Short Communication
Ying-Chieh Lee
Abstract
A Ni-Cr-Mn-Y-Nb resistive thin ï¬ÂÂlm was prepared in this study using DC and RF magnetron co-sputteringfrom Ni0.45-Cr0.27-Mn0.13-Y0.16 cast alloy and niobium targets. The electrical properties and microstruc-tures of Ni-Cr-Mn-Y ï¬ÂÂlms with Nb addition under various annealing temperatures were investigated. Thephase evolution, microstructure and composition of Ni-Cr-Mn-Y and Ni-Cr-Mn-Y-Nb ï¬ÂÂlms were char-acterized using X-ray diffraction (XRD), ï¬ÂÂeld-emission scanning electron microscopy (FESEM), ï¬ÂÂeld-emission transmission electron microscopy (HRTEM). All Ni-Cr-Mn-Y-Nb ï¬ÂÂlms annealed at 300oCexhibited an amorphous structure. The Ni17Y12crystalline phase was observed in Ni-Cr-Mn-Y-Nb ï¬ÂÂlmswith or without lower Nb content when annealed at 400oC. When the annealing temperature was set to300oC, the Ni-Cr-Mn-Y ï¬ÂÂlms exhibited a resistivity ~480mU-cm with the temperature coefï¬ÂÂcient ofresistance (TCR)at þ30 ppm/oC. However, Ni-Cr-Mn-Y ï¬ÂÂlms with 14 at.% Nb exhibited the smallesttemperature coefï¬ÂÂcient of resistance (þ5 ppm/oC) with the resistivity ~585mU-cm after annealing at300 C in air. Introduction The rapid development and improvement of information andtelecommunication technologies as well as the expansion of digitalindustries are based to a substantial degree on high precision,reliable, integrated, low noise and low power consuming electricalcomponents . The resistor is one of the fundamental componentsused primarily in electronic circuits. The demand for thin ï¬ÂÂlm re-sistors with low temperature coefï¬ÂÂcients of resistance (TCR) andhigh precision has dramatically increased in recent years. An important technical parameter of thin ï¬ÂÂlm resistors is thetemperature coefï¬ÂÂcient of resistance (TCR). A high TCR will result inthe resistance value drifting, influencing the resistor accuracy asthe temperature changes . The main factors influencing TCRinclude the ï¬ÂÂlm composition, sputtering process and annealingtemperature. The ï¬ÂÂlm composition plays a decisive role amongthese three factors. Therefore, employing an appropriate methodfor depositing a suitable ï¬ÂÂlm composition is essential to obtaininghigh-resistance resistors with a low TCR.Extensive rapid development in high entropy alloy (HEA) ï¬ÂÂlmwere obtained recent years by Yeh . High entropy alloys aremulticomponent systems composed of elements displaying anearly equiatomic conï¬ÂÂguration with contents ranging between 5and 35 at.% . It was generally found that high entropy alloys formsimple solid solution structures (rather than manycomplex phases)at elevated temperatures because of their large mixing entropies.However, it is possible to enhance the resistivity of alloy ï¬ÂÂlms usingthe high entropy alloy method. According to Matthiessen's rule: ῤtotat= ῤdefects + ῤrimpuritie + ῤrthermal. 2. Experimental procedure 2.1. Ni-Cr-Mn-Y thin ï¬ÂÂlmNickel (Ni), Chromium (Cr), Manganese (Mn), and Yttrium (Y)powders, as the main raw materials, were chosen to smelt thetarget for high-resistance thin ï¬ÂÂlm resistors. Alloy ï¬ÂÂlms weredeposited onto polished alumina (Al2O3) substrates. These aluminasubstrate were scribed for the TCR measurement into 1.6 ×0.8 mmcell sizes using a laser. Glass and Si wafers were used as substratesfor the sheet-resistance measurements and thin ï¬ÂÂlm thickness,respectively. These substrates were cleaned using a D.I. water-cleaning procedure and dried in nitrogen before loading into thesputtering chamber.Ni-Cr-Mn-Y thin ï¬ÂÂlms that were 80 nm in thickness weredeposited onto the substrates using a DC magnetron sputteringsystem. A Ni0.45-Cr0.27-Mn0.13-Y0.16 alloy with a diameter 76.2 mmwas used as targets. The DC power was ï¬ÂÂxed at 50 W. The sput-tering chamber was evacuated to a background pressure of 5 ×10-7torr using a cryo-pump. Sputtering was performed using argon gaswith a purity of 99.999% at flow of 60 sccm using mass flow con-trollers at a working pressure of 3 ×10-3torr for gas introductioninto the chamber. 2.2. Ni-Cr-Mn-Y-Nb thin ï¬ÂÂlmThe niobium target was made from Nb powders, which ishelpful to improved TCR and stabled ï¬ÂÂlm structure. Ni-Cr-Mn-Y-Nb thin ï¬ÂÂlms 80 nm in thickness were deposited onto the substratesusing a DC and RF magnetron co-sputtering system. A Ni0.45-Cr0.27-Mn0.13-Y0.16 alloy and niobium with a diameter 76.2 mm were usedas targets. The Ni-Cr-Mn-Y alloy target was set at the DC position.The niobium target with a diameter 76.2 mm was set at the RFposition. To obtain different niobium contents in the Ni-Cr-Mn-Yï¬ÂÂlm, the DC power was ï¬ÂÂxed at 50 W and the RF power waschanged from 20 W to 120 W. The sputtering chamber was evac-uated to a background pressure of 5 ×10-7torr using a cryo-pump.Sputtering argon gas with a purity of 99.999% at flow of 60 sccmwas performed using mass flow controllers with a working pres-sure of 3 *10-3torr. 2.3. Analysis Thin ï¬ÂÂlms deposited onto glass plates at room temperature weresubjected to transmission electron microscopy (TEM) and X-raydiffraction (XRD) studies, Thin ï¬ÂÂlms deposited onto Al2O3sub-strates (size: 400 mm2) were used to measure the electrical prop-erties. The substrate temperature was 25oC. The as-deposited ï¬ÂÂlmswere annealed at 250-400oC for 2 h, at a heating rate of 5oC/minin air.The sheet resistance Rsof the ï¬ÂÂlms was measured using thefour-point probe technique. The thickness tof the ï¬ÂÂlms wasmeasured using FE-SEM (cross-section). The resistivity measuredusing the four-probe method was consistent with the resistivityobtained by the Rsand tsamples. The TCR values of the thin ï¬ÂÂlmswere measured using thin long strips cleaved from the substrate.Electrical contacts at the two ends of the resistive strips were ob-tained by selectively coating the ends with sputtered silver. The DCresistance of the strips was measured using a digital multimeter(HP 34401A) at different temperatures (25oC and 125oC). The TCRof the thin ï¬ÂÂlms was measured using the following equation TCR ¼[(DR/DT) 1/R] *106ppm/K Conclusion: This study investigated thin ï¬ÂÂlms fabricated for the purpose ofpreparing high resistivity with low-TCR thin ï¬ÂÂlm resistors. Thedependencies of the Ni-Cr-Mn-Y-Nb thin ï¬ÂÂlm electrical propertieson the annealing temperatures and the ï¬ÂÂlm compositions were alsoinvestigated. Our conclusions are summarized as follows:A Ni-Cr-Mn-Y resistive thin ï¬ÂÂlm was prepared using DCmagnetron sputtering from Ni0.45-Cr0.27-Mn0.13-Y0.16cast alloy tar-gets. When the annealing temperature was set to 400oC, Ni-Cr-Mn-Yï¬ÂÂlms with some amounts of Ni17Y12nanocrystalline phases wereobserved. The Ni-Cr-Mn-Y ï¬ÂÂlm annealed at 300oC presented anamorphous structure using TEM analysis. The Ni-Cr-Mn-Y ï¬ÂÂlmsannealed at 300oC exhibited the smallest temperature coefï¬ÂÂcientof resistance (þ30 ppm/oC) with a resistivity of ~480mU-cm.A Ni-Cr-Mn-Y-Nb resistive thin ï¬ÂÂlm was prepared using DC andRF magnetron co-sputtering from Ni0.45-Cr0.27-Mn0.13-Y0.16 castalloy and niobium targets. All of the Ni-Cr-Mn-Y-Nb ï¬ÂÂlms annealedat O400OC exhibited an amorphous structure, except for speci-mens with 0% and 6.3% Nb addition at 400oC. Ni-Cr-Mn-Y ï¬ÂÂlmswith 6.3 at.% Nb annealed at 400oC presented amount of Ni17Y12crystalline phase. Amorphous structures were obtained for Ni-Cr-Mn-Y ï¬ÂÂlms with higher Nb content (14 at.%), which is attributedto the high entropy alloy effect. The TCR values gradually shiftedfrom positive to negative with increasing in niobium content. Asthe annealing temperature was increased, the TCR shifted fromnegative to close to zero. This shift is attributed to the crystallineand oxidation. The TCR of Ni-Cr-Mn-Y-Nb thin ï¬ÂÂlms could beadjusted to close to zero using the annealing process and adding Nbcontent. The oxidation layer thickness in the ï¬ÂÂlms was increasedsigniï¬ÂÂcantly from 8 nm at 14 at.% Nb to 11 nm at 31.6 at.% Nb. Thisresult indicates that the ï¬ÂÂlm surface oxidation becomes thickerwith more added Nb. The electrical properties indicated that Ni-Cr-Mn-Y ï¬ÂÂlms with 14% Nb addition annealed at 300oC exhibited thesmallest temperature coefï¬ÂÂcient of resistance (þ5 ppm/oC) with aresistivity of ~585mU-cm. For practical purposes, it is importantthat ï¬ÂÂlms with a small TCR possess high resistivity This work is partly presented at 19th Nano Congress for Next Generation August 31-01, 2017 Brussels, Belgium