Department of Physics, University of Helsinki, Finland.
J Phys Chem A. 2010 Aug 12;114(31):8033-42. doi: 10.1021/jp103499q.
This study presents a computational fluid dynamics modeling approach to investigate the nucleation in the water-sulfuric acid system in a flow tube. On the basis of an existing experimental setup (Brus, D.; Hyvärinen, A.-P.; Viisanen, Y.; Kulmala, M.; Lihavainen, H. Atmos. Chem. Phys. 2010, 10, 2631-2641), we first establish the effect of convection on the flow profile. We then proceed to simulate nucleation for relative humidities of 10, 30, and 50% and for sulfuric acid concentration between 10(9) to 3 x 10(10) cm(-3). We describe the nucleation zone in detail and determine how flow rate and relative humidity affect its characteristics. Experimental nucleation rates are compared to rates gained from classical binary and kinetic nucleation theory as well as cluster activation theory. For low RH values, kinetic theory yields the best agreement with experimental results while binary nucleation best reproduces the experimental nucleation behavior at 50% relative humidity. Particle growth is modeled for an example case at 50% relative humidity. The final simulated diameter is very close to the experimental result.
本研究提出了一种计算流体动力学建模方法,用于在流管中研究水-硫酸体系中的成核。基于现有的实验装置(Brus,D.;Hyvärinen,A.-P.;Viisanen,Y.;Kulmala,M.;Lihavainen,H.),我们首先确定了对流对流动形态的影响。然后,我们模拟了相对湿度为 10%、30%和 50%以及硫酸浓度为 10(9)至 3 x 10(10)cm(-3)时的成核情况。我们详细描述了成核区,并确定了流速和相对湿度如何影响其特性。将实验成核速率与经典的二元和动力成核理论以及簇活化理论获得的速率进行了比较。对于低 RH 值,动力理论与实验结果最为吻合,而二元成核在 50%相对湿度下最佳地再现了实验成核行为。对于 50%相对湿度的一个示例情况,模拟了粒子生长。最终模拟的直径与实验结果非常接近。