aperture NA=0.5) and a CCD camera (Andor Technology Clara, 1392×1040 pixels with size 6.45 μm). In the optical reflectivity image of the nanowire during operation, two zones are then discernible (FIG. 3): a zone, close to the wire, whose reflectivity has changed during the injection of the current and whose temperature is therefore beyond the transition temperature; and a zone whose optical reflectivity remains unchanged. These two zones are separated by an isothermal line for which the temperature increase corresponds exactly to the difference between the transition temperature of said material (Tien) and the ambient temperature (T.sub.a). One of the advantages of this method is that the determination of the temperature increase on this isothermal line may be done without any prior calibration of the reflectivity. Subsequently, heating or cooling of the microcircuit assembly—the latter being placed on a heating/cooling system (Linkam Scientific LTS 120)—to different ‘base temperatures’ T.sub.a allows as many isothermal lines as desired to be recorded. All of these isothermal lines may next be grouped together on a temperature map (FIG. 4).

[0061] 4. Revelation of Thermal Inertia Properties

[0062] This ‘temperature limitation’ property has been demonstrated on the same test device consisting of a gold nanowire on a glass substrate, covered by a thin film of said material, and heated by Joule effect following the sudden injection of a 20 mA electric current (FIGS. 5 and 6). During this experiment, the temperature increase of the wire was able to be determined precisely over time (with a temporal resolution of the order of a μs) by measuring the temporal variation of the electric resistance of the wire (which varies linearly with its temperature) using a custom-manufactured differential resistance measuring device [Microelectronics Journal 46 (2015) 1167-1174]. As shown in FIG. 6, the temperature increase of the wire ΔT.sub.wire was able to be measured over time for different base temperatures of the device, monitored by a heating/cooling system (Linkam Scientific LTS120). As shown in FIG. 5, the heating of the wire, measured 30 μs after the injection of the current, shows a minimum when the base temperature of the wire is close to the transition temperature. This reduction in the heating of the wire occurs because part of the heat given off by the wire has been absorbed by the spin transition material. The same experiment done when the nanowire is covered by a similar, but inactive compound (complex of Zn, [Zn(HB(1,2,4-triazol-1-yl).sub.3).sub.2]), shows a linear behavior in the heating of the wire as a function of the base temperature (FIG. 5).