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26 M.M. Abdelrahman Study of Ion Beam Sputtering using a Glow Discharge Ion Source M.M. Abdelrahman Accelerators & Ion Sources Department, Nuclear Research Center, Atomic Energy Authority, P.O. Box: 13759 Inchas, Cairo, Egypt. (Received on 25 July, 2009) In this work, sputtering yield in a glow discharge ion source system has been determined using the operating parameters of the ion source. The sputtering yield is found to be varied between 0.4 to 1 atoms removed per incident ion for nitrogen while for argon between 0.2 to 1.3 atoms removed per incident ion. The feature of this ion source is high output ion beam current and small size. Operation of the ion source is quite simple since a stable discharge can be obtained within a large range of main parameters such as, discharge voltage, discharge current and gas pressure. Also, beam profile for argon ion beam produced from the glow discharge ion source at Id = 2, 3 mA (discharge current) using argon gas with different gas pressures has been investigated. Keywords: Glow discharge ion source, sputtering yield, argon gas pressure, plasma production. INTRODUCTION Sputtering is a process whereby atoms are ejected from a solid target material due to bombardment of the target by energetic ions. It is commonly used for thin-film deposition, etching and analytical techniques. Physical sputtering is driven by momentum exchange between the ions and atoms in the material, due to collisions [1]. The average number of atoms ejected from the target per incident ion is called the sputter yield and depends on the ion incident angle, the energy of the ion, the masses of the ion and target atoms, and the surface binding energy of atoms in the target. The incident ions set off collision cascades in the target, when such cascades recoil and reach the target surface with an energy above the surface binding energy, an atom can be ejected. When a target is bombarded with fast heavy particles, erosion of the target material occurs: this is termed sputtering [2-7]. The glow discharge in sputtering is significantly dependent on the work function of the target material and pressure of the environmental gas [8]. Sputtered atoms ejected into the gas phase are not in their thermodynamic equilibrium state, and tend to deposit on all surfaces in the vacuum chamber. A substrate (such as a wafer) placed in the chamber will be coated with a thin film. Sputtering usually uses argon plasma. In the present work, we have studied the profile of the argon beam produced from the glow discharge ion source and determined the sputtering yield with the aid of the different operational parameters using argon and nitrogen gases at the same gas pressure. cm from the ion-exit aperture of the cathode and used to measure the output ion beam current. The working gas is admitted to the ion source through a hose fixed in a Perspex flange at the upper side of the anode. A 10 kV power supply is used for initiating the discharge (glow discharge) between the anode and the cathode. FIG. 1: Schematic diagram of the ion source and its associated electrical circuit [9]. EXPERIMENTAL SETUP A schematic diagram of the glow discharge ion source and its associated electrical circuit is shown in Fig. 1. This glow discharge ion source has been described before [9]. It consists of aluminium Pierce shape anode with small aperture to confine the discharge and aluminium plane cathode. The anode has an internal diameter of 28 mm at the upper side and 10 mm diameter at the lower side and its length 17 mm. The aluminium cathode has an aperture of diameter 1.5 mm and length 5 mm. Both the Pierce anode and the plane cathode are immersed in an insulator of Perspex material. The collector (Faraday cup) is situated at a distance of 5 A complete vacuum system is used to evacuate the ion source chamber. It consists of stainless steel silicon oil diffusion pump provided with electrical heater and backed by rotary fore vacuum pump. The rotary pump is used to evacuate the system with ultimate pressure of 10−2 to 10−3 mmHg, while the silicon oil diffusion pump is used to yield very low pressure in the ion source vacuum chamber of the order of 10−5 mmHg. The silicon diffusion pump is surrounded by water tubes for cooling during the operation. A liquid nitrogen trap is fixed between the ion source chamber and the silicon oil diffusion pump in order to prevent the silicon vapour from entering the ion source chamber. The working gas is 27 Brazilian Journal of Physics, vol. 40, no. 1, March, 2010 transmitted to the ion source from a gas cylinder through a needle valve to regulate the rate of gas flow. 240 chamber. The working gas is transmitted to the ion source from a gas cylinder through a needle valve1 -4 1 P = 4.0 x 10 mmHg to regulate the rate of gas flow. 210 EXPERIMENTAL RESULTS EXPERIMENTAL RESULTS 180 -4 2 P = 5.3 x 10 mmHg -4 3 P = 6.8 x 10 mmHg 2 3 Ib (P A) In this work, the distance between the anode and the cathode, dA−K is fixed at the optimum value [9] for stable discharge current high output ion beam current.the The dis- and the cathode, 150 In and this work, the distance between anode dA-K is fixed at the optimum value charge characteristics of the glow discharge ion source such as, discharge voltage, discharge currentand andhigh output ion beam discharge current output ion beam current. The discharge characteristics of the glow [9] for stable 120 current are investigated using nitrogen and argon gases. Also discharge ion source such as, discharge voltage, discharge current and output ion beam current are investigated the sputtering yield is determined using the experimental resultsusing for nitrogen and argon gases on stainless material nitrogen and argon gases. Also thesteel sputtering yield has been90determined using the experimental results (target). for nitrogen and argon gases on Stainless steel material (target). 60 1- Ion Source Properties 1- Ion Source Properties 30 Ib (mA) Id (mA) Figure 2 shows the relation between the discharge cur2 showsvoltage, the relation current, Id, and the discharge voltage, Vd, at different rent, Id , and Figure the discharge Vd , atbetween differentthe gasdischarge pressures, using nitrogen gas.nitrogen It is clear increase of increase of 0the discharge voltage was accompanied It isan clear that an gasP,pressures, P, using gas. that 0 0.4 0.8 1.2 1.6 2 the discharge voltage was accompanied by an increase of the by ancurrent, increase of the current, voltage; where atthe the same discharge voltage; the discharge current is higher discharge where at discharge the same discharge Id (mA) discharge current is higher at high pressure than that at low at high pressure thanthe thatrelation at lowbetween pressure.the Figure shows the relation between the output ion beam current, pressure. Figure 3 shows output3 ion FIG. 3: Output ion beam current versus discharge current at differbeamIb,current, and the discharge Id , at different niand theIb ,discharge current,current, Id, at different gas pressures, P, using nitrogen gas. It is obvious that, when the ent pressures using nitrogen gas. trogen gas pressures, P. It is obvious that, when the discharge discharge current increases, the output beam and current increases and high output ion beam current was current increases, the output ion beam current ion increases highobtained output ion beam current was obtained at low pressures at low pressures than that at high pressures. was accompanied by an increase of the discharge current, than that at high pressures. where at the same discharge voltage; the discharge current is higher at high pressure than that at low pressure. 240 2.2 Figure 5 shows the -4 -4 relation between the output ion beam 1 P = 4.0 x 10 mmHg 1 P = 4.0 x 10 mmHg 1 -4 -4 discharge current, I , at different gas current, I , and the b d mmHg 2 P = 5.3 x 10 mmHg 2 P = 5.3 x 10 2 210 -4 -4 3 P = 6.8 x 10 mmHg 3 PP,= 6.8 x 10argon mmHg 3 2 1 pressures, using gas. It is obvious that, when the 1.8 discharge current increases, the output 2ion beam current in180 creases and high output ion beam current was obtained at low 1.6 pressures than that at high pressures. 3 150 Fig. 6 shows beam profile for argon ion beam produced 1.4 from the glow discharge ion source at Id = 2 mA using ar1.2 120 gas. It is clear that the maximum value of the output gon ion beam is obtained at the center of the target at pressure 1 −4 mmHg and it decreases by increasing the equal 90 to 8 × 10 0.8 pressure. Fig. 7 shows beam profile for argon ion beam produced 60 0.6 from the glow discharge ion source at Id = 3 mA using argon gas. It is clear that the curves have the same behaviour 0.4 30 as shown in Fig. 6 but the maximum value of the output ion 0.2 beam increases by increasing the discharge current. Figs 6 and0 7 show the beam profile for argon gas at low voltage 0 0 0.8 1.2 1.6 2 (1.8 kV, 2.050.4 kV, respectively) and high pressure (1.1 ×10−3 0 1 2 3 4 5 −4 mmHg and 9 ×10 ImmHg, d (mA) respectively). It is clear that Vd (KV) , the beam profile is uniform distribution which is required in many field of industrial applications as, cleaning of the Fig.2: Discharge current versus discharge Fig.3: Output ion beam current versus materials, sputtering etc..(Broad Beam Surface). Figs 6 and FIG. 2: Discharge current versus discharge voltage at different presvoltage at different pressures using discharge current at different sures using nitrogen gas. 7 show beam profile at high voltage (3 kV and 3.5 kV, renitrogen gas. pressures using nitrogen gas. spectively) and low pressure (8 ×10−4 mmHg). It was found that, a peak appeared which is suitable for a thin focused ion Figure 4 shows the relation between the discharge current, beam and is required for ion beam applications of a narrow Id , and the discharge voltage, Vd , at different argon gas presarea surface. The increase of the extraction voltage (accelersures P. It is clear that an increase of the discharge voltage 28 M.M. Abdelrahman 1807 1.8 -4 at I = 2 mA, V = 3 kV, P = 8x10 mmHg d -4 1.6 3 1.4 1405 1.2 120 1 clear that an increase of the discharge voltage was accompanied 0.8 nt, where at the same discharge voltage; the discharge current is higher Ib (µ A) Id (mA) een the discharge current, Id, and the discharge voltage, Vd, at different d 4 1 at I = 2 mA, V = 2.05 kV, d d 2 -4 P = 9x10 mmHg 3 r 100 2 80 at I = 2 mA, V = 1.8 kV, 1 . r -4 1 P = 4.0 x 10 mmHg -4 2 P = 5.3 x 10 mmHg -4 3 P = 6.8 x 10 mmHg 1606 1 2 Ion beam current (arbitrary unit) 1 P = 4.0 x 10 mmHg -4 2 P = 5.3 x 10 mmHg -4 3 P = 6.8 x 10 mmHg 0.6 d 60 3 d -3 P = 1.1x10 mmHg r 0 -0.8 0.4 40 een the output ion beam current, Ib , and the discharge current, Id , -0.6 -0.4 -0.2 0 0.2 0.4 0.6 0.8 Distance (mm) 0.2 20 n gas. It is obvious that, when the discharge current increases, the FIG. 6: Beam profile for argon ion beam produced from the ion 0 gh output ion beam source 0at Id = 2 mA. 0 1 current was 2 3 obtained at low 4 5 pressures than 6that at 0 10 Vd (KV) 5 voltage at different pressures using argon gas. -4 at I160 d = d r 8 Fig.5: Output ion beam current versus discharge current at different 6 pressures gas. at I using = 3 mA, argon V = 2.45 kV, d d -4 P = 9x10 mmHg 4 r Fig.6 shows beam profile for argon ion beam produced from the glow discharge ion source 180 1 1.2 1.4 1.6 1.8 Id kV, (mA) at I = 3 mA, V = 3.5 P = 8x10 mmHg d Ion beam current (arbitrary unit) FIG. 4: Discharge current versus discharge voltage at different pressures using argon gas. Fig.4: Discharge current versus discharge 1 -4 at nitrogen is more easily to ionize than argon, where nitrogen has two . 0.2 0.4 0.6 0.8 1 P = 4.0 x 10 mmHg -4 2 P = 5.3 x 10 mmHg -4 3 P = 6.8 x 10 mmHg 2 2 mA using argon gas. It is clear that the maximum value of the output ion beam is obtained at at I = 3 mA, v = 2.05 kV, 1 d d the140 center of the target at pressure equal to 8 x 10-4 mbar0and it decreases by increasing the pressure. P = 1.1x10 mmHg -3 r -0.8 -0.6 -0.4 120 Ib (µ A) 0 0.2 0.4 0.6 0.8 Distance (mm) 2 100 -0.2 FIG. 7: Beam profile for argon ion beam produced from the ion source at Id = 3 mA. 80 3 60 2 -Determination of the Sputtering Yield 40 The rate of sputtering process can be calculated from simple considerations of the volume removed per atom. In particular, the thickness removed per second by ion beam sputtering given by the expression [11]: 20 0 6 charge es using 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 Id (mA) FIG. 5: Output ion beam current versus discharge current at differFig.5: Output ent pressures using argon gas. ion beam current versus discharge current at different pressures using argon gas. or argon ion beam produced from glow discharge ion source ation voltage) decreases the the width of the ion beam [10]. ear that the maximum value of the output ion beam is obtained at ual to 8 x 10-4 mbar and it decreases by increasing the pressure. δ = 1.66 × 10−24 . MS Ji . ρ e (1) where M is the atomic mass of the target atoms, ρ is the density of the sputtered material, e is the charge of the electron, ji is the ion beam current density at the target and S is the sputtering yield (atoms removed per incident ion) given by the relation: S= M1 lnW 1 M2 W cos θ (2) 29 Brazilian Journal of Physics, vol. 40, no. 1, March, 2010 where M1 is the mass of the incident ion, M2 is the mass of the target particle and W is the energy of the incident ion and θ is the angle between the incident beam and the target. By substituting eq. 2 in eq. 1, and using the experimental results, the rate of sputtering can be calculated, where in our case θ = 0, so cos θ = 1. Figs. 8 and 9 show the relation between the current density, J, in A/cm2 and the rate of sputtering, δ, in µm/min. at constant pressure, P = 4 × 0−4 mmHg, using pure nitrogen and argon gases. It is clear that at the same current density, the rate of sputtering in case of argon gas is higher than that for nitrogen gas at the same pressure. 1.1 rate of sputtering. N gas, 2 rate of sputtering, µmeter/minutes 1 -4 gas Pressure = 4x10 mmHg 0.9 0.8 0.7 0.6 0.5 0.4 0.3 5 10 15 20 25 30 35 40 45 2 J (A/cm ) FIG. 8: Relation between the current density, J ,in A/cm2 and the rate of sputtering, δ, in µm/min. at p = 4×10−4 mmHg for nitrogen gas on stainless steel material (target). CONCLUSION rate of sputtering, µmeter/minutes 1.4 1.2 Rate of sputtering, argon gas, gas pressure = 4x10-4 mmHg 1 0.8 0.6 0.4 0.2 0 5 10 15 20 25 30 2 J (A/cm ) FIG. 9: Relation between the current density, J ,in A/cm2 and the rate of sputtering, δ, in µm/min. at p = 4 × 10 − 4 mmHg for argon gas on stainless steel material (target). [1] R.Behrisch and W.Eckstein; Sputtering by Particle bombardment: Experiments and Computer Calculations from Threshold to Mev Energies. Springer, Berlin (eds.) (2007). [2] F. Aumayr and HP. Winter, Phil. Trans. R. Soc. Lond. A 362, 77–102 (2004). [3] J. F. Ziegler, J. Appl. Phys, 85, 1249-1272 (1999). [4] H. Gnaser, Low-Energy Ion Irradiation of Solid Surfaces, Springer- Verlag Berlin Heidelberg, Germany, 1999. [5] Tatsuya Banno et al, Vacuum, 80, 667–670 (2006). [6] S.Han et al, Vacuum, 78, 539–543 (2005). [7] L. He et al, Nanotechnology, 19, 445610 (2008). In this study, sputtering yield in a glow gas discharge ion source system has been determined using the operating parameters of this ion source. The main features of this ion source are high output ion beam current and small size. Operation of this ion source is quite simple since a stable discharge can be obtained within a large range of main parameters such as, discharge voltage, discharge current and gas pressure. The sputtering yield is found to be varied between 0.4 to 1 atoms removed per incident ion for nitrogen while for argon between 0.2 to 1.3 atoms removed per incident ion. Also, beam profile for argon ion beam produced from the glow discharge ion source at Id = 2, 3 mA (discharge current) using argon gas with different gas pressures has been investigated. Indeed, it is found also that, at the same current density, the rate of sputtering in case of argon gas is higher than that for pure nitrogen gas. This ion source can be used for etching, sputtering and micro-machining applications. [8] K. Hine et al, The Second International Symposium on Atomic Technology IOP Publishing, Journal of Physics: Conference Series 106,012019 (2008). [9] M.M.Abdel Rahman, A.G.Helal, O.A.Mostafa and F.W.Abdel Salam,, Journal of Nuclear and Radiation Physics, Vol. 3, No. 1, (2008). [10] S.G. Zakhary, Rev. Sci. Instrum. 66, 12, December (1996). [11] H.L.Garvin, Paper presented at KODAK Microelectronics Seminar, San Diego, Calefornia, Dec.11-12 (1972).