The 0.7 M SO₄/ZrO₂ catalyst was synthesized from the ZrO₂ precursor with 0.7 M H₂SO₄ through the wet impregnation method, then examined the effect of calcination temperature (400 and 500 ^oC) on the catalyst through characterization using XRD, FT-IR, SEM-EDX, and acidity test using ammonia as the adsorbate base. The 0.7 M SO₄/ZrO₂-400 catalyst had two types of crystalline phases namely monoclinic and a small peak of metastable tetragonal, while the crystalline phase of 0.7 M SO₄/ZrO₂-500 was only monoclinic. The results of FT-IR analysis showed that the four typical bands of sulfate ions that were perfectly coordinated with zirconium cations were found both at 400 and 500 ^oC calcination temperatures with almost the same band intensity. However, the acidity test results showed that the 0.7 M SO₄/ZrO₂-400 catalyst had a total acidity that was slightly greater than 0.7 M SO₄/ZrO₂-500 which was 5.74 and 5.59 mmol g^-1 respectively. The results of SEM-EDX analysis also showed that the surface of the 0.7 M SO₄/ZrO₂-400 catalyst was also brighter than 0.7 M SO₄/ZrO₂-500 which indicated that more sulfate ions were impregnated on the surface of zirconia with the SO₃ species mass was 5.75% while the SO₃ species mass of 0.7 M SO₄/ZrO₂-500 was only 4.62%.

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