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| Author | : United States. Congress. House. Committee on Science and Astronautics. Subcommittee on Aeronautics and Space Technology |
| Publisher | : |
| Total Pages | : 32 |
| Release | : 1974 |
| Genre | : Nuclear energy |
| ISBN | : |
| Author | : United States. Congress. House. Committee on Science and Astronautics. Subcommittee on Aeronautics and Space Technology |
| Publisher | : |
| Total Pages | : 88 |
| Release | : 1974 |
| Genre | : Nuclear energy |
| ISBN | : |
| Author | : The National Academies Keck Futures Initiative |
| Publisher | : National Academies Press |
| Total Pages | : 174 |
| Release | : 2014-05-22 |
| Genre | : Technology & Engineering |
| ISBN | : 0309300894 |
The National Academies Keck Futures Initiative (NAKFI) Conference in 2013 focused on the Future of Advanced Nuclear Technologies to generate new ideas about how to move nuclear technology forward while making the world safer and more secure. Beyond the public's apprehension concerning the safety of nuclear power, which calls out for better communications strategies, several challenges lie ahead for the nuclear enterprise in the United States. The workforce in nuclear technology is aging, there is an overreliance on large, high-risk reactor designs, and the supply of radioisotopes for nuclear medicine remains unstable-all problems crying out for solutions. The Future of Advanced Nuclear Technologies summarizes the 14 Interdisciplinary Research (IDR) teams' collaborations on creative solutions to challenges designed to propel the policy, engineering, and social aspects of the nuclear enterprise forward.
| Author | : United States. Congress. House. Science and Astronautics Committee |
| Publisher | : |
| Total Pages | : 82 |
| Release | : 1974 |
| Genre | : |
| ISBN | : |
| Author | : Mark Holt |
| Publisher | : |
| Total Pages | : 52 |
| Release | : 2019-04-27 |
| Genre | : |
| ISBN | : 9781096044116 |
An "advanced nuclear reactor" is defined in legislation enacted in 2018 as "a nuclear fission reactor with significant improvements over the most recent generation of nuclear fission reactors" or a reactor using nuclear fusion (P.L. 115-248). Such reactors include LWR designs that are far smaller than existing reactors, as well as concepts that would use different moderators, coolants, and types of fuel. Many of these advanced designs are considered to be small modular reactors (SMRs), which the Department of Energy (DOE) defines as reactors with electric generating capacity of 300 megawatts and below, in contrast to an average of about 1,000 megawatts for existing commercial reactors. Advanced reactors are often referred to as "Generation IV" nuclear technologies, with existing commercial reactors constituting "Generation III" or, for the most recently constructed reactors, "Generation III+." Major categories of advanced reactors include advanced water-cooled reactors, which would make safety, efficiency, and other improvements over existing commercial reactors; gas-cooled reactors, which could use graphite as a neutron moderator or have no moderator; liquid-metal-cooled reactors, which would be cooled by liquid sodium or other metals and have no moderator; molten salt reactors, which would use liquid fuel; and fusion reactors, which would release energy through the combination of light atomic nuclei rather than the splitting (fission) of heavy nuclei such as uranium. Most of these concepts have been studied since the dawn of the nuclear age, but relatively few, such as sodium-cooled reactors, have advanced to commercial scale demonstration, and such demonstrations in the United States took place decades ago. The 115th Congress enacted two bills to promote the development of advanced nuclear reactors. The first, the Nuclear Energy Innovation Capabilities Act of 2017 (NEICA), was signed into law in September 2018 (P.L. 115-248). It requires DOE to develop a versatile fast neutron test reactor that could help develop fuels and materials for advanced reactors and authorizes DOE national laboratories and other sites to host reactor testing and demonstration projects "to be proposed and funded, in whole or in part, by the private sector." The second, the Nuclear Energy Innovation and Modernization Act (NEIMA, P.L. 115-439), signed in January 2019, would require the Nuclear Regulatory Commission to develop an optional regulatory framework suitable for advanced nuclear technologies. The 115th Congress also appropriated $65 million for R&D to support development of the versatile test reactor in the Energy and Water Development Appropriations Act, FY2019, along with funding for ongoing advanced nuclear research and development programs (Division A of P.L. 115-244). Continued debate over advanced reactor issues is anticipated in the 116th Congress. A fundamental question may be the role of the federal government in advanced nuclear power development. DOE's budget request for FY2020 focuses the federal role on "early stage research" rather than the more expensive stages of demonstration and commercialization. Controversy is also likely to continue over the need for advanced nuclear power. Supporters contend that such technology will be crucial in reducing emissions of greenhouse gases and bringing carbon-free power to the majority of the world that currently has little access to electricity. However, some observers and interest groups have cast doubt on the potential safety, affordability, and sustainability of advanced reactors. Because many of these technologies are in the conceptual or design phases, the potential advantages of these systems have not yet been established on a commercial scale. Concern has also been raised about the weapons-proliferation risks posed by the potential use of plutonium-based fuel by some advanced reactor technologies.
| Author | : United States. Congress. House. Committee on Science and Astronautics. Subcommittee on Aeronautics and Space Technology |
| Publisher | : |
| Total Pages | : 80 |
| Release | : 1974 |
| Genre | : Nuclear energy |
| ISBN | : |
| Author | : J. V. Lolich |
| Publisher | : |
| Total Pages | : 5 |
| Release | : 2004 |
| Genre | : |
| ISBN | : |
This report describes technical modifications implemented by INVAP to improve the safety of the Research Reactors the company designs and builds.
| Author | : Michael Kuca |
| Publisher | : |
| Total Pages | : 126 |
| Release | : 2014 |
| Genre | : Nuclear energy |
| ISBN | : |
This project began as an examination of small and mini nuclear power plants as an emergent energy technology capable of sustained base-load power generation in northern climates. Literature review immediately demonstrated Alaska should remain current on small and mini nuclear power plants because commercial vendors are promoting their products to state leaders as certain solutions. Is Alaska prepared to receive, operate, and decommission advanced nuclear technology as an alternative to traditional hydrocarbon power plants? The graduate committee encouraged me to facilitate discussions with Alaska Center for Energy and Power (ACEP) leadership in reference to their 2010 study on small modular reactors. Gwen Holdman, Brent Sheets, and George Roe offered great encouragement for this project and allowed me to participated in nuclear related meetings with affiliates. In fall 2013, ACEP was hosting Idaho National Laboratory guests to discuss areas of common research interest. I was invited to prepare a short presentation of this project to Dr. Steven Aumeier, Director of Center for Advanced Energy Studies and Michael Hagood, Director of Program Development. ACEP and INL later determined a mobile mini reactor design for remote terrestrial deployment represents common research interests, and INL funded three UAF student fellowships at the Center for Space Nuclear Research (CSNR) Dr. Stephen Howe, Director of CSNR, allocated a team of six graduate fellows to explore terrestrial applications of a tungsten fuel matrix currently under design for nuclear thermal propulsion. UAF students selected for CSNR fellowship included Haley McIntyre, Alana Vilagi, and me. The team designed a Passively Operating Lead Arctic Reactor (POLAR), presented the POLAR design to INL staff and industry leaders and a subsequent poster was provided for the INE conference for Alaska Energy Leaders in October 2014. In addition to exceptional engineering experience, I was able to advance the graduate project in areas of technology, policy, economics, and energy infrastructure requirements needed to accept advanced nuclear technology. Concurrently, under a memorandum of agreement between the University of Alaska and Alaska Command ALCOM, I was able to advance the project to consider military applications of small modular reactors with ALCOM Energy Steering Group. It was in this context where I evaluated military installation energy usage in interior Alaska as compared to production of integral pressurized water reactors likely to emerge first in the commercial sector, and the ability of Alaska military to adopt this technology. As a side project, select courses of action were prepared and briefed to the commanding general of ALCOM should the nuclear option become attractive to the military. What began as an independent examination of small and mini nuclear power plants to satisfy a three-credit project requirement became an incredible collaboration among civilian, state, university, military, and industrial shareholders of the Alaska energy sector. Specific recognition for this report belongs to Haley McIntyre for her contribution to policy frameworks and as editor for this report, and Alana Vilagi for her contribution to process heat applications. The graduate committee along with ACEP leadership, INL-CSNR, and ALCOM should all be recognized as facilitators in this review of nuclear power in Alaska. The following report is presented in six chapters. The first two chapters attempt to introduce the reader to the current state of commercial nuclear energy in the nation as a pretext to developing the advanced reactor designs. Modifications to the existing framework are provided and the total cost of nuclear in Alaska is considered as opportunities and barriers to deployment are evaluated. As a conclusion, scenarios are developed to explain how this technology may contribute to our energy sector in the future. This project was unfunded, and its findings are intended to present a neutral examination of emergent nuclear design in the Alaska energy sector.
| Author | : United States. Congress. House. Committee on Science and Technology. Subcommittee on Energy Research and Production |
| Publisher | : |
| Total Pages | : 106 |
| Release | : 1986 |
| Genre | : Nuclear reactors |
| ISBN | : |
| Author | : |
| Publisher | : |
| Total Pages | : 12 |
| Release | : 1962 |
| Genre | : Nuclear rockets |
| ISBN | : |
