3.1. Microstructural Evolution in Annealed Cu–Zr Bulk Alloys
Figure 1 shows the XRD patterns of as-cast and annealed Cu–Zr bulk alloys. It can be seen from
Figure 1 that the diffraction peaks of the Cu
10Zr
7 (333) and Cu
8Zr
3 (232) compounds can also be observed on the XRD pattern of as-cast alloys, besides the obvious diffraction peaks of Cu (111), which indicate that the Cu
xZr alloy compounds were formed during the melting process of Cu–Zr bulk alloys. Compared with as-cast alloys, the intensity of diffraction peaks of the Cu–Zr bulk alloys annealed at 360 °C increased significantly, indicating that the grain size of the alloys grew gradually during annealing. In addition, weak Zr (222) and ZrO
2 (213) diffraction peaks can also be observed in the XRD spectra of annealed Cu–Zr bulk alloys, which can be attributed to the fact that Cu and Zr are almost insoluble at room temperature, and the supersaturated fine Zr grains dispersed at the Cu grain boundaries. The appearance of ZrO
2 (213) implies that the fine Zr grains on the surface of the alloy easily adsorb oxygen to form ZrO
2 during preparation, annealing, or storage at room temperature.
Figure 2 shows a metallographic of as-cast and annealed Cu-1.1%Zr bulk alloys before corrosion. Compared with
Figure 2a,b, it can be clearly seen that a large number of Cu
xZr alloy compounds, including Cu
10Zr
7 and Cu
8Zr
3, were dispersed at the grain boundaries of Cu grains in the as-cast and Cu–Zr bulk alloys annealed at 360 °C. As shown in the red front of
Figure 2, after annealing at 360 °C, the size of the Cu
xZr alloy compounds increased gradually due to the more active atom diffusion during annealing. The Cu
xZr alloy compounds dispersed at the grain boundaries of Cu grains inhibited the growth of Cu grains to a certain extent during annealing, resulting in little change in the average grain size of Cu grains.
The SEM images of the Cu–Zr bulk alloy are shown in
Figure 2c,d. Cu–Zr alloy compounds grew dispersed in Cu grain boundaries in the (c) as-cast and (d) 360 °C annealed Cu–Zr bulk alloys. The size of Cu–Zr alloy compounds increased slightly after annealing, which is in agreement with the metallographic picture.
3.2. Microstructure in As-deposited and Annealed Cu–Zr Alloy Films
Cu–Zr alloyed thin films with different Zr contents were prepared with thicknesses ranging from 50 nm to 420 nm, and EDS spectra showed that the Zr content ranged from 7.3 to 17.1 at.%.
Figure 3 shows the XRD patterns of the as-deposited and annealed Cu-17.1% Zr alloy films. The XRD pattern of the as-deposited films exhibits a weak diffraction peak, indicating a tiny grain size or amorphous structure in the alloy films [
22]. If the Zr content is further increased, it is possible to form amorphous Cu–Zr alloyed films. No diffraction peaks of elemental Zr and Cu
xZr compounds were observed which is different from those in Cu–Zr bulk alloys, as shown in
Figure 1. The reason is that Cu and Zr are immiscible in the alloyed film at room temperature, and the fine Zr grains dispersed at Cu grain boundaries. However, thermal annealing affects the microstructure in the alloyed thin films greatly, but only Cu diffraction peaks appear in the XRD patterns. The preferential growth of Cu (111) grains is visible, and the XRD intensity of Cu (111) diffraction peak gradually increased with annealing temperature, as a result of increased grain size in the alloyed thin films. The Cu (200) and Cu (220) diffraction peaks became weak when the annealing temperature increased up to 320 °C.
Figure 4a,b shows the TEM results of the as-deposited Cu and Cu-7.3%Zr alloy films of 50 nm thickness. The average grain size in the pure Cu thin films was 50~60 nm with clear grain boundaries, as shown in
Figure 4a. However, the grains in the Cu–Zr alloy thin films were very tiny, only 10~20 nm, as shown in
Figure 4b. This may be due to the large amount of tiny Zr grains dispersed in the copper grain boundaries, which inhibited the growth of Cu grains.
Figure 5 shows the surface morphology of the as-deposited and annealed Cu–Zr alloy films with different Zr contents, as well as the selected area electron diffraction (SAED) patterns of the self-formation faceted particles. The particles of the as-deposited films’ surface were very fine and uniform, as shown in
Figure 5a. In contrast to the flat surface of as-deposited alloy films, a large number of polyhedral particles emerged on the surface of the annealed Cu–Zr films. It should be pointed out that some particles were faceted and regular, as shown in
Figure 5b,c. The EDS results indicate that the composition of the regular particles was pure Cu, as shown in
Figure 5e, which is different from the Cu-rich particles obtained in previous studies [
8]. The average sizes of Cu particles in
Figure 5b,c are 369 and 173 nm, respectively. The results in the present work the earlier studies [
24,
25] demonstrate that the size of Cu particles can be controlled by changing the film’s composition and annealing condition.
The SAED pattern in
Figure 5f shows that the faceted Cu particles formed on the Cu–Zr alloy film were single crystals. As shown in
Figure 5b, some adjacent particles gradually grew into large polycrystalline particles.
Figure 5d shows the high-resolution image of surface morphology in the regions without the self-formed Cu particles in
Figure 5b. The particles in the nearby regions are very fine and uniform, and the size is slightly larger than that of as-deposited alloy films in
Figure 5a.
Comparing
Figure 2 and
Figure 5, it can be clearly seen that Cu–Zr bulk alloy and alloy films exhibited significantly different microstructure evolution behaviors after annealing. Many Cu
xZr alloy compounds dispersed at the grain boundary of Cu grains in annealed Cu–Zr bulk alloys. However, unlike bulks, numerous polyhedral Cu particles of sub-micron were formed on the Cu–Zr thin films’ surface upon thermal annealing. This difference is due to the obvious difference in the microstructure and residual stress state caused by different preparation methods [
15,
19], which leads to different microstructural evolution behaviors between bulk materials and thin film materials during annealing. Cu–Zr bulk materials are stable materials obtained by vacuum melting. During melting and the subsequent pouring process, the Cu and Zr atoms in the high temperature environment are easily diffused to form Cu
xZr alloy compounds, which grow further during annealing. Thin film materials are metastable materials obtained by magnetron sputtering. In the process of thin film deposition, it is difficult for Cu and Zr atoms to diffuse into Cu
xZr alloy compounds in a near room temperature environment. Therefore, no alloy compound was found in XRD phase analysis and SEM surface morphology observation. Kinetically, the relaxation of the compressive residual stress and thermal stress in the Cu–Zr alloy films resulted in the faceted Cu particles forming on the alloy film surface [
24,
25].
3.3. The Main Influencing Factors of Self-formed Cu Particles
Figure 6 shows the surface morphologies of 420 nm thick alloy films with different Zr contents after annealing at 300 °C. As displayed in
Figure 6a, the grains in the Cu films became larger after annealing, and some grains protruded from the surface. It can be seen in
Figure 6b,c that a lot of polyhedral particles appeared on the annealed Cu–Zr films, and they were significantly different from the Al hillocks protruding from the annealed Al films [
11], as well as the Cu grain growth protruding from the annealed Cu films in
Figure 6a. The mean sizes of Cu particles in
Figure 6b,c are 312 and 95 nm, respectively. For the same film thickness and annealing process, the number of particles increases, but the particle size decreases with increasing Zr content. The higher Zr content in the Cu–Zr alloy films can inhibit the diffusion of Cu atoms more obviously and the growth of Cu particles. At the same time, a high Zr content may lead to more triple line junctions appearing near the film surface, which is conducive to the accumulation and nucleation of Cu atoms.
Figure 7 shows the surface morphologies of 225 nm thick Cu-17.1%Zr films after annealing. It can be seen in
Figure 7a,b that both the particle size and the particle number increased with annealing temperature for the same film thickness and composition. The mean sizes of Cu particles in
Figure 7a,b are 99 and 206 nm, respectively.
Figure 8 shows the surface and cross-sectional morphologies of the annealed Cu–Zr film. The formation of a large number of polyhedral pure Cu particles inevitably consumes a lot of Cu atoms surrounding the nucleation sites. As a result, shallow pits emerged on the alloy films, as indicated by the red circle area in
Figure 8a, and they connected with each other, gradually accompanied by the growth of Cu particles. Thus, the film became thinner with the growth of many particles, as confirmed by the cross-sectional SEM image in
Figure 8b. The thickness of Cu–Zr films underneath self-formed Cu particles was thinner than that away from Cu particles, as shown in
Figure 8b. Since the interface was almost in perfect coincidence with the film surface, the surface diffusion of the Cu atoms seems to be the dominant mass transport mechanism of Cu particle growth.
Figure 9 shows the bright-field high resolution transmission electron microscope (HRTEM) images of the interface between the Cu particle and the alloy films. As displayed in
Figure 9a, a large Cu particle grew on the alloy film and was well bonded with the film, with clear boundary. It can be seen from the high-resolution image of the interface that the self-formed Cu particles were coherent with the film (
Figure 9b). This is completely different from the Al hillocks in the pure Al films [
11]. It can be seen from
Figure 8 and
Figure 9 that the Cu particles nucleated and grew on the film surface, while the Al hillock grew inside pure Al film [
11]—the nucleation positions of them were completely different.
Figure 9c shows the bright-field TEM images of a normal grain in Cu film. As compared to
Figure 9c, it can be found from
Figure 9b that the supersaturated Zr in the alloy film resulted in lattice distortion in the alloy films. Thus, the release of distortion energy during annealing is one of the driving forces to form Cu particles.
Figure 10 shows the Auger Electron Spectroscopy (AES) diagrams of the 50 nm Cu-7.3%Zr alloy film before and after annealing. The sputtering area was 2 × 2 mm, and the sputtering rate was about 35 nm/min. For the as-deposited and annealed alloy films, the time required for sputtering down to the film-substrate interface was about 2.75 and 2 min, respectively, that is, the thickness of the alloy film was reduced by 22 nm after annealing. This implies that surface diffusion mainly occurs during the particle growth.
3.4. Residual Stress in Cu–Zr Alloy Films
Figure 11 shows the residual stresses results of annealed Cu films and Cu-7.3%Zr alloy films. The Cu film exhibited a tensile stress, but this was compressive in the Cu-7.3%Zr alloy film. As the annealing temperature increased from room temperature up to 300 °C, the residual stress in the Cu film was reduced from 175 MPa down to 82 MPa. However, the stress in Cu-7.3%Zr alloy film increased from −16 MPa up to −125 MPa after annealing at 300 °C.
It has been suggested [
26] that the formation of metal hillocks is due to thermal-induced stress relaxation. For the Cu–Zr alloy films in this work, Zr atoms or tiny Zr grains distributed at the grain boundary of Cu played a pinning effect and could inhibit grain boundary diffusion. Therefore, residual compressive stress will be released mainly through the formation of particles. Cu particles are preferentially formed at scratches and grooves on films, indicating that residual stress is an important driving force for the formation of particles [
25]. Thermal annealing can activate the release of residual stress in thin films, and it can also induce thermal stress due to the mismatch of thermal expansion coefficients between metal films and soft PI substrates. The thermal expansion (CTE) of the PI substrates was 29.5 × 10
−6 °C
−1, and the CTE of Cu–Zr alloy films (
αf) was evaluated according to the mixture rule, supposing that Cu and Zr atoms were uniformly mixed together in the film:
where
α1 is 6.9 × 10
−6 °C
−1 for CTE of pure Zr,
α2 is 16.5 × 10
−6 °C
–1 for CTE of Cu, and
f is the volume fraction of Zr atoms and can be calculated from the atomic percent of Zr in the film. The elastic modulus of a Cu–Zr alloy
Ef was also evaluated by the mixture rule:
where
E1 is 97 GPa of pure Zr,
E2 is 130 GPa of pure Cu, and
f is the volume fraction of Zr in Cu–Zr film. Furthermore, the thermal stress was calculated according to the Stony Equation (3) [
27]:
where
T0 and
T1 denote the room and annealing temperature, respectively, and
αf and
αs denote the CTE of film and the CTE of substrate, respectively,
Ef is the elastic modulus, and Posson’s ratio ν
f is taken as 0.34 [
28] for the Cu–Zr/PI system.
Figure 12 shows the calculated thermal stress of alloy films annealed at different temperatures. A compressive thermal stress existed in the thin films because the CTE of the PI substrate was larger than that of Cu–Zr films, and the thermal stress was in the range of −397 to −1240 MPa, which was large enough to drive the formation of Cu particles on Cu–Zr film. The thermal stress increased with Zr content, and more particles emerged on the films of higher Zr contents (
Figure 6) and annealed at higher temperatures (
Figure 7).
3.5. Formation Mechanism of Faceted Cu Particles on Cu–Zr Alloy Films
Figure 13 shows a schematic diagram of particle formation. Surface diffusion plays an important role on the growth of Cu particles.
Figure 8 and
Figure 9 display the inhomogeneous film thickness and the perfect interface between Cu particles and film. The particle size decreased with increasing Zr content (
Figure 6). This was probably associated with the distribution of Zr atoms. More and more Zr atoms or tiny particles were segregated at Cu grain boundaries, inhibiting Cu diffusion and the growth of Cu particles. Moreover, lattice distortion increased with Zr content, and interface energy and stress energy were enhanced, which is favorable for the formation of more small particles. Furthermore, particles seemed to form at different times during annealing. As the annealing temperature was elevated, the mean particle size and number increased, because of more active Cu atomic diffusion. Meanwhile, the stress in the alloy film was further relaxed, which also inevitably leads to Cu particle growth and the emergence of new particles.
Many studies were carried out to understand the mechanism of the hillock formation. Grain boundary diffusion [
12], interfacial diffusion [
29], and creep-controlled diffusion [
30] have been proposed to understand the formation mechanism of hillocks. Hwang [
31] and Berla [
32] provided models for hillock growth based on plastic deformation respectively.
Based on the experimental results, it was illustrated that the formation mechanisms of faceted Cu particles on the annealed surface Cu–Zr alloy films surface is significantly different from that of the hillocks observed in Al and Cu films on Si substrates. The Cu particles grow by mass transportation along surfaces and grain boundaries driven by the relaxation of residual compressive stress, distortion energy, and thermal stress [
33]. First, Cu atoms are aggregated to form fine clusters, and then some clusters grow up to be small Cu particles at triple grain boundaries and voids on the Cu–Zr alloy film. The mass transfer during the growth of Cu particles is accomplished by surface diffusion.