| 3 | -- | 5 | Anne Jacobson, Pam Frost Gorder. Virtual physics lab close to reality |
| 6 | -- | 7 | Pam Frost Gorder. The googling of astronomy |
| 8 | -- | 11 | Douglas Tougaw, Jeffrey Will. Visualizing the future of virtual reality |
| 12 | -- | 13 | William L. Hase, Gustavo E. Scuseria. Computational chemistry |
| 14 | -- | 21 | Stefan Goedecker, Gustavo E. Scuseria. Linear scaling electronic structure methods in chemistry and physics |
| 22 | -- | 30 | Robert E. Wyatt, Eric R. Bittiner. Using quantum trajectories and adaptive grids to solve quantum dynamical problems |
| 31 | -- | 35 | Srinivasan Iyengar, Christian J. Burnham, Matt K. Petersen, Gregory A. Voth. Modeling condensed-phase chemistry through molecular dynamics simulation |
| 36 | -- | 44 | William L. Hase, Kihyung Song, Mark S. Gordon. Direct dynamics simulations |
| 45 | -- | 55 | Christoph Lossen. Singular: a computer algebra system |
| 56 | -- | 58 | R. Bowen Loftin. Multisensory perception: beyond the visual in visualization |
| 59 | -- | 67 | John Reid. The future of Fortran |
| 68 | -- | 71 | Dianne P. O'Leary, Yalin Evren Sagduyu, James G. Nagy. Robot control: swinging like a pendulum |
| 72 | -- | 74 | James G. Nagy, Dianne P. O'Leary. Partial solution to "Image deblurring: I can see clearly now" |
| 75 | -- | 87 | Muhammad Sahimi. Large-scale porous media and wavelet transformations |
| 88 | -- | 93 | David M. Smith. Using multiple-precision arithmetic |
| 94 | -- | 96 | Geoffrey Fox. Integrating computing and information on Grids |