In a striking advancement in water purification technology, researchers from Jiangnan University have developed a continuous microfluidic plasma reactor that effectively degrades methylene blue, a hazardous dye prevalent in textile wastewater. Methylene blue’s persistence in the environment and carcinogenic risks have long challenged conventional treatment methods, which either merely transfer pollutants or rely on energy-intensive processes with precise chemical demands.
This innovative system employs a dielectric barrier discharge (DBD) plasma generated within a polytetrafluoroethylene (PTFE) capillary—wound around a quartz tube. The reactor’s design features a copper rod high-voltage electrode within the quartz tube and a surrounding copper mesh as a grounded electrode. Both structures act as dielectric barriers, stabilizing plasma discharge inside the capillary. Argon gas flows alongside the methylene blue solution, forming a gas-liquid biphasic stream that passes through the plasma zone, allowing continuous exposure to highly reactive plasma species.
Comprehensive parameter studies revealed that degradation efficiency improves with increased plasma power and longer residence time, but declines when starting methylene blue concentrations rise. At 5.6 watts of plasma power, a 20 mg/L dye solution was nearly completely degraded—achieving 99.72% breakdown—in under 16 seconds. Remarkably, boosting plasma power to 17.3 watts enabled total (100%) degradation of a 100 mg/L solution in the same short interval.
Kinetic investigations demonstrated that the degradation kinetics conform closely to a pseudo-first-order model, with excellent correlation (R² = 0.9969). Interestingly, the rate constant diminished from 0.369 to 0.151 s⁻¹ as initial dye concentrations increased, a phenomenon attributed to the competitive scavenging of plasma-generated reactive radicals at higher pollutant loads.
Optical emission spectroscopy provided insight into the reactive species driving the degradation—hydroxyl radicals (OH at 309 nm), atomic hydrogen lines (Hα at 656 nm, Hβ at 486 nm), and atomic oxygen (at 777 nm) were identified as dominant. Radical quenching tests employing isopropanol, a hydroxyl radical scavenger, significantly reduced degradation efficiency and rate constants, confirming hydroxyl radicals as vital oxidative agents.
Further mass spectrometry analyses traced methylene blue’s breakdown pathway, beginning with hydroxyl radical-induced demethylation and ring cleavage that generated intermediates such as azure B, azure A, and azure C. These intermediates then underwent successive oxidation to yield simpler organic acids and inorganic ions, indicating thorough mineralization potential.
The system’s continuous operation and stable discharge were validated by voltage-charge monitoring and consistent spectral profiles, while the energy yield for degrading 100 mg/L methylene blue at around 7 seconds residence time reached a promising 73.10 g·kWh⁻¹. Although the current setup is limited to single-capillary throughput, scaling up via multiple parallel channels could augment pollutant processing capacity significantly.
This breakthrough microfluidic plasma technology not only offers an intensified and energy-efficient approach for treating recalcitrant organic dyes but also sets a precedent for continuous water remediation processes with enhanced operational control and efficiency.
Article Title: Degradation of methylene blue by a continuous microfluidic plasma process
News Publication Date: 10-May-2026
Web References: http://dx.doi.org/10.1007/s11705-026-2665-3
Keywords
microfluidic plasma, methylene blue degradation, dielectric barrier discharge, water treatment, hydroxyl radicals, continuous reactor, advanced oxidation processes

