New CFD model optimizes green production of high-purity chemicals

In the production of dimethyl carbonate (DMC), a versatile chemical critical for manufacturing lithium-ion battery electrolytes, pharmaceuticals and high-performance polymers, an ultra-high purity (≥99.95%) is needed to meet stringent industrial standards. Melt crystallization, as a green manufacturing method is highly important for this purpose; however, the widespread adoption of this technology has been hindered by complex heat and mass transfer phenomena, which can lead to uneven crystal growth and suboptimal yields.

Addressing these challenges, a research team from Tianjin University’s National Engineering Research Center of Industrial Crystallization Technology has proposed a new computational model that reveals the dynamics of DMC crystallization. By integrating computational fluid dynamics (CFD) simulations with experimental data, the team mapped how natural convection—a process driven by temperature-induced fluid flow—shapes the distribution of DMC crystal layers, causing lower yield.

“The dynamic heating strategy precisely modulates the temperature gradient along the crystallizer walls, providing a balance between rapid crystal growth and higher yield,” explains explained lead author ​Prof. Hongxun Hao. “Our model bridges the gap between theoretical predictions and industrial reality.”

By quantifying how fluid dynamics interact with thermal gradients, the researchers can now tailor crystallization processes to specific materials, slashing energy use and production time without compromising quality.”

The study further introduced a predictive correlation that links crystallization time, crystal yield, and heat transfer coefficients—a tool provided a new sight of design and optimization of melt crystallization processes. The findings are published in Green Chemical Engineering.

“Validated through laboratory-scale experiments, the computational framework offers a cost-effective pathway for scaling up melt crystallization in industries,” adds Hao. “Beyond DMC, the methodology holds promise for purifying other thermally sensitive materials, such as organic semiconductors and pharmaceutical intermediates, where precision and sustainability are paramount.”

###

Contact the author: Hongxun Hao National Engineering Research Center of Industrial Crystallization Technology, School of Chemical Engineering and Technology, Tianjin University, Tianjin, China, Email: hongxunhao@tju.edu.cn.

Green Chemical Engineering (GreenChE) is a peer-reviewed international and interdisciplinary journal for the significant cutting-edge research and the latest technological advances in core areas of green and sustainable development of chemistry and chemical engineering as well as in other relevant disciplines. Our articles mainly focus on presenting new findings of exceptional significance to their field, and also be of wider interest to readers working in other areas across the green chemical engineering. Up to now, GreenChE has been included in ESCI, EI, Scopus, and CSCD databases, and all articles of GreenChE are available on the Web of Science platform.