Fig. 2b shows that the particle siz

Fig. 2b shows that the particle size rises first and then aggregation (A5 in Table 3) is formed with the increment of NH3 concentration.

This result is inconsistent with that of Wang et al. [18].NH3, as a catalyst, could accelerate TEOS hydrolysis and condensation reactions, resulting in producing more oligomers to form larger
particles, but at higher NH3 concentration, aggregation will be formed if condensation rate is larger than TEOS hydrolysis rate.

Fig. 2c illustrates that the influence of the water concentration on particle size follows the similar trend as NH3, that is, the particle size increases with increasing H2O concentration and reaches the maximum value at about 6 M, and then descends at higher concentration.

This result shows good agreement with the work of [16,18,19]. H2O could accelerate TEOS hydrolysis to contribute to formation of larger particles, while at higher H2O concentration,
H2O dilutes the oligomers in reaction solution, resulting in the formation of smaller particles. Much detailed discussion about effect of NH3 and H2O on the particle size could be seen in Section 3.3 and 4.

Moreover, Bougush et al. [19] found that near the maximum achievable size for any given TEOS concentration, monodispersity could hardly be achieved and bimodal final particle size distributions were commonly observed.

However, in our experiments, near the maximum achievable size (873 nm) for 0.75 M TEOS, monodispersity is often achieved and only the bimodal final particle size distribution can be observed at 0.15 M NH3 and 4.7 M H2O (A1 in Table 3). Further investigations on this phenomenon are underway to understand completely the formation mechanism of particles in this reaction system.