The paper shows the microfabrication processes of a Ruthenium-based resistance temperature detector and its behavior in response to irradiation at ambient temperature. The radiation test was done in a public hospital facility and followed the procedures based on the ESA specification ESCC 22900. The instrumentation system used for the test is detailed in the work describing the sensors resistance evolution before, during, and after the exposure. A total irradiation dose of 43 krad with 36 krad/h dose rate was applied and a subsequent characterization was performed once the Ru sensors were submitted to an 80°C annealing process during a period of 168 h. The experimental measurements have shown the stability of this sensor against total ionizing dose (TID) tests, not only in their resistance absolute values during the irradiation phase but also in the relative deviation from their values before irradiation.
1. Introduction
Resistive thermometry is being used in science and industry since final decades of XIX century, as metals show predictable dependence of their electrical resistance on temperature. Platinum is the metal that combines high temperature linearity, repeatability, sensitivity, and stability. Resistive elements made of copper combine the highest linearity with temperature with poor robustness against corrosion as it starts to oxidize only above 100°C. Nickel and its alloys bring about the advantage of their high temperature coefficient and low cost but worse linearity than platinum. In particular, this metal covers the widest range of temperature, from cryogenic values (liquid helium, 4.2 K) to melting point (like gold, 1337 K) [1].
When measuring temperature near absolute zero, the Ruthenium oxides have been used extensively because of their high sensitivity and resolution [2–6]. At ambient temperatures, metallic Ru has also been explored in a wide range of applications, as integrated on a compact water quality measurement system [7] or to compensate the thermal drift of magnetoresistive (MR) current sensors [8]. Particularly, these types of sensors are being used to measure and control the electrical current in spacecraft power systems [9]. At the same time, accurate thermal control of various sections of the equipment used on board minimizes failures and power consumption.
Batteries, propulsion subsystems, generic electronics, or infrared channels must be thermally controlled within their operation range, which includes a temperature interval comprised between 120 K and 420 K [10, 11]. Ruthenium temperature sensors can be directly integrated in the electronic circuits as a thin film form, therefore bringing about an alternative to be used in the thermal control units of spacecraft systems.
The present work describes an experimental methodology to investigate the stability of Ru thin film temperature sensors under irradiation, following the mandatory protocol for evaluating sensors and electronics components prior to their onboard integration in space missions. The European Space Agency (ESA) procedure described in the specification ESCC 22900 was used in its main statements [12]. As a result, the feasibility to use Ru films as temperature sensors in spacecraft environments is assessed through their stability against a total ionizing dose (TID).
2. Device Fabrication and Layout
Silicon 100 650 μm thick wafer was used as substrate for the sensors. A 1800 Å thick Al2O3 layer was deposited by RF magnetron sputtering (200 W, 45 sccm Ar, 3.8 mTorr) for electrical insulation. Then, the temperature sensors were defined by laser lithography (DWL Lasarray 2.0, 442 nm laser beam) with the geometry shown in Figure 1, where the 850 μm × 280 μm area was used to imprint the serpentine layout defining the active sensor.
Relevant dimensions of the Ru sensor film.
A 400 Å thick Ru film was then deposited by ion beam deposition process (IBD, Nordiko 3600 tool [13]) and defined by lift-off. Electrical contacts consist of a 3000 Å thick AlSiCu metal layer deposited by magnetron sputtering (Nordiko 7000 machine, 2 kW, 3 mTorr, 50 sccm Ar) and protected with 150 Å thick TiWN2 films. The subsequent lift-off and cleaning steps defined the connections pattern shown schematically in Figure 2.
Connections pattern definition of the Ru sensor after lift-off and cleaning steps.
Finally, passivation was accomplished using a 3000 Å thick silicon nitride (Si3N4) dielectric layer deposited by plasma-assisted chemical vapor deposition (electrotech machine, at 300°C, 850 mTorr with SiH4, NH3, and N2 gases flux) over the wafer, using reactive plasma-etching (LAM machine ion-enhanced fluorine-based plasma, at 140 mTorr with Ar, CF4, and O2 gases flux) technique to define the contact pads holes over the dielectric layer. Figure 3 shows the actual layout of the microfabricated Ru sensor.
Actual layout of the Ru temperature sensor.
3. Experimental Methodology
The irradiation procedure followed the ESA specification [12] and was carried out at the facility of the Radiotherapy Department within the La Fe University Hospital in Valencia (Spain).
In the experiment, three Ru thin film sensors were irradiated by an X-rays photons beam produced by the source of accelerated electrons. Figure 4 shows the target area (40 cm × 40 cm) enclosing the printed-circuit-board where the Ru sensors were placed.
Ru sensors placed in the irradiation area.
The beam consisted of a photons spectrum up to 6 MeV of energy with an average of 2 MeV and a radiation dose of 36 krad/h (6 Gy/min). That value was a compromise between the standard dose used at the hospital facility and the rate group considered in the ESA specification [12]. Also, a maximum irradiation level of 43 krad was decided as the optimum dose taking into account the time needed by the irradiation facility for the patients therapy. That dose level sets the room usage to less than 80 min, being enough to accomplish the 43 krad level identified as the D class in [12]. The ambient temperature during the experiment was stable at 19.5°C fulfilling either the requirement of t=20±10°C or the specification that variations should be lower than 3°C during the irradiation time.
The specification described in [12] stated that sensors under test must be characterized once the irradiation exposure finishes. In particular, the Ru sensor resistance was measured at the same temperature after 12, 24, and 168 h of total irradiation time. Afterwards, the sensors were submitted to an annealing process of 168 h at 80°C and finally their resistance was measured once again at the initial temperature of 19.5°C. To pass or fail the test, stability criteria of 1°C as a maximum variation during the exposure time were assumed.
Before submitting the Ru sensors to the irradiation exposure, a temperature characterization was done to know the Ru temperature coefficient, TCRRu, its temperature sensitivity, S, and the reference resistance at 0°C, RRu,o. To do this, the sensors resistance was obtained measuring the voltage drop across their terminals when circulating a 1 mA DC current. Previous works with similar sensors found a thermal resistance of about 0.06°C/mW driving with 1 mA. Considering that value, the temperature deviation due to self-heating was estimated less than 0.02%. In a specific application, the driving current would be lesser. Simultaneously, the sensors were submitted inside a climate chamber to a temperature sweep from 0°C to 80°C in steps of 10°C. Figure 5 shows the acquisition system designed to measure the voltage across each of the Ru sensors once they were supplied with a 1 mA independent current source. In this experiment, the voltmeter and switches CH1 to CH4 were implemented by the unit 34970A from Agilent. The resistance measurements uncertainty was obtained from an electronic current source implemented with a reference voltage Vref and a precision resistor R, both components with a relative uncertainty of about 0.1%. The voltage measurements across the sensors were taken using the unit 34970A from Agilent. This equipment has a 61/2-digit built-in digital voltmeter. Doing several calculations, these data made an uncertainty of 0.15% for the sensors resistance measurements.
Measurement and acquisition system designed to characterize the Ru sensors (voltmeter and switches CH1 to CH4 were implemented by the unit 34970A from Agilent).
Figure 6 shows the experimental resistance-to-temperature characteristic of the three Ru sensors with their average temperature coefficients, from which a very good linearity was obtained in that temperature range.
Experimental resistance-to-temperature characteristic of the Ru samples Ru_20, Ru_21, and Ru_22 before irradiation.
4. Experimental Results and Discussion
Once the resistance-to-temperature characteristic was obtained in the absence of irradiation, the resistance of the sensors was measured during the irradiation time as the total dose was increased (Figure 7). Figure 8 shows the deviation with respect to the initial nonirradiated value, from which a high stability can be obtained, with maximum variation of 0.5%, 0.46%, and 0.2%, respectively, for samples Ru_20, Ru_21, and Ru_22. The temperature variation associated with the irradiation time was of 0.5°C, 0.9°C, and 0.9°C, respectively; these values were less than the stability criteria assumed initially.
Resistance dependence under increasing irradiation doses, for the 3 Ru sensors.
Percentage change of the irradiated Ru sensors compared with the initial nonirradiated one.
Following the procedure described in the previous section, the Ru sensors resistance was obtained at 12, 14, and 168 h after the irradiation time and at the end of an additional 168 h annealing period at 80°C. All the resistance measurements were taken at the same initial temperature of the experiment (19.5°C).
Figure 9 shows how the relative deviation in % of each irradiated sensor with respect to the reference one varies from the initial % before irradiation. It can be concluded that the measurements done reveal that the Ru electrical resistance, apart from this optimum linearity as a temperature sensor, has a strong stability against total ionizing dose tests. The sensors manifest slight variation not only in their resistance absolute values during the irradiation phase but also in their relative deviation from the previous irradiation values. The electrical resistance stability can be extended when comparing, as basic specification [12] states, the relative deviation with respect to a reference sensor before and after irradiation.
Variation of the relative deviation of Ru resistance with respect to the reference sensor: (a) Ru_20, (b) Ru_21, and (c) Ru_22 samples.
5. Conclusions
The aim of the work was to demonstrate the feasibility of thin film Ru resistors as temperature detectors under irradiation exposure. The validation was carried out under the protocol described in the ESA ESCC basic specification 22900. The measurements obtained by the designed instrumentation system revealed excellent stability with the irradiation doses (less than 0.5% variation up to 40 krad). The observed sensor behavior remained stable (less than 0.7% variation) after a 168 h annealing period at 80°C. As a consequence, Ru-based resistance temperature sensors offer an interesting choice to use in space instrumentation and control systems requiring integrated temperature measurement at the conventional range (from 120 K to 420 K). Further research is being done combining total ionizing doses and cryogenic temperatures to evaluate the Ru sensors feasibility to be applied in cryogenic instruments or systems, integrated with the electronic components.
Competing Interests
The authors declare that they have no competing interests.
Acknowledgments
The authors would like to thank Dr. J. Pérez Calatayud, Director of the Radiotherapy Service at the La Fe Hospital (Valencia, Spain), for his kindness to provide the hospital facilities for this work. This work was supported in part by the Spanish Ministry of Economics and Competitivity under the AYA2012-37444-C02-01 Project by the Generalitat Valenciana under the Prometeo/2012/044 Project and by the 217152-312630 Grant of the Consejo Nacional de Ciencia y Tecnología (CONACYT México). INESC-MN acknowledges FCT funding through Project EXCL/CTM-NAN/0441/2012 and IN Associated Laboratory (Pest-OE/CTM/LA0024/2011).
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