XYLENE POWER LTD.

NUCLEAR ENERGY

TABLE OF CONTENTS

By Charles Rhodes, P.Eng., Ph.D.

There are two methods of producing nuclear energy, fission and fusion. Both methods are explored on this web site.

The sun is powered by fusion so renewable energy is actually fusion energy. However, renewable energy is intermittent. Renewable electricity generators require efficient daily and seasonal energy storage and long distance transmission to provide uninterruptible electric power. Frequently the cost of making renewable electricity uninterruptible is prohibitive. It is often more practical to price electricity at uninterruptible and interruptible rates so that applications that require uninterruptible electricity pay more per blended kWh than applications that operate using only interruptible electricity.

Advances in nuclear fission technology have rendered obsolete past concerns about nuclear safety, nuclear fuel usage inefficiency and nuclear waste disposal.

Other than via renewable energy, fusion based electricity generation is difficult and expensive to realize on Earth. For fundamental physical and thermodynamic reasons, as long as fission fuel is available, the cost of a kWhe from Earth based fusion will always be several times the cost of a kWhe from Earth based fission. The economic opportunity for Earth based fusion, if any, is for enhancing breeding of start fuel for fast neutron fission reactors.
 

NUCLEAR MOTIVATION
1. Nuclear Motivation	2. Nuclear Technologies
3. Sustainable Nuclear Power	4. Modular Reactors
5.Electricity Generation Reactors	6. Reactor Design Constraints
NUCLEAR FISSION
1. CANDU Reactors	2. Fast Neutron Reactors
3. Molten Salt Reactors	4. FNR Safety
5. FNR Siting	6. FNR Initial Fuel Sources
7. Ottensmeyer Plan	8. Ottensmeyer Plan Detail
9. FNR Material Recycling	10. Non-Proliferation
11. FNR Specifications	12. FNR Design
13. FNR Mathematical Model	14. FNR Fuel Rods
15. FNR Fuel Tubes	16. FNR Fuel Tube Wear
17. FNR Fuel Bundle	18. FNR Primary Liquid Sodium Flow
19. FNR Heat Exchange Tubes	20. FNR Safety Analysis
21. FNR Control	22.
NUCLEAR WASTE
1. Ottensmeyer Plan Implementation	2.
3. Radiation Safety	4. Nuclear Waste Categories
5. Nuclear Waste Disposal	6. Helium-3 Recovery
7. NWMO / OPG	8. Nuclear Waste Dry Storage
9. Nuclear Waste Containers	10. Porcelain
11. Nuclear Waste Container Seals	12. Seepage
13. DGR Ventilation	14. Jersey Emerald
15. DGR Closing Remarks	16. Nuclear Waste Disposal Press Release
17. Nuclear Education	18. Presentation Notes
19. Pickering Advanced Recycle Complex (PARC)	20. Letter To Federal Political Leaders
21. Letter to Minister of Environment and Climate Change, Ontario	22. Letter to Mininster of Environment and Climate Change, Canada
23. U of T 17-02-09 Slide Presentation	24. U of T Presentation
NUCLEAR FUSION
Fusion section is currently being reconstructed. Please examine this section at a later date.
1. PIF Glossary	2. Nuclear Fusion Prospect
3. Plasma Impact Fusion	4. Nuclear Fusion Engineering Considerations
5. D-T Fusion Fuel	6. Spherical Compression Part A
7. Adiabatic Compression	8. Fusion Output
9. Liquid Lead Constraints	10. Spherical Compression Part B
11. Random Plasma Properties	12. PIF Process
13. Liquid Lead Shell Formation	14. Pressure Vessel
15. Port Valves	16. Process Timing
17. Tritium Breeding	18.
19. Spheromak Compression	20. Real Plasma Spheromaks
21. Spheromak Generator	22. Plasma Spheromak Lifetime
23. Vacuum Pumping Constraints	24. Liquid Lead Pumping
MICRO FUSION
1. Micro Fusion Introduction	2. Micro Fusion FAQ
3. Micro Fusion Energy Flows	4. Micro Fusion Economics
5. Micro Fusion Regulatory Hurdles	6. Alumina Cylinder
7. Micro Fusion International

It is the intent of this author to eventually produce web pages addressing all of the above mentioned topics.

This web page last updated February 9, 2017.