TY - DATA T1 - Molecular Insights into the Nucleation and Growth of CH4 and CO2 Mixed Hydrates from Microsecond Simulations PY - 2016/11/02 AU - Zhongjin He AU - Krishna M. Gupta AU - Praveen Linga AU - Jianwen Jiang UR - https://acs.figshare.com/articles/media/Molecular_Insights_into_the_Nucleation_and_Growth_of_CH_sub_4_sub_and_CO_sub_2_sub_Mixed_Hydrates_from_Microsecond_Simulations/4193448 DO - 10.1021/acs.jpcc.6b07780.s005 L4 - https://ndownloader.figshare.com/files/6842439 KW - 5 12 6 2 KW - 5 12 6 4 KW - 5 12 KW - 5 12 6 3 KW - Microsecond Simulations Hydrates KW - hydrogen-bonded water rings KW - nucleation KW - water molecules KW - CO 2 KW - 4 1 5 10 6 3 KW - 4 1 5 10 6 2 KW - 4 1 5 10 6 4 KW - CH 4 KW - CO 2 Mixed Hydrates KW - gas hydrate resource KW - 5 12 6 2 cages KW - 5 12 cages KW - 4 1 5 10 6 2 metastable cages KW - simulation results show N2 - Hydrates of CH4/CO2 gas mixture are widely involved in hydrate-based applications, such as CH4/CO2 separation and exchange in exploitation of natural gas hydrate resource; nevertheless, their formation mechanisms remain elusive. In this study, microsecond simulations are performed to investigate the nucleation and growth of CH4/CO2 mixed hydrates from two-phase systems of water and CH4/CO2 gas mixture. The simulation results show that CH4-occupied small 512 cages initiates hydrate nucleation in a local liquid phase with a high gas concentration, where CO2 and CH4 cooperatively adsorb to hydrogen-bonded water rings toward hydrate-like ordering and cage formation. The difference in hydrophobicity between CH4 and CO2 affects the stability of nanobubbles of CH4/CO2 gas mixture in water and nucleation rate, and a high content (>75%) of CO2 accelerates nucleation due to its high solubility. The formation kinetics reveals the preferential uptake of CH4 into CH4/CO2 mixed hydrates during nucleation and the transition from fast to slow growth due to the rapid conversion of free water into hydrates. After hydrate growth, most water molecules in the systems are converted to CH4/CO2 mixed hydrates, composed of standard cages (512, 51262, 51263, and 51264) and metastable cages (4151062, 4151063, and 4151064). In these incipient hydrates, gas molecules always prefer to occupy the size-fitting cages, i.e., CH4 in 512, 4151062, 51262 cages and CO2 in 4151062, 51262, respectively. Interestingly, the abundance of 4151062 metastable cages (especially those CO2 occupied), with a size between those of small 512 and large 51262 cages, suggests their important role in the formation of incipient CH4/CO2 mixed hydrates. Multiple pathways are observed for the nucleation of CH4/CO2 mixed hydrates. In most of the systems, amorphous hydrates are formed with small sI and sII motifs exhibiting short-range orders, while only one system grows into partially ordered solids containing a large sI domain with long-range order spanning the whole simulation box. From bottom-up, this simulation study reveals the complex interplay between gas and water molecules at the condition of hydrate formation, and provides microscopic insights into the nucleation and growth of CH4/CO2 mixed hydrates. ER -