International Journal of Engineering Materials and Manufacture (2021) 6(4) 299-304 

https://doi.org/10.26776/ijemm.06.04.2021.05 

 

Anis, S. M. S.
1
 , Ramesh, S.

1,2
, Lee, K. Y. S.

3
 and Wu T.

4
 

1 
Center of Advanced Manufacturing and Material Processing, Department of Mechanical Engineering 

Faculty of Engineering, University of Malaya, 50603 Kuala Lumpur, Malaysia 

2 
Department of Mechanical Engineering, Faculty of Engineering, Universiti Teknologi Brunei 

BE1410 Brunei Darussalam. 

3 
Center of Systematic Innovation Research, Department of Mechanical Engineering,  

Faculty of Engineering and Technology, Tunku Abdul Rahman University College, 53300 Kuala Lumpur, Malaysia. 

4
School of Mechanics, Civil Engineering and Architecture, Northwestern Polytechnical University 

Xi’an 710072, China 

E-mail: syufina.saufi@gmail.com 

 

Reference: Anis et al. (2021). Densification and Mechanical Properties of Alumina Ceramics via Two-Step Sintering with Different 

Holding Times. International Journal of Engineering Materials and Manufacture, 6(4), 209-304. 

 

 

Densification and Mechanical Properties of Alumina Ceramics via Two-Step 

Sintering with Different Holding Times  

 

 

Anis Syufina Hj. Mohammad Saufi, Ramesh Singh, K. Y. Sara Lee and Tao Wu 

 

 

Received: 24 April 2021 

Accepted: 08 July 2021 

Published: 01 October 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

The densification and mechanical properties of alumina ceramics were investigated via two-step sintering (TSS) with 

different holding time. The alumina ceramics were sintered at 1450 °C for 1 min during the first stage, followed by 

sintering at 1350 °C with different holding times (2-24h). Conventional sintering (CS) was also performed on the 

alumina ceramics at 1450 °C for 2 h for comparison purpose. It was found that dense alumina with a relative density 

above 98% could be attained when TSS with a holding time of more than 12 h. The samples exhibited Vickers 

hardness between 5-8 GPa and fracture toughness of about 6 MPa.m
1/2

. In contrast, conventional sintered alumina 

yielded low relative density (85%), large grain size (2 μm), low Vickers hardness (4.23 GPa) and fracture toughness 
(4.73 MPa.m

1/2
). This study revealed that TSS is a viable approach in aiding densification, suppressing grain growth, 

and improving the mechanical properties of alumina ceramics.  

Keywords: Two-step sintering, Alumina, Grain size, Mechanical properties. 

 

1 INTRODUCTION 

Alumina (Al2O3) is one of the widely used engineering ceramics in biomedical and aerospace industries owing to its 

excellent biocompatibility, strength, hardness, and stability in physiological environment [1-2]. However, the sintering 

of alumina using the conventional method at lower temperatures frequently resulted in lower density, fracture 

toughness and flexural strength. As such, various sintering techniques and approaches have been employed to enhance 

its mechanical properties, such as addition of dopants [3], microwave sintering [4], spark plasma sintering [5] and 

two-step sintering [6]. Since high sintering temperatures (>1450 °C) were generally required to produce high-density 

alumina ceramics using pressureless sintering [7], two-step sintering has been experimented to lower the densification 

temperatures and suppressing abnormal grain growth in order to retain a fine microstructure [8].  

Two-step sintering (TSS) is a sintering method that consists of two stages sintering. At the first stage, the green 

sample is heated to a high temperature of T1 and holding at this temperature for a very short period. This is followed 

by the second stage, where the temperature is lowered to T2 and holding at this temperature for a longer holding 

time to allow densification to proceed without grain coarsening. Based on the literatures, the intermediate relative 

density of about 70% should be attained at the first stage before proceeding to the second stage of sintering [9]. 

Numerous studies have been examined the effect of various sintering parameters such as T1, T2 and holding time to 

achieve better densification. It was revealed that the densification rate of alumina was enhanced when T1 was selected 

between 1400-1450 °C, with a relative density of 72-88%. When T1 was higher than 1450 °C, the densification rate 

has been found to decrease rapidly [10]. In another study, it was found that T1 ≤ 1450 °C could avoid rapid alumina 

grain growth. The researchers reported that sintering at 1450 °C for an hour and further cooled down to 1350 °C for 

34 h yielded alumina ceramics with relative density above 96% with no grain growth observed [11]. As for the second 

sintering temperature T2, it was proposed to be lower than 1400 °C to suppress grain growth. By employing T1 at 



Anis et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 299-304 

300 

1450 °C, the authors revealed that a flatter grain size-density slope was evidenced when T2 was set at 1350 °C (4, 8 

and 12 h holding time), as compared to 1400 °C (4 and 8 h holding time). Besides, fully dense alumina has been 

reported within 12 h of holding time at T2 of 1350 °C [10].  

Based on the research works, it was proposed that the two-step sintering temperatures T1 and T2 be set at 1450 

°C and 1350 °C, respectively. However, documented works on detailed mechanical properties are rarely available. 

Thus, this work aimed to evaluate densification and mechanical properties of alumina via conventional and two-step 

sintering. With the recommended sintering temperatures, different holding time was employed in the second stage 

of sintering. The results obtained were then compared with the conventional sintered alumina.  

 

2 METHODS AND MATERIALS 

Commercially available pure alumina (Kyoritsu Co. Ltd., Japan; 99.8% Al2O3 content, 150 nm mean particle size), 

was used in this study. The alumina powder was uniaxially pressed and cold isostatic pressed at 200 MPa (Riken 

Seiki, Japan) to form solid samples. The alumina samples were first sintered at 1450 °C (T1), with a heating rate of 10 

°C/min and hold for 1 min. The temperature was then lowered to 1350 °C (T2) and hold at this temperature at 

different holding times of 2, 4, 6, 8, 10, 12 and 24 h. Conventional sintering (CS) was also carried out for the alumina 

sample at 1450 °C / 2 h hold for comparison purpose. Detailed sintering stages of CS and TSS are listed in Table 1. 

The sintered samples were then ground using SiC papers with grit sizes ranging from 120 to 1200, before polished 

with diamond paste of 6 μm and 1 μm to achieve reflective surfaces (Imtech Grinder-Polisher). Phase analysis was 

conducted using X-ray diffraction (XRD; Rigaku Geiger-Flex diffractometer, Japan), operated with a 2θ scanning 
range from 20° to 50°. The XRD patterns were identified using Standard Joint Committee for Powder Diffraction 

Standard (JCPDS) files no. PDF#42-1468. According to Archimedes’ principle, the bulk density was measured using 

water immersion method (Densi-Meter, AG204 Mettler Toledo, Switzerland). The relative density of the sintered 

alumina was calculated by taking the theoretical density as 3.98 g/cm
3
. Vickers hardness and fracture toughness were 

determined using Vickers indentation technique. Vickers hardness was performed using a pyramidal diamond indenter 

(Wolpert Wilson Instruments, USA), with an applied load of 10 kgf, according to ASTM E384-99 and ISO 14705. 

Fracture toughness was evaluated using the formula proposed by Shetty et al. [12]. Microstructure analysis was 

analysed via the scanning electron microscope (SEM) (Philips XL30 SEM, The Netherlands). The average alumina 

grain size was then measured using the line-intercept method. 

 

Table 1: Sintering stages of conventional (CS) and two-step (TSS) sintering 

 

Sintering Method Sintering Stage (temperature/holding time) 

CS 1450 °C/2 h 

TSS1 1450 °C/1 min → 1350 °C/2 h 

TSS2 1450 °C/1 min → 1350 °C/4 h 

TSS3 1450 °C/1 min → 1350 °C/6 h 

TSS4 1450 °C/1 min → 1350 °C/8 h 

TSS5 1450 °C/1 min → 1350 °C/10 h 

TSS6 1450 °C/1 min → 1350 °C/12 h 

TSS7 1450 °C/1 min → 1350 °C/24 h 

 

3 RESULTS AND DISCUSSION 

3.1 Phase Analysis, Densification and Microstructure Evolution 

The XRD phase analysis revealed the presences of alumina phases for conventional and two-step sintered alumina 

samples, as shown in Figure 1. Alumina traces were detected at the angles of 25.5°, 35.2°, 37.8° and 43.4°, 

respectively. All the conventional and two-step sintered samples exhibited highly crystalline structures, regardless of 

the sintering holding time up to 24 h. 

The relative density and grain size of sintered alumina with different sintering holding time are presented in Figure 

2. For two-step sintered samples, it was observed that the relative density linearly increased with sintering holding 

time up to 8 h, followed by a significant increment from 92.8% (8 h) to 95.8% (10 h), with no abnormal grain 

growth observed. With the further increased of holding time, the relative density increased gradually and achieved 

highly dense samples with a relative density of about 98% (12 and 24 h). This was also accompanied by minor grain 

growth from 1.35 μm (12 h) to 1.65 μm (24 h). On the other hand, conventional sintered alumina showed a low 
relative density of 85.6% and a large average grain size of 1.93 μm, as compared with all the two-step sintered 
samples. Figure 3 shows the correlation between grains size and relative density of the sintered samples. The results 

showed that there were two grain size-densification trajectory which represents the densification rate as depicted by 

the slope of the linear line in Figure 3 could be observed for the alumina ceramic. Comparison between the two 

trajectory slopes, indicated that rapid grain growth was observed when relative density reached 95.8% and above, 

where the grain size grew rapidly from 1.15 μm to 1.65 μm. Li & Ye [11] also reported similar findings, where fast 



Densification and Mechanical Properties of Alumina Ceramics via Two-Step Sintering with Different Holding Times  

301 

grain growth was noticeable when relative density of alumina exceeded 90%. Also, they found that two-step sintered 

alumina ceramics (1450 °C/1 h → 1350 °C/34 h and 1380 °C/1 h → 1330 °C/50 h) resulted in better densification and 
smaller grain size.  

SEM micrographs of the conventional (CS) and two-step (TSS) sintered alumina samples are shown in Figure 4, 

which were generally comprised of equiaxed alumina grains. Figure 4(b-c) shows the two-step sintered alumina at 

different holding time of 6 h, 10 h and 24 h, where the grain size gradually grew with the increase of holding time. 

It was observed that all the TSS samples (with holding time up to 24 h) exhibited smaller grain size (≤ 1.65 μm), as 
compared to the CS samples (1.93 μm). This suggested that TSS has the potential to suppress alumina grain growth 
when compared to CS method Although there was a substantial reduction in grain size for TSS3 (0.98 μm) as 
compared to the CS samples, there were some porosities observed among the grains as shown in Figure 4(b). When 

the sintering holding time was increased from 6 to 10 h, the grain size grew to 1.15 μm and was accompanied by a 
reduction in porosities (Figure 4(c)). This observation shows that the densification was still incomplete at the holding 

time of 10 h. However, as the holding time was increased to 24 h, a densified and homogeneous microstructure was 

attained as depicted in Figure 4(d). TSS7 successfully demonstrated the effectiveness of two-step sintering in 

suppressing grain growth coupled with improved densification as compared to CS technique. Loh et al. [6] have also 

reported smaller grain size with limited grain growth for two-step sintered alumina ceramics as compared to 

conventional sintered sample.  

 

 
 

Figure 1: X-ray diffraction patterns of conventional (CS) and two-step sintered alumina samples at different holding 

time 

 

 
 

Figure 2: The relative density and grain size of conventional and two-step sintered alumina with different sintering 

holding time on the. Key: CS – conventional sintering, TSS – two-step sintering 



Anis et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 299-304 

302 

 

Figure 3: The grain size as a function of relative density for two-step sintered alumina 

 

 

 

  

 

Figure 4: SEM micrograph of sintered alumina: (a) CS, (b) TSS3, (c) TSS5, (d) TSS7 

  



Densification and Mechanical Properties of Alumina Ceramics via Two-Step Sintering with Different Holding Times  

303 

3.2 Vickers Hardness and Fracture Toughness 

Figure 5 shows the Vickers hardness and fracture toughness of sintered alumina with different holding time. The two-

step sintered samples demonstrated a gradual increased in hardness with the holding time, from 5.12 GPa (2 h) to 

6.3 GPa (10 h). This was followed by a steep increase in hardness with the further increment of holding time and 

reached hardness of about 8.13 GPa for holding time of 24 h. There was a substantial improvement in hardness for 

all the two-step sintered samples as compared to the conventional sintered sample (4.23 GPa). The Vickers hardness 

of the alumina was found to be strongly dependent on the relative density as shown in Figure 6.   

The fracture toughness of the two-step sintered alumina ceramics was found to vary in the range of 5.5-5.9 

MPa.m
1/2

 when held at different duration. In general, fracture toughness of the alumina did not change very much 

for holding times of 8 h and above, indicating that the holding time did not have significantly affected the toughness 

of the ceramic. Nevertheless, the fracture toughness obtained for the TSS was higher than that of the CS sample (4.73 

MPa.m
1/2

). Loh et al. [6] found that two-step sintering (1550 °C/0 min → 1450 °C/8 h) did not enhance the 
densification, Vickers hardness and fracture toughness of alumina ceramics, despite obtaining a lower grain size as 

compared to conventional sintered sample. This discrepancy could be associated with the different starting material 

used as well as the different TSS regime employed.  

 

 

Figure 5: The Vickers hardness and fracture toughness of conventional and two-step sintered alumina with different 

sintering holding time. Key: CS – conventional sintering, TSS – two-step sintering 

 

 

Figure 6: The relationship between Vickers hardness and relative density of sintered alumina 



Anis et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 299-304 

304 

4 CONCLUSIONS 

Based on the current study, the effect of second stage sintering holding time (2 to 24 h) on the densification and 

mechanical properties of two-step and conventional sintered alumina ceramics were investigated. It was found that 

two-step sintered alumina (1450 °C/1 min → 1350 °C/24 h) yielded a highly dense sample (>98%), small grain size 
(1.65 μm), high Vickers hardness of 8.13 GPa and fracture toughness of 5.91 MPam1/2. It was also found that the 
fracture toughness of two-step sintered alumina ceramics was not significantly affected by the sintering holding time 

duration. A linear relationship between Vickers hardness and densification of alumina was also identified. This work 

revealed that two-step sintering method was beneficial in suppressing alumina grain growth and resulted in improved 

densification and mechanical properties when compared to conventional sintering method. 

 

ACKNOWLEDGEMENT  

The authors are grateful to UTB and UM for providing the facilities to undertake this research.  

 

REFERENCES 

1. Katti, K. S. (2004). Biomaterials in total joint replacement. Colloids and Surfaces B: Biointerfaces, 39(3), 133-

142. 

2. Khodaii, J., Adibi, H., Barazandeh, F., Rezaei, M., & Sarhan, A. A. D. (2021). Investigation of the surface 

integrity,  flexural strength on the grinding of alumina for biomedical applications. Precision Engineering, 67,110-

122. 

3. Dhuban, S. B., Ramesh, S., Tan, C. Y., Wong, Y. H., Johnson Alengaram, U., Ramesh, S., et al. (2019). Sintering 

behaviour and properties of manganese-doped alumina. Ceramics International, 45(6), 7049-7054. 

4. Abbas, M. K. G., Ramesh, S., Lee, K. Y. S., Wong, Y. H., Ganesan, P., Ramesh, S., et al. (2020). Effects of 

sintering additives on the densification and properties of alumina-toughened zirconia ceramic composites. 

Ceramics International, 46(17), 27539-27549. 

5. Vukšić, M., Žmak, I., Ćurković, L., & Kocjan, A. (2021). Spark plasma sintering of dense alumina ceramics from 

industrial waste scraps. Open Ceramics, 5, 100076. 

6. Lóh, N. J., Simão, L., Jiusti, J., Arcaro, S., Raupp-Pereira, F., De Noni, A., et al. (2020). Densified alumina 

obtained by two-step sintering: Impact of the microstructure on mechanical properties. Ceramics International, 

46(8), 12740-12743. 

7. Li, H., Xi, X., Ma, J., Hua, K., & Shui, A. (2017). Low-temperature sintering of coarse alumina powder compact 

with sufficient mechanical strength. Ceramics International, 43(6), 5108-5114. 

8. Yin, Z., Yuan, J., Cheng, Y., Wang, C., Wang, Z., & Hu, X. (2016). Microstructure and mechanical properties of 

Al2O3/Ti(C, N) ceramic tool materials by one-step and two-step microwave sintering. Materials Science and 

Engineering: A, 670, 159-165. 

9. Chen, I. W.& Wang, X. H. (2000). Sintering dense nanocrystalline ceramics without final-stage grain growth. 

Nature, 404(6774), 168-171. 

10. Wang, C.-J., Huang, C.-Y., & Wu, Y.-C. (2009). Two-step sintering of fine alumina–zirconia ceramics. Ceramics 

International, 35(4), 1467-1472. 

11. Li, J.& Ye, Y. (2006). Densification and Grain Growth of Al2O3 Nanoceramics During Pressureless Sintering. 

Journal of the American Ceramic Society, 89(1), 139-143. 

12. Shetty, D. K., Wright, I. G., Mincer, P. N., & Clauer, A. H. (1985). Indentation fracture of WC-Co cermets. 

Journal of Materials Science, 20(5), 1873-1882.