CFRL News No. 39 (2002. 8. 20)
Cold Fusion Research Laboratory (Japan) Dr. Hideo Kozima, Director
E-mail address; cf-lab.kozima@pdx.edu
Websites; http://web.pdx.edu/~pdx00210/
CFRL News No. 39 をお送りします。
この号では、次の記事を掲載しました。
1) ICENES 2002 のプログラム
2) ICENES 2002 で発表予定の論文
1) ICENES 2002 のプログラム
ICENES
2002のプログラム(暫定)が参加者に送られてきました。主題はプラズマ核融合ですが、常温核融合にも目配りしたいという意図がはっきり表れたプログラムで、CFP関係の論文も10編ばかり収められています。全体のプログラムは下記ウェブサイトに掲載されるようです。
http://www.unm.edu/~isd/icenes/icenes.htm
CFP関連の論文は10月1日(午前、1編), 10月2日(午前、1編) および10月3日 (午後、数編) とポスター(9月30日– 10月3日、数編).に発表されます。
INENESからのe-メールの前文とCFP関係の部分に重点を置いて抜粋したプログラムとを掲載します。
11th International Conference on Emerging Nuclear
Energy Systems
Sheraton Old Town Hotel
Albuquerque, New Mexico, USA
29 September ‑ 4 October 2002
Greetings:
We are pleased to welcome everyone to the 11th
International Conference on Emerging Nuclear Energy Systems. The objective of the
conference is to discuss, on a broad international basis, the state of various
advanced and non‑conventional concepts for nuclear energy production. The results
of' developments to be discussed could contribute to the sustainability of' future
energy production. This open public forum brings together international leaders
in government, industry, and academe for discussions. The oral and poster
presentations will be included in the ICENES 2002 Proceedings, which will be compiled, edited, bound, and distributed
following the conference.
We
are grateful for the support of the sponsors and encourage everyone to
acknowledge their contribution to the success of the conference: UNM Office of'
the Vice Provost for Research; UNM Chemical & Nuclear Engineering; Sandia
National Laboratories; Lawrence Livermore National Laboratory; and Los Alamos
National Laboratory.
We
appreciate the time and dedication of the speakers and presenters in preparing
their presentations and papers for publication in the ICENES 2002 Proceedings.
We
welcome you to our 11th conference on these critical topics.
Sincerely,
International Chair Jose Martinez‑Val
Program Chair Thomas
A. Melhorn
ICENES 2002: Program
SUNDAY, SEPT. 29
6:00 – 7:30 Welcome Reception (Fireplace Room)
MONDAY, SEPT. 30
8:00 WELCOME T.A. Melhorn, J.M.
Martinez-Val,
8:10 KEYNOTE A.D. Romig
8:35-12:00 ADVANCED FISSION
MODERATOR V.H. Reis
9:45-10:00 BREAK
12:00-12:45 LUNCH
12:45-5:00 ACCELERATOR-DRIVEN SYSTEMS
MODERATOR C.D. Bowman
7:30 Continental Breakfast
8:00 ‑ 11:45 NUCLEAR WASTE
MODERATOR: Alan Baxter, General Atomics, USA.
8:00 V1adimir Novikov,
International
Institute for Applied Systems Analysis, AUSTRIA
Stigma of the GLOBAL Nuclear Legacy and its Impact
on the Likelihood of Success of the Nuclear
8:30 J. Dash, Low
Energy Nuclear Laboratory, Port land
State University, USA
Effects of Hydrogen Isotopes on Radioactivity of Uranium
9:00 A. Tonchev, Triangle
Universities Nuclear Laboratory,
Duke University, USA
Measurement of
Benchmark Nuclear Data for Thermal
Spectrum Transmuter Design
9:30 N. Shubin, Institute of Physics and Power
Engineering, RUSSIA
Neutron Cross Section
Evaluations for Actinides at Intermediate
Energies 239Pu
10:00 ‑ 10:15 BREAK
11:45-12:30 LUNCH
12:30-4:15 FUSION ENERGY I
MODERATOR M. Piera, Institute of Nuclear Fusion,
Spain
2:45-3:00 BREAK
4:00-5:00 TOUR of the
Albuquerque Museum
5:00-6:00 RECEPTION & No-host
Bar (foyer)
6:00-9:00 BANQUET (Outdoor
Sculpture Garden) –New Mexican Buffet
WEDNESDAY, OCT. 2
7:30 Continental Breakfast
8:00-10:15 FUSION ENERGY II
MODERATOR: john S. DeGroot, Dept. of
Applied Science, University of California – Davis, USA
9:30 ‑ 9:45 BREAK
9:45 Hideo Kozima, Physics
Department, Portland State University, USA
The Cold Fusion Phenomenon and Its Application
to Energy Production and Nuclear Waste Remediation
10:15‑12:00 PIC & HYBRID/PIC MODELING WORKSHOP
MODERATOR: Thomas A.
Melhorn, Sandia National Laboratories, USA
12:00 ‑ 12:45 LUNCH
12:45‑ 4:30 PIC WORKSHOP (conclusion)
2:45 ‑ 3:00 BREAK
4:00 ‑ 5:00 IPCC TOUR (or free
time)‑ not firm yet
THURSDAY, OCT. 3
7:30
Continental Breakfast
8:00 ‑11:15 SPACE NUCLEAR POWER & PROPULSION
MODERATOR:
Steve A. Slutz, Sandia National Laboratories, USA.
9:30 ‑ 9:45 BREAK
11:15 ‑12:00 LUNCH
12:00 ‑ 3:45 APPLICATIONS
MODERATOR:
Paul McKenna, University of Strathclyde in Glasgow, SCOTLAND
12:00 Paul McKenna
(presenter), Royal
Society of Edinburgh Fellow,
University of Strathclyde in Glasgow, SCOTLAND
Laser‑Induced Nuclear
Physics and Applications
12:30 G.H. Miley; Dept. of Nuclear, Plasma, and Radiological Engineering, University of
Illinois, Urbana‑Champaign, USA
Low Energy Reaction Cell for Portable Power
1:00 Takaaki
Matsumoto, Department
of Nuclear Engineering, Hokkaido University, JAPAN
Electro‑Nuclear
Collapse and its Potential Applications
1:30 Xavier Dufour, Laboratoire des Sciences Nucleaire
CNAM, FRANCE
Exothermal Effect by
Passing a DC Current Through a Composite Conductor. Possible Nuclear
Explanation
2:00 Xi Z Li Department of Physics, Tsinghua University,
CHINA
Nuclear Science in
Condensed Matter: Nuclear Energy Without Strong Nuclear Radiation
2:30 ‑ 2:45 BREAK
2:45 Alexander B.
Karabut Scientific
Industrial Association "Luch", Russian Federation
Research Into Powerful
Solid X‑Ray Laser (Wavelength is 0. 8 ‑ 1.2 nm) with Excitation of High Current Glow Discharge Ions
3:15 George H. Miley Dept. of Nuclear, Plasma, and
Radiological Engineering, University of Illinois, Urbana‑Champaign, USA
Theory of X‑ray Laser Emission from Highly Loaded Hydrides
3:45 ‑ 4:30 CLOSING REMARKS
Thomas A. Melhorn, Program Chair
Jose M. Martinez‑Val, International Chair
Introduction to ICENES 2005:
Hamid Ait Abderrahim, SCK‑CEN, Reactor Physics &
MYRRHA Dept., BELGIUM
SEPT. 30 ‑ OCT. & POSTERS
Mary E. White, ATR Institute, University of New
Mexico, USA
Building Stakeholder
Relations in Support of Emergency Preparedness and Response
Fulvio Frisone, Department of Physics, University of Catania,
ITALY
Theoretical Analysis of the Cold E7usion Process
Scott M. Sepke, FOCUS Center, Nuclear Engineering Dept.,
University of Michigan, USA
Electron Motion and Thomson Scattering of Interfering Counter Propagating High‑Intensity Laser Beams
Eiichi Nishimura, Ministry of Economy, Trade and Industry, JAPAN
Concept Design of a New Liquid Metal Target Station
for Accelerator Driven Systems
Y. Nakao, 202 NSC, University of Florida, USA
Fokker‑Planck Modelling of Core Plasma Heating by Relativistic Electrons
Alexander B. Karabut, Scientific Industrial Association
"Luch", Russian Federation
Experimental Registration of a High Current Glow Discharge of the Excited Long Living Atomic
Levels with the Energy of 1‑3 keV and Nuclear Products
Emission in the Solid Medium
2) ICENES 2002 で発表予定の論文
この国際会議にPSUから発表予定の論文とそのAbstractを掲載します。上のプログラムにあるように、論文(1)は10月2日の9:45分から、論文(2)は10月1日の8:30分から発表される予定です。
(1) H. Kozima, “The Cold Fusion Phenomenon and Its
Application to Energy Production and Nuclear Waste Remediation”
(2) J. Dash, I. Savvatimova, G. Goddard, S. Frantz, E. Weis and H. Kozima, “Effects of Hydrogen Isotope on Radioactivity of Uranium”
[Abstract 1]
“The Cold Fusion Phenomenon and Its Application to Energy Production and Nuclear Waste Remediation”
The Cold Fusion Phenomenon (CFP) is concerned with nuclear reactions and accompanying events occurring in solids with high densities of hydrogen isotopes in ambient radiation.
1. Necessary conditions for the CFP
Necessary and sufficient conditions for CFP are not fully determined yet. Some necessary conditions are deduced from existing experimental data sets;
1-1. Transition metals: Pd, Ni, Ti, Mo, . . . . =. M. It is necessary to use transition metals in which hydrogen isotopes are occluded to form transition-metal hydrides or/and deuterides.
1-2. Hydrogen isotopes: H, D, (T) = H. Hydrogen isotopes to be occluded in these transition metals are protium or/and deuterium (and probably tritium).
1-3. For positive CFP results a minimum amount of occluded hydrogen isotopes is required. The minimum amount of the occluded hydrogen isotopes expressed by the ratio of atoms is H/M]_{min} » 0.7.
1-4. Existence of background thermal neutrons. There are no positive results without background neutrons. Positive effects also occur when a source of thermal neutron is imposed during cold fusion experiments.
This list shows that we should not confine our theoretical investigation to D + D fusion reactions if we want to explain whole data sets consistently.
The CFP is characterized by following characteristics;
2-1. Qualitative reproducibility. The CFP occurs with qualitative reproducibility, i.e. the same macroscopic initial condition causes quantitatively different effects from zero to a maximum.
2-2. Sporadic and intermittent occurrence. The CFP occurs sporadically and intermittently without expectation.
2-3. Localized reactions. From experimental data, we know reactions responsible for CFP mainly occur in surface layers of thickness about 1 micron. There is evidence for hot spots where surface topography is drastically changed.
2-4. Optimum combinations of [transition metal] - [hydrogen isotopes] – [electrolyte]. It seems that there are optimum combinations of transition metals with occluded hydrogen isotopes and electrolytes used in the experiments.
2-5. Variety of elements produced by nuclear transmutation (NT) are accompanied by excess heat Q; The products include transmuted nuclei with mass numbers larger than 5, ^{4}He (=He4), tritium (T), neutrons (n), gamma, X-rays, .
2-6. Nuclear transmutations (NT’s) producing nuclides with mass number larger than 5 are classified in three groups; a) NT_{D}, b) NT_{F} and c) NT_{A} explained by decay after, fission after and simple absorptions, respectively, of clusters of neutrons and protons by nuclei in the material used in the experiments.
2-7. Definite relations between amounts of these products N_{Q}, N_{NT}, N_{He4}, N_{T}, N_{n}, and N_{gamma};
N_{Q} » N_{NT} » N_{He4} » N_{T} » 10^{7} N_{n}.
3. Explanation of the Experimental Data
Sets.
A unified and systematic explanation for the CFP in the framework of modern physics, therefore, should be given. Catalysis by neutral particles provides a mechanism to avoid Coulomb barrier between charged particles. In this way nuclear reactions induce nuclear transmutations which are observed as explained above in 2-5, 2-6 and 2-7. A successful explanation of many experimental data sets by a model (TNCF model) and quantum mechanical verification of the premises assumed in the TNCF model by the present author will be presented. Key elements of the explanation are neutron bands in solids and neutron drops made of large number of neutrons and a few protons and electrons. This model was developed by the author over the past several years as seen in the References of this abstract below.
4. Applications
On the basis of these experimental facts and theoretical investigations, we will discuss possible applications of CFP for energy production and nuclear waste remediation. Using appropriate metal and hydrogen isotopes, we can control nuclear reactions in solids effectively producing excess heat and nuclear products. The same principle is used for remediation of hazardous nuclear waste transmuting them into non-radioactive nuclides.
5. References
5-1 H. Kozima, Discovery of the Cold Fusion Phenomenon ‑ Evolution of the, Solid State ‑ Nuclear Physics and the Energy Crisis in 21st Century, Ohtake Shuppan KK., Tokyo, Japan, 1998.
5-2 H. Kozima, K. Kaki and M. Ohta, "Anomalous
Phenomenon in Solids Described by the TNCF Model", Fusion Technology 33, 52 (1998).
5-3 H.
Kozima, "Neutron Band in Solids", J. Phys. Soc. Japan 67, 3310 (1998).
5-3 H. Kozima, K. Arai, M. Fujii, H. Kudoh, K.
Yoshimoto and K. Kaki, "Nuclear Reactions in Surface Layers of Deuterium‑Loaded
Solids" Fusion Technol. 36, 337 (1999).
5-4 H.
Kozima, "Neutron Drop: Condensation of Neutrons in Metal Hydrides and
Deuterides", Fusion Technol. 37, 253 (2000).
5-5 H.
Kozima, M. Ohta, M. Fujii, K. Arai and H. Kudoh, “Possible Explanation of
^{4}He Production in a Pd/D_{2} System by the TNCF Model” Fusion Science and
Technology 40, 86 (2001).
5-6 H. Kozima, “Neutron Bands made of Excited Neutron States of Nuclei on the Lattice Points of Transition-metal Hydrides” Phys. Rev. Lett. (Submitted.)
[Abstract 2]
“Effects of Hydrogen Isotope on Radioactivity of Uranium”
Uranium foils were attached to the cathode of a glow discharge apparatus. A plasma of either hydrogen or deuterium was used to bombard the uranium. The rates of alpha, beta, and gamma emissions were significantly greater for the bombarded uranium than for the original material. These results are in agreement with results obtained on uranium co-deposited with hydrogen by electroplating.