Mo Jiang, Ph.D.

Assistant Professor, Department of Chemical and Life Science Engineering

  • Richmond VA UNITED STATES
  • Biotech 8 419A
  • Chemical and Life Science Engineering

Advance crystallization and material manufacturing for health and energy applications

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Biography

Mo Jiang has been at VCU since 2018. His main research interests include to advance scalable sustainable production of emerging materials with precise control for health and energy applications, and to understand the links among the synthesis process, particle property distribution, and product quality. Current projects include energy-efficient scalable manufacturing of essential (bio)pharmaceutical ingredients and active cathode materials for Li-ion batteries using slug flow.

Industry Expertise

Chemicals
Energy
Pharmaceuticals
Manufacturing

Areas of Expertise

Advanced Manufacturing and Materials Engineering
Reactive crystallization
Process crystallization
Multiphase slug flow
Reaction Engineering
Separations
(Bio)Pharmaceuticals
Battery materials
Process design and control

Education

Massachusetts Institute of Technology

Ph.D.

Chemical Engineering

2015

University of Illinois at Urbana-Champaign

M.S.

Chemical Engineering

2008

Tsinghua University

B.S.

Biology

2006

Affiliations

  • American Institute of Chemical Engineers - Senior Member

Media Appearances

VCU receives $2.5M grant to extend battery life development

Virginia Business  online

2020-02-13

“Our goal is to improve the batteries so that they can last longer, be more durable and safer,” Gupta said in a statement. He will work with Mo Jiang, a VCU assistant professor, and Parans Paranthaman, a corporate fellow at Oak Ridge National Laboratory.

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Research Focus

• Advanced manufacturing of uniform and tunable particles (e.g., lithium-ion battery cathode materials)

With expanding demand of lithium-ion batteries in portable electronic devices, such as smartphones and iPads and environmental-friendly vehicles (e.g., electric and hybrid vehicles), it is important to further improve safety, extend battery life, increase charge capacity, and reduce cost. A key missing component is effective and efficient manufacturing of complex active cathode materials, such as nickel-cobalt-manganese oxide micron-sized particles, at needed production scales. Cathode microparticle quality and uniformity are difficult to control with current reactor technologies, requiring post-synthesis procedures such as milling and sieving to narrow the particle size distribution. This risks product quality and reduces production efficiency. An innovative slug-flow reactor manufacturing process is developed to directly produce well-controlled microparticles for advanced battery performance and accelerated scale-up. The availability of controllable cathode materials makes electronic devices using lithium-ion batteries safer and of better quality at a lower cost. One impact of this research is reduced environmental impact due to efficient materials use and increased battery life.

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• Scalable continuous crystallization process with platform design

In the pharmaceutical and chemical industries, the continuous generation of crystals of target size distribution has the potential to improve efficiency for post-crystallization operations. The control of crystallization processes can be challenging when undesirable phenomena such as particle attrition and breakage occur. Segmented/slug flow crystallization is one of the effective continuous processes demonstrated to allow enhanced control of organic crystal properties such as size and shape. The slurry flow is combined with an air flow and fed to a tube to induce a multiphase hydrodynamic instability that spontaneously generates well-mixed slugs where the crystals continue to grow. The slug flow continuous crystallization platform is developed and process designed for important pharmaceuticals.

Research Grants

USP: Rifapentine Synthesis

U.S. Pharmacopeial Convention

2021-02-15

This project aims to synthesize pharmaceutical Rifapentine with consistent high quality and reduced costs. Specifically, continuous flow processes are developed for reaction synthesis, purification, and crystallization

Advanced Slug-flow Manufacturing of Uniform and Tunable Battery Cathode Particles

Department of Energy

2020-09-01

This project aims to increase energy density and lifetime of battery, by manufacturing low-Cobalt cathode oxide material with tunable quality, using self-mixed slug flow, and scale up reaction process for industrial collaboration.

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Slug-Flow Reactor Manufacturing of Uniform Nickel-Cobalt-Manganese Oxide Microparticles for Battery Cathodes

National Science Foundation

2020-01-01

This research is to develop a new process for the manufacture of uniform nickel-cobalt-manganese (NCM) oxide microparticles to serve as cathodes in lithium-ion batteries. It explores a continuous slug-flow manufacturing technology. Microscopically, in a slug-flow reactor, each particle experiences the same environment with spatially uniform reaction kinetics and hydrodynamics conditions throughout the nucleation and growth process, leading to uniform particles with controlled compositions, microstructures and properties. Macroscopically, the manufacturing setup and conditions can remain the same while allowing convenient tuning of the production rate, i.e., scaling up or scaling down. The slug flow process is also equipped with in-line bright-field imaging for microparticle monitoring and quality control. The research advances the fundamental understanding of microparticle nucleation, growth, and reaction engineering. It also studies the link between microparticles with high uniformity and controlled spatial composition and battery performance, which sheds light on a rational way to produce next-generation battery materials.

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Courses

CLSE 409 Process Control in Chemical and Life Science Engineering

The goals of this core course are to train undergraduate students to develop mathematical models that involve material and energy balance equations for dynamic single and multi-unit reactive and non-reactive chemical processes with recycle and bypass streams. Students will also learn to define transfer functions that relate the input and output variables in the system and understand the dynamics of first-, second-, and higher-order systems by quantitatively describing the system response to inputs, such as step changes. Finally, students will apply a variety of techniques that enhance feedback control that include designing a simple feedback control loop, performing stability analysis on feedback and cascade systems and tuning control loops and address safety.

CLSE 656 Advanced Chemical Reaction Engineering

This graduate-level core course builds upon foundations of chemical reaction engineering with a goal of educating students to apply contemporary tools for the analysis and design of modern chemical reactor systems. The course will provide a review of chemical reaction engineering principles before progressing to advanced topics. Advanced material in this course will include the development of mathematical models and computational implementation to simulate reacting systems and experimental approaches to determine reaction parameters and mechanisms. Additional materials will cover current approaches of industrial crystallization for production, purification, and formulation of solid chemicals.

ENGR 591 Process Analytical Technology

The goals of this core course for pharmaceutical engineering are to help students to understand the principles, know state-of-the-arts, and gain practical experience of important process analytical technology. Specifically, the operation and techniques of analytical instrumentation commonly used, for in-line monitoring/control, on-line or off-line analysis. Also, students will get better understanding and preventing common mistakes on data collection (e.g., sampling), data comprehension, and data analysis (e.g., chemometrics).

Selected Articles

Slug-flow co-precipitation synthesis of uniformly-sized precursor microparticles towards improved reproducibility and tap density of Li(Ni0.8Co0.1Mn0.1)O2 for Li-ion batteries

ACS Applied Energy Materials

M. Mou, A. Patel, S. Mallick, K. Jayanthi, X. Sun, M. P. Paranthaman, S. Saleh, S. Kothe, E. Baral, J. H. Mugumya, M. L. Rasche, R. B. Gupta, H. Lopez, M. Jiang

2023-03-06

The microparticle quality and reproducibility of Li(Ni0.8Co0.1Mn0.1)O2 (NCM811) cathode materials are important for Li-ion battery performance but can be challenging to control directly from synthesis. Here, a scalable reproducible synthesis process is designed based on slug flow to rapidly generate uniform micron-size spherical-shape NCM oxalate precursor microparticles at 25–34 °C. The whole process takes only 10 min, from solution mixing to precursor microparticle generation, without needing aging that typically takes hours. These oxalate precursors are convertible to spherical-shape NCM811 oxide microparticles, through a preliminary design of low heating rates (e.g., 0.1 and 0.8 °C/min) for calcination and lithiation. The outcome oxide cathode particles also demonstrate improved tap density (e.g., 2.4 g mL–1 for NCM811) and good specific capacity (202 mAh g–1 at 0.1 C) in coin cells and reasonably good cycling performance with LiF coating.

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Synthesis and theoretical modelling of suitable co-precipitation conditions for producing NMC111 cathode material for lithium-ion batteries

Energy & Fuels

J. H. Mugumya, M. L. Rasche, R. Rafferty, A. Patel, S. Mallick, M. Mou, J. Bobb, R. B. Gupta, M. Jiang

2022-09-08

Lithium nickel manganese cobalt oxide (NMC111) is considered to be one of the most promising cathode materials for commercial lithium-ion battery (LIB) fabrication. Among the various synthesis procedures of NMC111, hydroxide co-precipitation followed by lithiation is the most cost-effective and scalable method. Physical and chemical properties of the co-precipitation product such as yield, particle size, morphology, and tap density, depend upon the various reaction parameters, which include pH, chelating agents, metal salt concentrations, and stirring speed. As a consequence, detailed theoretical and experimental modeling is critically required to not only understand the interdependence between the particle properties and reaction conditions but also optimize these parameters. In this study, theoretical modeling was performed to analyze the role of various NH4OH concentrations with varying pH on the yield of the NMC(OH)2 product. From the experimental findings, it was observed that the product obtained at a pH of 11.5 and NH4OH concentration of 0.02 M possessed the highest tap density. Three of the hydroxide precursors with different tap density values were chosen to lithiate and were applied for coin cell fabrication. The NMC(OH)2 precursor with the highest tap density had the highest specific capacity of 155 mAh g–1 at 0.1 C and retained up to 78.6 mAh g–1 at 5 C. The variation of the Li+ diffusion coefficient for the three selected materials was also studied using electrochemical impedance analysis.

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Fast continuous non-seeded cooling crystallization of glycine in slug flow: Pure α-form crystals with narrow size distribution

Journal of Pharmaceutical Innovation

M. Mou, M. Jiang

2020-03-03

Glycine has been widely used as pharmaceutical excipients and synthesis reagents, and commercial glycine has a significant amount of aggregation and wide particle size distribution. A simple but reproducible process for generating uniform glycine crystals is always desired for both product quality and process efficiency purposes. Glycine crystals of α-form and narrow size distribution can be continuously generated within 10 min from cooling crystallization in millimeter-sized slug flow, without using external seeds nor adding solvent/additives. And, the operational boundaries of crash cooling time (at proper starting concentrations) for pure α-form non-aggregating product crystals are identified.

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