Zahariev Federico, Xu Peng, Westheimer Bryce M, Webb Simon, Galvez Vallejo Jorge, Tiwari Ananta, Sundriyal Vaibhav, Sosonkina Masha, Shen Jun, Schoendorff George, Schlinsog Megan, Sattasathuchana Tosaporn, Ruedenberg Klaus, Roskop Luke B, Rendell Alistair P, Poole David, Piecuch Piotr, Pham Buu Q, Mironov Vladimir, Mato Joani, Leonard Sam, Leang Sarom S, Ivanic Joe, Hayes Jackson, Harville Taylor, Gururangan Karthik, Guidez Emilie, Gerasimov Igor S, Friedl Christian, Ferreras Katherine N, Elliott George, Datta Dipayan, Cruz Daniel Del Angel, Carrington Laura, Bertoni Colleen, Barca Giuseppe M J, Alkan Melisa, Gordon Mark S
Department of Chemistry and Ames Laboratory, Iowa State University, Ames, Iowa 50014, United States.
VeraChem LLC, 12850 Middlebrook Road, Suite 205, Germantown, Maryland 20874-5244, United States.
J Chem Theory Comput. 2023 Oct 24;19(20):7031-7055. doi: 10.1021/acs.jctc.3c00379. Epub 2023 Oct 4.
The primary focus of GAMESS over the last 5 years has been the development of new high-performance codes that are able to take effective and efficient advantage of the most advanced computer architectures, both CPU and accelerators. These efforts include employing density fitting and fragmentation methods to reduce the high scaling of well-correlated (e.g., coupled-cluster) methods as well as developing novel codes that can take optimal advantage of graphical processing units and other modern accelerators. Because accurate wave functions can be very complex, an important new functionality in GAMESS is the quasi-atomic orbital analysis, an unbiased approach to the understanding of covalent bonds embedded in the wave function. Best practices for the maintenance and distribution of GAMESS are also discussed.
在过去五年中,通用原子和分子电子结构系统(GAMESS)的主要重点是开发新的高性能代码,这些代码能够有效且高效地利用最先进的计算机架构,包括中央处理器(CPU)和加速器。这些工作包括采用密度拟合和碎片化方法来降低强关联方法(例如耦合簇方法)的高计算量增长,以及开发能够最佳利用图形处理单元和其他现代加速器的新型代码。由于精确的波函数可能非常复杂,GAMESS中的一项重要新功能是准原子轨道分析,这是一种用于理解波函数中嵌入的共价键的无偏方法。文中还讨论了GAMESS维护和分发的最佳实践。
