Abstract
There are still many unsolved mysteries in the thermal decomposition process of urea. This paper studied the thermal decomposition process of urea at constant temperatures by the thermal gravimetric–mass spectrometry analysis method. The results show that there are three obvious stages of mass loss during the thermal decomposition process of urea, which is closely related to the temperature. When the temperature was below 160 °C, urea decomposition almost did not occur, and molten urea evaporated slowly. When the temperature was between 180 and 200 °C, the content of biuret, one of the by-products in the thermal decomposition of urea, reached a maximum. When the temperature was higher than 200 °C, the first stage of mass loss was completed quickly, and urea and biuret rapidly broke down. When the temperature was about 240 °C, there were rarely urea and biuret in residual substance; however, the content of cyanuric acid was still rising. When the temperature was higher than 280°C, there was a second stage of mass loss. In the second stage of mass loss, when the temperature was higher than 330 °C, mass decreased rapidly, which was mainly due to the decomposition of cyanuric acid. When the temperature was higher than 380 °C, the third stage of mass loss occurred. However, when the temperature was higher than 400 °C, and after continuous heating was applied for a sufficiently long time, the residual mass was reduced to almost zero eventually.
Highlights
Interest in the study of urea has continued to grow since urea was found by Roselle [1]in 1773
The urea pyrolysis process with the temperature rising at a certain heating rate has been studied by many researchers
The urea pyrolysis process has a close relationship with the temperature, so thermogravimetric experiments of urea at constant temperatures were studied in this paper
Summary
Interest in the study of urea has continued to grow since urea was found by Roselle [1]in 1773. Interest in the study of urea has continued to grow since urea was found by Roselle [1]. In 1828, German chemist Wohler [2] converted inorganic ammonium cyanate to organic urea by heating method for the first time, which, for the first time, broke the traditional idea that organics can only be obtained from organic compounds. The synthesis of urea has opened a prologue of artificial synthesis organics, and it is thought to be a pioneer in organic chemistry research. Urea has been widely used in many fields such as the medical industry, agriculture, manufacture, and commerce and is closely related to human production and living. There are still many mysteries in the thermal decomposition process of urea. Selective catalytic reduction (SCR), which uses urea water solution (UWS)
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