| R-1 | Bernard, E.N. — The U.S. National Tsunami Hazard Mitigation Program Summary |
| R-2 | González, F.I., et al. — The NTHMP Inundation Mapping Program |
| R-3 | Priest, G.R., et al. — Tsunami hazard assessment in Oregon |
| R-4 | Eisner, R.K., et al. — Inundation maps for the State of California |
| R-5 | Oppenheimer, D., et al. — The CREST Project: Consolidated reporting of earthquakes and tsunamis |
| R-6 | Bernard, E.N., et al. — Early detection and real-time reporting of deep-ocean tsunamis |
| R-7 | McCreery, C.S. — Impact of the National Tsunami Hazard Mitigation Program on operations of the Pacific Tsunami Warning Center |
| R-8 | Jonientz-Trisler, C. — The Mitigation Strategic Implementation Plan: Toward tsunami-resistant communities |
| R-9 | Hagemeyer, R. — Develop state/NOAA coordination and technical support |
| R-10 | Frinell-Hanrahan, K. — Creating a tsunami-ready community |
| R-11 | Brown, G., and S. Simmons — Alaska's 5-year tsunami activity report (1997–2001) |
| R-12 | Hansen, R., et al. — Tsunami inundation mapping for Alaska communities |
| R-13 | Eisner, R.K. — State of California tsunami 5-year review (1997–2001) |
| R-14 | Dengler, L. — Tsunami mitigation efforts on California's north coast |
| R-15 | Yanagi, B.S. — State of Hawaii tsunami 5-year review (1997–2001) |
| R-16 | Fryer, G.J., et al. — Inundation mapping in Hawaii |
| R-17 | Darienzo, M. — Oregon's 5-year tsunami activity report (1997–2001) |
| R-18 | Crawford, G.L. — Tsunami inundation preparedness in coastal communities |
| R-19 | Walsh, T.J., et al. — Tsunami hazard map of the southern Washington coast: Modeled and inferred tsunami inundation from a Cascadia Subduction Zone earthquake |
| R-20 | Manson, C.J., and L. Walkling — TsuInfo, a tsunami information component of the National Tsunami Hazard Mitigation Program |
| R-21 | Jonientz-Trisler, C. — The Mitigation Strategic Implementation Plan: Toward tsunami-resistant communities |
| R-22 | Oppenheimer, D., et al. — The CREST Project: Consolidated reporting of earthquakes and tsunamis |
| R-23 | Sokolowski, T. — The U.S. West Coast and Alaska Tsunami Warning Center |
| R-24 | Meinig, C., et al. — System development and performance of the Deep-ocean Assessment and Reporting of Tsunamis (DART) system from 1997–2001 |
| 1-1 | Bernard, E.N. — Tsunami: Reduction Of Impacts through three Key Actions (TROIKA) |
| 1-2 | Gusiakov, V.K. — Basic Pacific tsunami catalog and database, 47 BC–2000 AD: Results of the first stage of the project |
| 1-3 | Priest, G.R. — Priority directions for research on tsunami hazard estimation: Cascadia Subduction Zone, Pacific Northwest coast of North America |
| 1-4 | Synolakis, C.E., et al. — The first generation of tsunami inundation maps for the State of California |
| 1-5 | Rabinovich, A.B., et al. — Tsunami risk estimation for the coasts of Peru and northern Chile |
| 1-6 | Downes, G.L., and M.W. Stirling — Groundwork for development of a probabilistic tsunami hazard model for New Zealand |
| 1-7 | Kaistrenko, V., et al. — A new paradigm of tsunami safety solution |
| 1-8 | Kawata, Y. — Disaster mitigation due to next Nankai earthquake tsunamis occurring in around 2035 |
| 1-9 | Legg, M.R., and J.C. Borrero — Tsunami potential of major restraining bends along submarine strike-slip faults |
| 1-10 | Stein, D., et al. — Reducing earthquake and tsunami hazards in Pacific Northwest ports and harbors—Protecting our Ports and Harbors Project |
| 1-11 | Kaistrenko, V., and T. Pinegina — A tsunami hazard parameter for Zhupanovo, Kamchatka calculated using historical and paleotsunami data |
| 1-12 | Long, D., and R. Holmes — Submarine landslides and tsunami threat to Scotland |
| 1-13 | Wood, N., and D. Stein — A GIS-based vulnerability assessment of Pacific Northwest ports and harbors to tsunami hazards |
| 2-1 | Okal, E.A., et al. — The Peruvian tsunami of 23 June 2001: Preliminary report by the International Tsunami Survey Team |
| 2-2 | Koshimura, S., and V.V. Titov — Preliminary model results for the 23 June 2001 Peruvian tsunami |
| 2-3 | Tappin, D.R., et al. — Offshore evidence on the source of the 1998 Papua New Guinea tsunami: A sediment slump |
| 2-4 | Titov, V.V., et al. — Re-evaluating source mechanisms for the 1998 Papua New Guinea tsunami using revised slump estimates and sedimentation modeling |
| 2-5 | Borrero, J.C. — Changing field data gives better model results: An example from Papua New Guinea |
| 2-6 | Okal, E.A., et al. — 1946 Aleutian tsunami field survey in the Marquesas |
| 2-7 | Dengler, L. — Impacts of the 2001 Peru Tsunami in Camana |
| 2-8 | Geist, E.L., et al. — Modeling the 23 June 2001 Peru local tsunami using results from a quick seismic inversion of the earthquake |
| 2-9 | Goring, Derek G., et al. — The response of New Zealand waters to the Peru tsunami of 23 June 2001 |
| 2-10 | Davies, H.L., et al. — Learning from the Aitape tsunami |
| 2-11 | Watts, P., et al. — Potential landslide tsunamis near Aitape, Papua New Guinea |
| 2-12 | Matsumoto, T., et al. — Shallow sediment structure and possible slope failure off the northern coast of Papua New Guinea |
| 2-13 | Gelfenbaum, G., et al. — Sedimentary deposits from the 17 July 1998 Papua New Guinea tsunami |
| 2-14 | Ortiz, M., et al. — Source areas of the Acapulco-San Marcos, Mexico earthquakes of 1962 (M 7.1; 7.0) and 1957 (M 7.7), as constrained by tsunami and uplift records |
| 3-1 | Goff, J.R., and B. McFadgen — Nationwide tsunami during prehistoric Maori occupation, New Zealand |
| 3-2 | Tsuji, Y., et al. — Geological traces of historical and pre-historical tsunamis in the lake bed layers of four lagoons on the south coast of Honshu Island, Japan |
| 3-3 | Peters, R., et al. — An overview of tsunami deposits along the Cascadia margin |
| 3-4 | López, G.I., and P.T. Bobrowsky — A 14,000 year old record from a coastal freshwater lake: Sedimentological evidence for tsunamigenic events on the west coast of Vancouver Island, British Columbia, Canada |
| 3-5 | Goldfinger, C., and P. Watts — Tsunamigenic mega-slides on the southern Oregon Cascadia Margin |
| 3-6 | Moore, A.L. — Grain-size trends in a Holocene tsunami deposit from Cultus Bay, Puget Sound, Washington |
| 3-7 | Neal, C.A., and C.F. Waythomas — Tsunami deposits from the 3500-bp caldera forming eruption of Aniakchak Volcano, Alaska |
| 3-8 | Shuto, N. — Tsunami-induced topographical change recorded in documents in Japan |
| 4-1 | Lander, J.F., and A. Mercado — U.S. Atlantic Coast tsunamis |
| 4-2 | Altinok, Y., et al. — Historical tsunamis in the Sea of Marmara |
| 4-3 | Alpar, B., et al. — Determination of probable underwater failures and modeling of tsunami propagation in the Sea of Marmara |
| 4-4 | Otay, E.N., and C. Melek Kazezyilmaz-Alhan — Earthquake generated water waves on uniformly sloping coasts |
| 4-5 | Tinti, S., and A. Piatanesi — Numerical simulations of the 8 September 1905 Calabrian tsunami (southern Italy) as a tool to improve the assessment of tsunami risk on the Calabrian coast |
| 4-6 | Yalciner, A.C., et al. — Field surveys and modeling of the 1999 Izmit tsunami |
| 4-7 | Mercado, A., and W. McCann — Evaluation of the tsunami hazard for eastern Hispaniola and western Puerto Rico in the Caribbean Sea region |
| 5-1 | Papadopoulos, G.A., and F. Imamura — A proposal for a new tsunami intensity scale |
| 5-2 | Curtis, G.D. — A multi-sensor research program to improve tsunami forecasting |
| 5-3 | Imamura, F., et al. — TIMING: Sanriku network for the exchange of tsunami information |
| 5-4 | Ohmachi, T., et al. — Seawater pressure induced by seismic ground motions and tsunamis |
| 5-5 | Abe, K. — Exclusion of a coastal effect from tsunamis recorded at ports in the use of the observed seiche |
| 5-6 | Rabinovich, A., et al. — Spectral and statistical analysis of the far-field and near-field records of the 1960 Chile tsunami |
| 5-7 | Lindquist, K., and R. Hansen — Modern approaches to the near-real-time seismic monitoring component of tsunami hazard mitigation |
| 5-8 | Matsuguchi, T., et al. — Use of FCI (Function Coded Image) in the tsunami database |
| 5-9 | Eble, M.C., et al. — Acquisition and quality assurance of DART data |
| 5-10 | Mofjeld, H.O., et al. — Seismic-wave contributions to bottom pressure fluctuations in the North Pacific—Implications for the DART Tsunami Array |
| 5-11 | Didenkulov, I.N., et al. — Hydroacoustic signal record analysis for the search of seismic emission radiation foregoing a bottom earthquake and tsunami occurrence in the Pacific |
| 5-12 | Kato, T., et al. — A new tsunami monitoring system using RTK-GPS |
| 5-13 | Utyakov, Lev.L., et al. — Project of effective tsunami warning system based on remote bottom pressure stations |
| 5-14 | Lazarev, V.E., and Lev.L. Utyakov — Autonomic bottom pressure stations for remote recording of tsunami waves |
| 6-1 | Iwasaki, S.-I. — Tsunamis due to solid slab landslides along the slope-theoretical solution |
| 6-2 | Lynett, P., et al. — Numerical modeling of tsunami generation by submarine landslide |
| 6-3 | Fine, I.V., et al. — Modeling of tsunami generation by submarine and subaerial landslides |
| 6-4 | Satake, K. — Tsunami modeling from submarine landslides |
| 6-5 | Tinti, S., and E. Bortolucci — Impact on Calabria and Sicily of a large tsunamigenic scenario collapse of Stromboli volcano |
| 6-6 | Fryer, G.J., and P. Watts — Motion of the Ugamak Slide, probable source of the tsunami of 1 April 1946 |
| 6-7 | Tinti, S., and E. Bortolucci — Computer simulation of the landslide-induced 1741 Oshima-Ohshima tsunami in the Japan Sea |
| 6-8 | Watts, P., and J.C. Borrero — Probability distributions of landslide tsunamis |
| 7-1 | Hebenstreit, G.T. — Tsunami science in the Information Age |
| 7-2 | Titov, V.V., et al. — Project SIFT (Short-term Inundation Forecasting for Tsunamis) |
| 7-3 | Ortiz, M., et al. — A fast preliminary estimation model for transoceanic tsunami propagation |
| 7-4 | Koike, N., and F. Imamura — Application of the inversion method to a real-time far-field tsunami forecast system |
| 7-5 | Geist, E.L. — Modeling the natural complexity of local tsunamis |
| 7-6 | Takahashi, T., and H. Yeh — Effects of coastal subsidence on tsunami run-up characteristics |
| 7-7 | Koshimura, S., et al. — Simulation of paleotsunamis in Puget Sound, Washington |
| 7-8 | Ohmachi, T., et al. — Tsunami simulation technique considering dynamic seabed displacement and acoustic effects of water |
| 7-9 | Hsu, T.-J., et al. — Numerical modeling of tsunami wave forces and overtopping on coastal structures |
| 7-10 | Mirchina, N., and E. Pelinovsky — Dispersive intensification of tsunami waves |
| 7-11 | Avdeev, A.V., et al. — Complex analysis of ocean tsunami observation data for solution of the inverse problem |
| 7-12 | Nosov, M.A., and S.N. Skachko — Non-linear mechanism of tsunami generation by bottom oscillations |
| 7-13 | Watts, P., et al. — Coupling of tsunami generation and propagation codes |
| 7-14 | Romanelli, F., et al. — Examples of tsunami synthesis: Excitation by offshore and coastal seismic sources |
| 7-15 | Pelinovsky, E., et al. — Numerical simulation of tsunami propagation near the French coast of the Mediterranean |
| 7-16 | Shevchenko, G.V., et al. — Investigation of long waves in the port of Kholmsk, Sakhalin Island |
| 7-17 | Takaoka, K., et al. — Possibility for transoceanic tsunami forecast by numerical simulation—Example of 1960 Chilean tsunami by numerical simulation |
| 7-18 | Koshimura, S., and H.O. Mofjeld — Inundation modeling of local tsunamis in Puget Sound, Washington, due to potential earthquakes |
| 7-19 | Holmes, M.L., and L. Dinkelman — Modeling paleotsunamis in Puget Sound, Washington |
| 7-20 | Chang, K.-T., and P.L.-F. Liu — Simulation of tsunamis and run-up along the eastern coast of Taiwan |
| 7-21 | Matsuyama, M., and H. Tanaka — An experimental study of the highest run-up height in the 1993 Hokkaido Nansei-oki earthquake tsunami |
| 7-22 | Fujima, K. — Long wave propagation on large roughness |
| 7-23 | Petroff, C.M., et al. — Particle advection by turbulent bores—Orientation effects |
| 7-24 | Kato, F., et al. — The grain-size effects on scour around a cylinder due to tsunami run-up |
| 7-25 | Teng, M.H., and K. Feng — Effect of beach roughness on tsunami run-up |
| 7-26 | Beikae, M. — A numerical technique for calculation of tsunami generation, propagation, and inundation of dry land |
| 7-27 | Marchuk, A.G., and A.A. Anisimov — A method for numerical modeling of tsunami run-up on the coast of an arbitrary profile |
| 7-28 | Mizutani, S., and F. Imamura — Dynamic wave force of tsunamis acting on a structure |
| 7-29 | Lynett, P., and P.L.-F. Liu — A simple moving boundary scheme for depth-integrated equation models |
| 7-30 | Preuss, J., and H. Yeh — Application of small-scale scenarios as a mitigation tool to reduce the effects of tsunami-structure interaction |
| 7-31 | González, F.I., et al. — The FACTS Project: First step toward a tsunami community modeling activity |
| 7-32 | Ballerini, M., and T.C. Kaplan — Coastal community risk from tsunami waves: Analysis of topographic influence on wave run-up using the 12 July 1993 Okushiri, Japan and the 12 December 1992 Flores Island, Indonesia tsunamis and computational and physical models |