Reactive Crystallization of Lithium Carbonate Nanoparticles by Microwave Irradiation of Aqueous Solution Containing CO2 Microbubbles

Abstract: In this study, we used minute gas-liquid interfaces around CO 2 microbubbles activated by microwave irradiation as new reaction fields and developed a crystallization technique to produce lithium carbonate (Li 2 CO 3 ) nanoparticles. At the minute gas-liquid interfaces, nucleation occurs predominantly because of the formation of numerous local supersaturation regions at higher temperatures; hence, fine-sized Li 2 CO 3 particles with a narrow size distribution are crystallized, as the Li 2 CO 3 solubility decre… Show more

“…Taborga et al [12] have investigated the effects of different additives on the size and morphology of Li 2 CO 3 crystals and have proposed that the presence of polyethylenimine (PEI), polyethylene glycol (PEG), and poly (4-styrenesulfonic acid) (P4SA) can increase the length of Li 2 CO 3 crystals. Matsumoto et al [13] developed a novel crystallization technique to produce Li 2 CO 3 nanoparticles using minute gas-liquid interfaces around CO 2 microbubbles activated by microwave irradiation. The results showed that with the formation of numerous local supersaturation regions at the minute gas-liquid interfaces, fine-sized Li 2 CO 3 particles with a narrow size distribution were crystallized due to the higher nucleation rate.…”

Mechanism and Modelling of Reactive Crystallization Process of Lithium Carbonate

“…Taborga et al [12] have investigated the effects of different additives on the size and morphology of Li 2 CO 3 crystals and have proposed that the presence of polyethylenimine (PEI), polyethylene glycol (PEG), and poly (4-styrenesulfonic acid) (P4SA) can increase the length of Li 2 CO 3 crystals. Matsumoto et al [13] developed a novel crystallization technique to produce Li 2 CO 3 nanoparticles using minute gas-liquid interfaces around CO 2 microbubbles activated by microwave irradiation. The results showed that with the formation of numerous local supersaturation regions at the minute gas-liquid interfaces, fine-sized Li 2 CO 3 particles with a narrow size distribution were crystallized due to the higher nucleation rate.…”

Mechanism and Modelling of Reactive Crystallization Process of Lithium Carbonate

“…The results obtained in the two systems indicated that local supersaturation in the regions around the minute gas-liquid interfaces increased approximately twice compared with the supersaturation of the surrounding bulk solution, and the generation of numerous local supersaturation regions near the gas-liquid interfaces decreased the r C/CS necessary for the selective crystallisation of the metastable a-form and unstable b-form. Examination of the electrification of minute-bubbles was conducted by the zeta potential measurement to clarify the occurrence of interactions at the gas-liquid interfaces [13][14][15]. The zeta potential of the minutebubbles in water was negative, from À40 to À90 mV, at an average bubble diameter of 10-30 lm.…”

“…In this study, a micron-scale bubble formation technique that enables the generation of local supersaturation in the regions around the gas-liquid interfaces was applied to the antisolvent crystallisation of glycine to control polymorphism. Minimising the bubble diameter in the gas-liquid systems helps achieve the following: (i) acceleration of mass transfer and reactive absorption with an increase in the gas-liquid interfacial area, (ii) an increase in the average residence time of the bubbles with a decrease in buoyancy, and (iii) the occurrence of interactions at the gas-liquid interface caused by electrification of minute-bubbles [13][14][15]. When minute-bubbles with the above properties are introduced into the antisolvent crystallisation of glycine, the local supersaturation at the minute gas-liquid interfaces increases due to the accumulation of glycine and antisolvent caused by the residence of minute-bubbles with surface potential in the liquid phase for a long period of time.…”

Change in glycine polymorphs induced by minute-bubble injection during antisolvent crystallisation

“…Compared to the previous studies, our experimental results indicated that not only increasing V MeOH but also bubble injection and minimizing bubble size led to the enhanced production of unstable ß-form caused by the inhibition of polymorphic transformation from ß-form to α-form. Investigation about the electric charge on the minutebubble surface to clarify the occurrence of interactions at the gas-liquid interfaces revealed that the zeta potential of minute-bubbles with d bbl of 10 -30 µm was negative value between -50 and -100 mV [6,7,9], and the presence of glycine and methanol led to the zeta potential approach to 0 mV [12]. These findings indicated that glycine and methanol concentrations increased locally in the vicinity area of minute gas-liquid interfaces.…”

“…Minimizing bubble diameter in gas-liquid systems helps achieve the following: i) acceleration of mass transfer and reactive absorption with an increase in the gas-liquid interfacial area, ii) increase in the average residence time of the bubbles with a decrease in buoyancy, and iii) occurrence of interactions at the gas-liquid interface caused by electrification of minute-bubbles [6,7]. Because solute and antisolvent are accumulated near the gas-liquid interfaces by the residence of minute-bubbles with surface potential in the liquid phase for a long period of time, the production of a less stable polymorph and the shift in the overall solid-liquid equilibrium can be expected to occur.…”

Enhanced production of unstable polymorph by antisolvent crystallization supplying minute-bubbles