Optimization for modulation conditions in nanoparticle synthesis using tandem modulated induction thermal plasmas with intermittent synchronized feeding by machine learning
Abstrak
The influence of control parameters was studied on silicon (Si) nanoparticle synthesis using tandem modulated induction thermal plasmas (Tandem-MITP) with time-controlled feeding of feedstock (TCFF) method to optimize the modulation conditions on the basis of machine learning technique. This novel method, developed by our group, creates a time-varying high-temperature thermofluid field that facilitates efficient nanoparticle synthesis, with numerous control parameters influencing the process. To optimize the synthesis conditions, a comprehensive numerical thermofluid model was developed to simulate thermal plasma fields, feedstock dynamics, and nanoparticle formation and transport. Using this model, we applied a machine learning-based sequential approximate optimization (SAO) method with a radial basis function (RBF) network to identify optimal modulation conditions for maximizing nanoparticle production with smaller particle sizes. The results demonstrate that higher modulation amplitudes induce greater fluctuations in the plasma temperature and gas flow fields, leading to an increased quantity of smaller Si nanoparticles. Results showed that larger modulation condition provides larger variation in temperature-gas flow field, which results in larger quantities of smaller nanoparticles.
Penulis (9)
Yasunori Tanaka
Y. Nagase
R. Okano
Y. Nakano
T. Ishijima
S. Kitayama
S. Sueyasu
Shu Watanabe
Keitaro Nakamura
Format Sitasi
Akses Cepat
- Tahun Terbit
- 2025
- Bahasa
- en
- Total Sitasi
- 1×
- Sumber Database
- Semantic Scholar
- DOI
- 10.1007/s41614-025-00188-5
- Akses
- Open Access ✓