Ellipsometric study of passive and anodic oxide films formed on Ti and Nb electrodes


doi:10.5599/jese.245  221 

J. Electrochem. Sci. Eng. 5(4) (2015) 221-230; doi: 10.5599/jese.245 

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 

Original scientific paper 

Ellipsometric study of passive and anodic oxide films formed on 
Ti and Nb electrodes 

Ljubomir Arsov, Irena Mickova  

Faculty of Technology and Metallurgy, University Ss. Cyril and Methodius, Rudjer Boskovic 16,  
1000 Skopje, Republic of Macedonia 

Corresponding Author: arsov@tmf.ukim.edu.mk; Tel. +389 2 3088 43; Fax: + 389 2 3 065 389 

Received: October 20, 2015; Accepted: November 26, 2015 
 

Abstract 
Electrochemical formation of passive films and active/passive transition on Ti and Nb 
metal surfaces in various concentrations of H2SO4 and KOH solutions was investigated 
using potentiostatic and cyclic voltammetry methods. By simultaneous electrochemical 
and in-situ ellipsometric measurements the coefficients of film thickness growth of 
passive films in the potential region from -1.5 V to 4 V were determined. Results indicate 
the strong influence of the concentration and electrolyte nature to the active/passive 
transitions and stability of passive films. The influence of cathodic pre-treatment on the 
passive films dissolution and appearance of the reactivation peaks during the reverse 
potential cycling were shown. By multiple cycle sequences in which the final anodic 
potential was gradually enlarged, the barrier properties of passive films on investigated 
electrodes were confirmed. The electrochemical and ellipsometric data showed that the 
passive films formed on Nb electrode are more resistant that passive films formed on Ti 
electrode, especially in higher concentrations of investigated aggressive solutions. 

Keywords 
Potentiostatic method, Cyclic voltammetry, Film thickness growth, Stability and reactivation of 
passive films 

 

Introduction 

Over the past 50 years there has been a growing interest for the use of titanium and niobium, 

as well as theirs alloys, in various branches of the chemical and mechanical industry as 

construction materials, specifically in transport and stocking of aggressive fluids. They have been  

also used in electro-synthesis, solar energy conversion bio-medical and air-space applications. 

Research on the electrochemical behavior of Ti and Nb have covered the wide range of topics as 

http://www.jese-online.org/
mailto:arsov@tmf.ukim.edu.mk


J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 PASSIVE AND ANODIC OXIDE FILMS ON Ti & Nb 

222  

active-passive transition [1-2], formation of anodic oxide films [3-4], structure and chemical 

composition, breakdown processes [5-6], semi-conducting and optical properties [7-8] etc. 

Titanium and niobium belong to the group of valve metals because they develop spontaneously 

the stable passivating layers either when contacting air and/or water solutions. These layers in 

reality are natural oxide films, which are always present on Ti and Nb surfaces and explain their 

high corrosion resistance. In order to increase the corrosion resistance of Ti and Nb, the natural 

oxide films can be controllably thickened by anodic oxidation in appropriate electrolytes or by 

thermal oxidation in atmospheric conditions [9,10]. The anodic oxide film formation on Ti and Nb 

electrodes have been studies in some acid and alkaline electrolytes, using ellipsometry and other 

electrochemical and optical techniques, but generally for potentials/voltages higher than the 

trans-passive region [11,12]. Although the studies of metal passivity exist for almost 200 years, in 

literature data can be found very rarely the use of elliposmetric methods for determining the film 

thickness only in passive region during the cyclic voltammetry CV measurements. A few 

information’s can be found in ref. [13] about the formation of passive films on Ti electrode in 0.1 

M H2SO4 depending of sweep rate and in one of our recent papers concerning the thickness 

growth and dissolution of electrochemical passive film on Nb in 10 M KOH [14].  

The purpose of present investigations is to study the active passive transition of Ti and Nb 

electrodes, simultaneously with in-situ ellipsometric measurements. In that way is expected to get 

valuable results about the film thickness growth for each applied potential during the 

potentiostatic and CV scans measurements in forward and reverse potential directions. The 

comparative studies of Ti and Nb in acidic and alkaline solutions are carried out.       

Experimental  

Electrodes. Massive cylindrical Ti and Nb rods (Alfa Aesar, Johnson Matthey Company), with 

purity 99.95 % and 99.8 % respectively and with 12.7 mm dia., were cut in disc species with length 

of 10 mm which were served as the working electrodes. On one basis of the disc a shout cooper 

wire was employed as the electrical contact. The discs were fitted into glass tubing of appropriate 

internal diameters by an epoxy resin (Struers), leaving the other basis with surface area of 1.27 

cm
2
 to contact the solution. Before each experiment the electrode surfaces were mechanically 

polished using metallographic emery paper 600 and then electro-polished to the mirror brightness 

in the baths: (i) for Ti electrodes containing: 60 ml perchloric acid + 540 ml methyl alcohol + 350 ml 

ethylene glycol mono butyl ether. The electro polishing conditions are given in ref. [15], (ii) for Nb 

electrodes containing: 170 ml nitric acid + 50 ml. hydro fluoric acid + 510 ml methyl alcohol + 5 g 

citric acid at voltage of 15.2 V. After electro-polishing the electrodes were rinsed with re-distilled 

water, ultrasonically cleaned in ethanol and finally dried using argon gas under pressure.  

The counter electrode was a Pt grid with large surface area. The reference electrode was a 

saturated calomel electrode (SCE) in acidic aqueous solutions and mercury oxide electrode in 

alkaline aqueous solution. The potentials in this work are presented against using reference 

electrode. To avoid contamination, the reference electrodes were connected to the working 

electrode through the bridges with a Luggin capillary filled with the test solutions. After each 

experiment the working electrodes were mechanically re-polished and prepared for the next 

measurements using the procedures of electro-polishing as described above. 

Optical Electrolytic cell. A three compartment optical electrolytic cell with an inlet and outlet for 

bubbling inert gas was adopted for electrochemical and ellipsometric in-situ measurements. 

Experiments were done in a Pyrex vessel with two optical quartz widows fixed at an angle of 70
O
. 



Lj. Arsov at al. J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 

doi:10.5599/jese.245 223 

The specimen surfaces were mounted vertically, with a rigid clamping system having adjustments 

for rotation, tilt and central positioning in the cell. Details of the design of this optical electrolytic 

cell are given elsewhere [16]. Prior to each experiment, when the electrode was immersed in the 

electrolyte solution, the electrolyte in the cell was de-aerated by flowing argon gas through a 

fritted bubbler for at least 30 min. before the run. The gas flow was disconnected during the run. 

Solutions. Aqueous solutions Merck p.a. with concentrations of 1 M H2SO4, 3 M H2SO4, 1 M KOH 

and 6 M KOH was prepared in re-distilled and de-ionized water. After each experiment the 

electrolyte in the cell was exchanged in order to avoid eventual build-up of soluble Ti or Nb 

species.  

Apparatus. The electrochemical measurements were carried out potentiostatically and 

potentio-dynamically using HEKA model 488 potentiostat/galvanostat connected to a personal 

computer.  

The ellipsometric measurements were performed with a Rudolph Research type 43603-200 

thin-film ellipsometer at a wavelength of 546.1 nm and an incident angle of 70
O 

Results and discussion 

Electrochemical passivity of Ti and Nb has been mainly studied using galvanostatic, potentio-

static, potentiodynamic and EIS techniques [17-20]. In this paper we used potentiostatic and 

potentiodynamic methods combined with ellipsometry. Ellipsometry, also known as reflection 

polarimetry, is a very precise method for determining the optical constants, thickness and nature 

of reflecting surface, especially the metal surfaces with and without existence the thin films on 

them. This method derives its name from the measurements of the elliptically polarized light 

results from optical reflection from the investigate surface [21]. Hence, ellipsometry finds 

applicability in a wide variety of fields such as physical, chemical and micro-electronic engineering, 

corrosion, electrochemical and chemical formation of passive layers on metals, oxides, polymer  

films semiconductors, biology, medicine etc. The main strength of this technique lies in its 

capability to allow in-situ measurements and simultaneous determination of many optical 

parameters necessary to quantify the investigated system. The new generation of ellipsometers 

allows determination the film thicknesses of from 0.1 nm to 30 m.   

In ellipsometric measurements the experimentally measured parameters Δ  and ψ  are related 

to the physical properties of the system by the use of Fresnel’s equation 

/ tg exp( Δ)p sr r i      (1) 

In Eq. 1, tg  represents relative amplitude attenuation, Δ  is relative phase change, i is 

imaginary number, rp and rs represent the Fresnel reflection coefficients for electromagnetic wave 

polarized parallel and perpendicular to the plane of incidence, respectively. For a three 

component system, the ellipsometric parameters Δ  and  are complex function of the following 

parameters. 

m f stg exp( Δ)  (n ,  n ,  n , ,  ,  )i d  
  

    (2) 

In Eq. 2, 


mn  is complex refractive index of medium,


fn - complex index of film, 


sn  - complex 

index of metal substrate, d - film thickness, - wavelength of incidence electromagnetic wave and  

- angle of incidence. To minimize the unknown parameters in Fresnel’s equation the refractive 

index of medium (electrolytic solutions) could be determine with Abbe’s refractometer, refractive 

index of metal substrate by some separate methods, for example elipsometrical measurements in 



J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 PASSIVE AND ANODIC OXIDE FILMS ON Ti & Nb 

224  

vacuum of evaporated metal on microscope glasses. The other parameters as: wavelength , was 

given in dependence of used laser and angle of incidence was adjusted to the ellipsometer. By 

method of mathematical iteration, using computer program, the film thickness and complex index 

of refraction are determined. In our case the experimentally measured parameters Δ  and   are 

fitted with theoretically calculated curves for Δ  and  for increasing direction of film thickness for 

in advance given step of film growth. 

Passive film on titanium electrode 

After electropolishing, the Ti electrodes were immersed in H2SO4 solutions with various 

concentrations and open circuit potential, OCP, was recorded during the establishment of steady 

state potential, i.e. when the variations of potentials with time are negligible. The potentiostatic 

measurements were initiated from steady state potential with successive increasing the potential 

on the same electrode up to begin the evolution of oxygen in trans-passive region. Then, on the 

same electrode the potential was also successively changed in the reverse, cathodic direction up 

to value of starting potential. The variation of currents with time during establishment of steady 

state conditions were recorded for each successive change of potential. The steady state currents 

were then taken in construction of potentiostatic curves. Fig. 1 (a) illustrates the profile of one 

typical potentiostaic curve in the potential region from 0.75 to 3.5 V. In the first forward scan an 

active dissolution region exists and the anodic current increases exponentially with potential up to 

point a, where the anodic current peak is formed. In this region two processes take place: metal 

dissolution and in the same time growth of anodic oxide film. However, the metal dissolution is 

prevalent process. In the second region the anodic current decreases toward a low value 

corresponding to the beginning of the passivation. The passive film formation and its growth with 

imposed potential are followed with long current plateau whose values are near to zero. The third 

region corresponds to trans-passive region, point c, where anodic current begin again to increase. 

In the first forward scan simultaneously with potentiostatic current-voltage, the ellipsometric 

measurements were also performed during imposed potentials. From ellipsometrically measured 

parameters  and  the film thicknesses were calculated, presented in fig. 1 (b). For calculation 

the film thicknesses the input data in equation (1) and (2) were: for 3M H2SO4  


mn  = 1.364, for 

virgin Ti substrate 


sn = 2.94(1-1.217 i), for wavelength of incident light  = 546.1 nm and for angle 

of incidence  = 70
O
, whereas the unknown values of 


fn and d were calculated by fitting the 

theoretical data to the experimentally measure ones. The fitting procedure was performed by a 

special prepared computer program in which 


fn was searched for prior given values of the 

thicknesses in increments’ of 1 nm, in an increasing direction. The number of theoretical  -  

points on the theoretical fitted curves depend of the thickness increments’ given from our side. 

Taking into account that our ellipsomteric measurements were performed in one relatively short 

potential region where the final film thickness at the end of the passive region is relatively low, the 

large dispersion of experimental points from the theoretically fitted curves is expected. During the 

computation only one theoretical function T = f(- T) was searched from the family of 

theoretical functions which had minimal distance to the experimental measured points  - In 

determination the thicknesses of passive films the theoretical values of ( - T) were taken in 

consideration whereas experimental dispersion of measure points ( - ) were neglec- 

ted. Details of computer program and fitting procedure are given in ref. [22]. 
 



Lj. Arsov at al. J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 

doi:10.5599/jese.245 225 

a 
 1 

 2 

-50 

0 

50 

100 

150 

200 

-1 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 4 
E / V vs. SCE 

I 
/ 


A
 

a 

b 
c 

 
b 

 

 

0 

2 

4 

6 

8 

10 

12 

14 

-1 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 4 
E / V vs. SCE 

d
 /

n
m

 

 
Fig. 1. (a) Potentiostatic I – E curve obtained on electropolished Ti surface in 3 M H2SO4,  

(b) Simultaneous determination the thickness of passive film by ellipsometry  

As it can see from fig. 1 (b) in the forward cycle the film thickness increases almost linearly and 

there is no noticeable dispersion of points which present growth of film thickness. From the slope 

of forward curve the coefficient of film thickness growth is determined, i.e.  = 2.51 nm/V. In the 

reverse potential scan, with decrease of imposed potential in cathodic direction up to potential of 

-0.25 V, the long current plateau with current values also near to zero are observed. In this 

potential region ellipsometric measurements show that the thickness of the already formed 

passive film has constant value and there is no indication for its dissolution and thinning. At 

potential of -0.25 V begins reactivation process with sharp increase of anodic currents indicating 

electrochemical dissolution of the formed passive film. The reactivation peak already covers the 

activation. In the potential region between -0.25 V and -0.75 V, corresponding to the reactivation 

processes, the passive film was subject of continuously thinning and at the final potential of -0.75 

V the film thickness is minimized and already has the same value as at the starting potential of the 

first forward scan. This indicates that the formed passive film is completely dissolved.             

 



J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 PASSIVE AND ANODIC OXIDE FILMS ON Ti & Nb 

226  

Passive film on niobium electrode 

In the similar way as in case of Ti, the Nb electrode was electropolished and then immersed in 

H2SO4 solutions with various concentrations and the OCP was recorded during the establishment 

of steady state potential. The potentiodynamic measurements were initiated at potential of -0.75 

V where a considerable cathodic current is observed and ended at 1 V (SCE), fig. 2(a)  

a  1 

                      2 
  

-0.9 -0.6 -0.3 0.0 0. 0.6 0.9 1.2 
-2.0 

-1.5 

-1.0 

-0.5 

0.0 

0.5 

1.0 

1.5 

2.0 

I 
/ 
m

A
 

E / V vs. SCE 

1 

2 

 

b 
 1 

 2 

0 
0.5 

1 
1.5 

2 
2.5 

3 
3.5 

4 
4.5 

-0.9 -0.6 -0.3 0 0.3 0.6 0.9 1.2 
E / V vs. SCE 

first cycle 
second cycle 

 d
 /

 n
m

 

 
Fig. 2. (a) Voltammograms of Nb recorded in 10 M H2SO4, 1 – first cycle, 2 – second cycle;  

(b) Simultaneous determination the thickness of passive film by ellipsometry 

In the first forward scan the cathodic current approaches zero value and when it get anodic 

values the process of metal dissolution and in the same time formation of anodic oxide films 

occur, as in case of titanium electrode. The active-passive transition exists in all investigated 

concentrations, but with increasing the concentration of H2SO4 this process is more pronounced. 

During the reverse scan the reactivation processes or reduction of the already formed passive 

films were no recorded, even in high concentration of H2SO4 up to 10 M. This was the main reason 

why our measurements started at more cathodic potential where the noticeable catholic current 

appears in the beginning of the first forward scan and in each other next subsequent scans. It was 

expected that the natural or later formed passive films will be reduced at second scan during the 



Lj. Arsov at al. J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 

doi:10.5599/jese.245 227 

cathodic polarization of electrode. But the passive film formed in first forward scan cannot be 

cathodically reduced in the reverse scan. In the second cycle a constant current close to zero, for 

both, forward and reverse scans were recorded. The voltammograms in the next subsequent scans 

were almost identical to the second one. It is evident that after the first cycle, the Nb electrode 

remained passive over the whole investigated potential region and the formed passive film 

blocked all possible redox reaction at the Nb/passive film/electrolyte interface. Compeering the CV 

curves between Nb and Ti electrode it can conclude that in H2SO4 solution the Nb is corrosion 

more resistant than Ti electrode. During the CV scans simultaneous ellipsometric measurements 

were also performed, as in casa of titanium electrode. From ellipsometric parameters  and  the 

film thicknesses were calculated fig 2 (b). In the beginning of the measurements, when cathodic 

current  pass through  the  electrochemical cell,  small  decrease  of the film thickness is observed, 

probably  due to the partly dissolution of natural oxide film. With apparition of anodic current 

begin growth of anodic oxide film which is linear function up to the final anodic potential of 1 volt. 

From the slope of this linear curve the coefficient of film thickness grow of  = 2.58 nm/V was 

determined. In the first reverse scan the thicknesses of the film have constant values up to the 

starting potential of -0.75 V. In the second and subsequent scans the thickness of the film has 

almost the same constant values, as in the end of first forward and reverse scan. The dispersion of 

the measured points in the second scans could be observed, probably for small dissolutions of the 

passive film and its reparation during the potential scan, or by existing of some side reactions.  

a  

0.2

0.4

0.6

-0.9 -0.6 -0.3 0.0 0.3 0.6 0.9

43

2

1

E / V vs Hg/HgO

I 
/ 

m
A

 
E / V vs. HgHgO 

 

b 

d
 /

 n
m

 

6 

5 

4 

3 

2 

1 

0 
-0.9 -0.6 -0.3 0 0.3 0.6 0.9 

E / V vs. Hg/HgO 

1 

2 

3 

4 

 1 
b 2 

 3 

 4 

 5 

 6 

 7 

 8 

 
Fig. 3. (a) Multiple cycle sequences at increasing final anodic voltage of Nb recorded in 1M KOH; 1, 2, 3, and 

4 represent number of cycle, (b) Simulated film thickness growth in each subsequent cycle 

I 
/ 

m
A

 



J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 PASSIVE AND ANODIC OXIDE FILMS ON Ti & Nb 

228  

Fig. 3 (a) shows sequences of CV measurements where the final anodic potential on Nb in 1 M KOH 

is gradually enlarged in each next cycle. All subsequent presented voltammograms started from 

the same cathodic potential of -0.9 V and also finished to the same catholic potential of -0.9 V. The 

difference in measurements is only to the increasing of final anodic potential.  The progress of film 

thickness growth with anodic potential may take place only if the actual potential exceeds the 

maximum value attained in the previous cycle.  The shapes of the sequences recorded in fig. 3 (a) 

represent just the copy segments of the corresponding voltammogram recorded from the starting 

potential at -0.9 V to final potential at 0.9 V at once, without sequences. The simulated film thick-

ness growth that should be obtained by ellipsometric measurements are presented in fig.3 (b). 

   

 

-15

-10

-5

0

5

10

15

20

-2 -1 0 1 2 3 4

1, 2

E / V  vs Hg/HgO

I 
/ 

m
A

a

d

 
E / V vs. HgHgO 

 
 1 

 2 

-5 

0 

5 

10 

15 

20 

25 

-2 -1 0 1 2 3 4 
E / V vs. Hg/HgO 

a 

b 

c 

d 

d
 /

 n
m

 

 
Fig. 4. (a) Voltammograms of Nb recorded in 6 M KOH, a – initial current at potential of -1.5 V,  

d – final current at potential of -1.5 V,  1 – first cycle, 2 – second cycle;   
(b) Simultaneous determination the thickness of passive film by ellipsometry, a- initial potential,  

b – final anodic potential, c – beginning of reactivation process,  
d – final potential at -1.5 V after the first cycle, d-a –cathodic dissolution at -1.5 V during 15 min  

of the rest film thickness after its partly dissolution in the reverse scan.  

I 
/ 

m
A

 



Lj. Arsov at al. J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 

doi:10.5599/jese.245 229 

For each sequence, film thickness growth in the first forward scan and has constant value in the 

reverse scans. For each next sequence, in the first forward scan the film thickness has constant 

value up to the end of previous cycle and then continues to grow up to the final anodic potential. 

It is evident that by gradually increasing the final anodic potential the passive film grows by 

additional building of the new film on the already existing. The experiments in fig. 3, confirm the 

barrier properties of anodic oxide film build on the Nb surface.  

The voltammograms recorded on Nb at the higher concentration of 6 M KOH are shown in 

Fig. 4 (a). The starting cathodic potential was at -1.5 V and final anodic potential at 4 V. In the first 

forward scan at the initial potential of -1.5 V, point a, a small cathodic current occurs and then in 

the anodic direction active/passive transition is recorded. In the reverse scan, at potential of about 

-0.5 V, begin reactivation process which partly covers the activation region. This suggested that 

with appearance of reactivation peak only part of the formed passive film is dissolved. At the end 

of the first reverse cycle, at cathodic potential of -1.5 V, point d, the noticeable cathodic current 

flows through the electrochemical cell. If we keep for example 15 min. the electrode at this 

potential and then initiate the second cycle, the voltammogram of the second cycle will be 

completely the same as in the first cycle. This indicates that after the first cycle, with keeping of 

some period of time the Nb electrode at -1.5 V, the previously formed passive film in the first cycle 

will be completely dissolved. The simultaneous ellipsometric measurements of the film thickness 

growth, presented in fig. 4 (b), showed continuous increasing of film thickness in the first forward 

scan and constant thickness values in the first reverse scan up to -0.5 V where begin reactivation 

process. In the region of reactivation peak the film thickness partly decrease and did not reaches 

the initial value at -1.5 V, as before starting the CV measurements. During the keeping the 

electrode at potential of -1.5 V, the film dissolution continue and finally it get the same value as in 

the beginning of the first forward scan.  

Conclusions 

From potentiostatic and potentiodynamic measurments of Ti and Nb electrode in H2SO4 and 

KOH solutions, simultaneous with ellipsometric in-situ measurements, the following conclusions 

can be drawn:  (i) Comparative studies of mechanically polished and electropolished metal 

surfaces have shown that the dispersion of experimental points from the theoretically fitted 

curves is smaller for electropolished metal surfaces. It should be noted that during the fine 

mechanical polishing with diamond spray, smooth surfaces with mirror brightness were obtained. 

However, mechanical polishing leaves numerous micro-surface scratches and defects with random 

distributions which cause areas of differing electrical potentials due to surface stress. This is the 

main reason why in this work we used electropolished metal surfaces instead of fine mechanical 

polished. (ii) The potentiostatic and potentiodynamic curves of Ti and Nb recorded in all 

investigation concentrations of H2SO4 and KOH solutions showed active passive transition with 

formation of passive films which are stable in lower concentration of investigated solution.  (iii) For 

all investigated concentration of H2SO4 and KOH solutions, the passive film thickness growth on Ti 

and Nb electrodes are linear function with applied potential, up to final anodic potential in the 

forward scan. (iv) For Ti electrode in 3M H2SO4, the passive films formed in the forward potentials 

were completely dissolved in the reverse potentials, where reactivation process was recorded. (v) 

For Nb, even in 10 M H2SO4, the high stability of the passive films was recorded. In the reverse 

potential scan, no reactivation peak and dissolution of passive films was observed. (vi) In 6 M KOH 

the passive film on Nb electrode was partially dissolved with apparition of the reactivation peak 



J. Electrochem. Sci. Eng. 5(4) (2015) 221-230 PASSIVE AND ANODIC OXIDE FILMS ON Ti & Nb 

230  

whose current intensity is about half intensity of the activation peak. With keeping the electrode 

at potential of -1.5 V the rest of the film was completely dissolved. (vii) Finally it can conclude that 

Nb electrode is more resistance in H2SO4 and KOH solutions than the Ti electrode.          

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