1. The Peculiar Energy Machine of Jasper James
Moray B. King

2. Intro What is it? How did I hear of it? Can we explain it?
Is it tapping ZPE?

3. US Patent 4,368,416 Jasper Lewis James
Filed: Feb Issued: Jan 1983
Inventor Died: Nov 1979

4. Thermionic-Thermoelectric Generator System and Apparatus
US Patent 4,368,416
4 inches
22 inches
Output: 20 KW pulsed DC, 400 Hz
Temperature: degrees C

5. My Story

6. My Story March 2001, Tip from professor Disclosure
Government projects benefit society

7. My Story March 2001, Tip from professor Disclosure
Government projects benefit society
September 11, Stopped!

8. My Story July 2009, Tesla Tech Conference Dr. George Freibott, M.D.
President American Naturopathic Association
20 years

9. My Story July 2009, Tesla Tech Conference Dr. George Freibott, M.D.
President American Naturopathic Association
20 years
James Device used in small nuclear reactors

10. Back Story

11. Back Story
Thank You
Ryan Wood!

12. Back Story Jasper “Lew” James Born: Aug 4, 1917
B17 pilot in World War II
Died: Nov 21, Knoxville, TN
No Autopsy
Never married

13. Back Story Jasper “Lew” James Founder: Weldynamics Inc. 1973
James Laboratories, Inc Sep 1978
Greenville, TN
Vice President
President: James I. Dye
Attorney: Morgan C. Fitch
Development Leader: Dewey Franklin
On board of directors: David Love

14. Cylindrical Evacuated Tube
Hot
~425 degrees C ~800 degrees F
Negative Contact -
“Snout” Outside
Positive Contact +
Jasper James, US 4,368,416

15. Two Concentric Cylinders
Stainless Steel Surfaces Coated
Anode +
16 x 3 inches
Cathode –
22 x 4 inches

16. Connection Terminals Jasper James, US 4,368,416 Negative - Positive +
To Inner Cylinder Anode +
To Outer Cylinder Cathode -

17. Thermopile Inside Anode
Jasper James, US 4,368,416
Alternating Wafers
Silicon Carbide & Carbon
SiC C

18. Assembly Tube: Concentric Cylinders Thermopile: Stack of Wafers
SiC
SiC – Silicon Carbide
Anode +
Cathode -
C – Carbon C

19. Thermopile “Explanation?”
Jasper James, US 4,368,416
Silicon Carbide & Carbon
Junction
SiC +
C -
Electron Donor
Electron Acceptor
Stacking Wafers Sum Voltages !?

20. Thermopile 4 Stacks Jasper James, US 4,368,416 Tungsten Strips SiC +
380 Wafers per stack
Stacks Connected in Series
1520 Wafers

21. Ceramic Thermopile Holder
Inner Cylinder Anode +
Jasper James, US 4,368,416

22. Thermoelectric Semiconductor Pile
Thermionic Tube
Thermoelectric Semiconductor Pile
SiC +
SiC – Silicon Carbide
Anode +
Cathode -
C – Carbon
C -

23. Thermionic Tube Backward
James
Standard
Gap ~cm
Gap ~mm
Cathode Outside
Cathode Inside
Anode Cool
Anode Inside
Cool Anode?
Heating Filament

24. Tube Electrode Surfaces
Anode: Graphite
Cathode Mixture:
Barium Oxide
Calcium Oxide
Strontium Oxide

25. Thermionic Tube? Backward! What cools anode? Gap too big
What causes tube to fire?

26. Thermoelectric Wafer Stack High Voltage Fires Tube
SiC +
SiC – Silicon Carbide
Anode +
Cathode -
C – Carbon
C -

27. Thermoelectric Voltage
Silicon Carbide & Carbon
Junction
SiC +
C -
Electron Donor
Electron Acceptor
Contact Potential ~0.4 volts
Sum of 1520 wafers manifest ~600 volts?!

28. Does Stacking Wafers Sum Voltages?
SiC C
SiC

29. Does Stacking Wafers Sum Voltages?
SiC + - C - +
SiC
Polarity Alternates

30. Does Stacking Wafers Sum Voltages?
SiC + - C - +
SiC
Polarity Alternates
No! If static at equilibrium

31. Wafer Stack Must Manifest High Voltage Pulse Event

32. Wafer Stack Must Manifest High Voltage Pulse Event
How?

33. SiC C Wafer Stack
Low Temperature
High Temperature
Insulator
Conductor

34. Silicon Carbide Semiconductor Bands Electron Energy Level Conduction
Gap
Valence
Low Temperature
High Temperature

35. No Voltage Polarization at Either Extreme
Low Temperature
High Temperature
Electrons in Conduction Band
Smeared Cloud in Equilibrium
Electrons in Valence Band
No Motion
Insulator
Conductor

36. Wafer Stack Transition
No Electron Mobility  Complete Mobility
Semiconductor
Heats Grows Electron Cloud

37. Wafer Stack Transition
No Electron Mobility  Complete Mobility
Semiconductor
Avalanche Discharge

38. Avalanche Discharge Fires the Tube
SiC +
Anode +
Cathode -
C -

39. Pulsed Flywheel Circuit
Anode
Cathode +
Wafer Stack -
Electron Movement

40. Trigger the Discharge!

41. Trigger the Discharge!
How?

42. Switching Circuit Tube Capacitor Load Capacitor Tube
Jasper James, US 4,368,416

43. Switching Circuit Tube Capacitor Load Capacitor Tube
Jasper James, US 4,368,416

44. Switching Circuit Section
Load
Transistor Switch
Capacitor
SCR Switch
Tube

45. Switching Illustrated
Tube
Capacitor
Load + -

46. Charge Capacitor
Tube
Capacitor
Load + -

47. Isolate Capacitor
Tube
Capacitor
Load + - + -

48. Discharge Capacitor
Tube
Capacitor
Load + -

49. Isolate Capacitor
Tube
Capacitor
Load + -

50. Control Switching Tube Capacitor Load Capacitor Tube
Jasper James, US 4,368,416

51. Circuit Components
Jasper James, US 4,368,416

52. Switching Triggers Avalanche
Drives Flywheel Circuit
Anode + -
Capacitor
Cathode
Pulsed Electron Movement

53. Two Capacitors - + Charged C1 V0 C2 Uncharged Initial Energy = ½ C1V0

54. Closing Switch Triggers Current Spike- + C1 C2 Vf
Final Energy = ½ C1Vf + ½ C2Vf 2

55. Switching Event Fires the Tube
SiC +
Anode +
Cathode -
C -

56. Energy Transfer

57. Energy Transfer
Heat creates conduction band electrons

58. Energy Transfer Heat creates conduction band electrons
Conduction band electrons exit stack

59. Energy Transfer Heat creates conduction band electrons
Conduction band electrons exit stack
Electrons from cap enter valance band !?

60. Energy Transfer Heat creates conduction band electrons
Conduction band electrons exit stack
Electrons from cap enter valance band !?
Capacitor charged: E = ½ CV2

61. Energy Transfer Heat creates conduction band electrons
Conduction band electrons exit stack
Electrons from cap enter valance band !?
Capacitor charged: E = ½ CV2
Heat energy exits stack

62. Energy Transfer Heat creates conduction band electrons
Conduction band electrons exit stack
Electrons from cap enter valance band !?
Capacitor charged: E = ½ CV2
Heat energy exits stack
Stack cools

63. Torus Heat Flux
Heat Energy Exits through Snout

64. Actual Embodiment Two Tubes Thermopile: 1520 Wafers per Tube
400 – 450 degrees C
Alternating Output Capacitors
Switching 400 Hz
Output: 200 Amps 108 Volts

65. Standard Theory

66. Thermionic Tube

67. Thermoelectric Generator
Thermal Flux
Electric Elements in Series

68. Heat Pump Heat Transfer Electric Elements in Series

69. Peltier Cooler

70. Standard Thermionic / Thermoelectric

71. Standard Thermionic / Thermoelectric
Direct Current (DC)

72. Standard Thermionic / Thermoelectric
Direct Current (DC)
Near Constant Voltage

73. Standard Thermionic / Thermoelectric
Direct Current (DC)
Near Constant Voltage
Heat Difference

74. Standard Thermionic / Thermoelectric
Direct Current (DC)
Near Constant Voltage
Heat Difference
Thermodynamic Equilibrium

75. SiC Conductivity Increases with Temperature
Google Images: “SiC foam” “electrical conductivity”

76. Band Model At Equilibrium

77. Intrinsic Semiconductor
Electron Concentration = Hole Concentration

78. Band Theory

79. Band Theory
Approximation

80. Band Theory
Approximation
Great at Thermodynamic Equilibrium

81. Band Theory Approximation Great at Thermodynamic Equilibrium
Inaccurate

82. Band Theory Approximation Great at Thermodynamic Equilibrium
Inaccurate
Surface Irregularities

83. Band Theory Approximation Great at Thermodynamic Equilibrium
Inaccurate
Surface Irregularities
Hot Spots

84. Band Theory Approximation Great at Thermodynamic Equilibrium
Inaccurate
Surface Irregularities
Hot Spots
Abrupt Pulse/Spike Events

85. Metal – Semiconductor Junction
Can pulse event drive
Low energy electrons into valence holes?

86. SiC Conductivity
“Switches” with Temperature
Off
Allows Turn On

87. Negative Resistance

88. Negative Resistance Energy from somewhere Snap back Hysteresis?
Stored
ZPE?
Snap back
Hysteresis?
Avalanche

89. Avalanche Breakdown

90. Gas Ionization Avalanche
By Dougsim - Own work, CC BY-SA 3.0,

91. Thyristor Silicon Controlled Rectifier (SCR)

92. Thyristor Two Transistor Analogy

93. Thyristor I-V Curve

94. Thyristor Behavior Spontaneous Trigger

95. Thyristor Behavior Spontaneous Trigger Reverse over-voltage

96. Thyristor Behavior Spontaneous Trigger Reverse over-voltage
High Temperature

97. Thyristor Behavior Spontaneous Trigger Reverse over-voltage
High Temperature
Rapid rising dv/dt: Voltage Spike

98. Nonlinear Thermodynamics
Ilya Prigogine
1977 Nobel Prize in Chemistry
Explains system self-organization

99. Required for Self-Organization
Nonlinear System
Far from Equilibrium
Energy Flux

100. Rectify RF Noise
Capacitor
Load
Antenna
Ground
Diode

101. Discharge Capacitor
Antenna
Diode
Ground
Capacitor
Load

102. ZPE Coupling?

103. Energetic Vacuum
E t > h
Uncertainty Principle
Pair Production

104. Zero Point Spectrum
Energy Density r
hw3
r =
2p2c3
Frequency w

105. Vacuum Catastrophe Nassim Haramein

106. Vacuum Catastrophe PBS Space Time

107. ZPE - Turbulent Virtual Plasma
“Quantum Foam”
Electric flux enters and leaves our 3D space through mini virtual particles that constantly appear and disappear.

108. Hyperspace Flux Flatland Slot Polarized Vacuum Elementary Particle
Incoherent Fluctuations
Polarized Vacuum
Elementary Particle

109. From Vacuum Fluctuations
Pair Production
The turbulence of the vacuum energy manifests self-organization. A churning production of electron-positron pairs appear and disappear on a rapid time scale in the turbulence of the vacuum fluctuations. Quantum electrodynamics describe them as “virtual” particles because their lifetimes are so short. The activity is the foundation of quantum electrodynamics with all elementary particles intertwined with the vacuum fluctuations.
Electron Positron
From Vacuum Fluctuations
109

110. Everything Emerges from Collectives
2005

111. Zero-Point Energy: Basis
Quantum Effects – Boyer, Phys. Rev. D 11(4), 2832 (1975).
Hydrogen Atom – Puthoff, Phys. Rev. D 35(10), 3266 (1987).
Energy Source – Cole, Puthoff, Phys. Rev. E 48(2), 1562 (1993).
Gravity – Puthoff, Phys. Rev. A 39(5), 2333 (1989).
Inertia – Haisch, Puthoff, Rueda, Phys. Rev. A 49(2), 678 (1994).

112. Principles for Cohering Zero-Point Energy
Highly Nonlinear System
Abruptly Drive Far From Equilibrium
Maximize ZPE Interaction Using
Ions
Vortex Forms

113. Discharge Tubes

114. Paulo & Alexandra Correa

115. Correa Tube
Anode
Cathode
Glow Buildup

116. Correa Tube
Anode
Cathode
Discharge

117. Correa Tube

118. Pulsed Abnormal Glow Discharge
Negative Resistance

119. Pulsed Abnormal Glow Discharge
Negative Resistance
Quench Arc!

120. PAGD Circuit
Correa, US 5,416,391 and 5,449,989 (1995)

121. Correa Publications

122. Discharge Precursor
Microscopic Plasmoids

123. Ken Shoulders
1927 – 2013
Ken Shoulders. Ken Shoulders dedicated his career to the study of microscopic plasmoids. It is his work that provides the best evidence that zero-point energy is cohered by ball lightning.
123

124. Launching Charge Cluster
Dielectric Plate
Anode
Sharp Cathode
Witness Plate
Path
Shoulders, U.S. Patent 5,018,180 (1991)

125. Electrum Validum (EV)

126. Electrum Validum (EV)
1011 Electrons ~100 Billion

127. Electrum Validum (EV)
1011 Electrons ~100 Billion
106 Ions ~1 Million

128. Electrum Validum (EV) 1011 Electrons ~100 Billion 106 Ions ~1 Million
Charge/Mass Ratio like electron

129. Electrum Validum (EV) 1011 Electrons ~100 Billion 106 Ions ~1 Million
Charge/Mass Ratio like Electron
Contains Excessive Energy

130. Pure EV Launcher Liquid Metal Restores Cathode Tip
Shoulders, U.S. Patent 5,018,180 (1991)

131. Liquid Metal Protuberance
Glow Plasma
Point Cathode
Mesyats, Proc. 17th Int. Sym. on Discharges and Electrical Insulation in Vacuum, 720 (1996)

132. Explosive Emission
Glow Plasma
Liquid Metal Tip
Point Cathode

133. Other Names
EV – Electrum Validum

134. Other Names
EV – Electrum Validum
EVO – Exotic Vacuum Object

135. Other Names EV – Electrum Validum EVO – Exotic Vacuum Object
Microscopic Plasmoid

136. Other Names EV – Electrum Validum EVO – Exotic Vacuum Object
Microscopic Plasmoid
Microscopic Ball Lightning

137. Hollow Cathode Pseudospark Chamber
Insulators
Intermediate Electrodes
Anode
Generates Pulsed Electron Beams

138. Correa Tube
Anode
Cathode
Glow Buildup

139. Abnormal Glow Discharge Launches EV’s
Correa Tube
Anode
Cathode
Abnormal Glow Discharge Launches EV’s

140. Abrupt Discharge Jasper James Tube
Anode +
Cathode -

141. Hot Spots Avalanche Breakdown

142. Carbon Hot Spots Launch EV’s Snapback Discharge Event SiC + - C - +

143. Edge Hot Spots Surrounding Plasma During Discharge Launch EV’s? SiC +- C - +
SiC
Surrounding Plasma During Discharge
Launch EV’s?

144. Improvements

145. Extended Thyristor Stack

146. Cold Cathode Tube Anode: Graphite Cathode Mixture: Barium Oxide
Calcium Oxide
Strontium Oxide
Radioactive Material

147. Radioactive Material in Wafer Stack
SiC +
C -

148. Through semiconductor stack drives tube
Avalanche Discharge
Through semiconductor stack drives tube
p +
p+ Positive
Anode +
Cathode -
n- Negative
n -

149. Summary

150. Did Jasper James Discover “Thermodynamically Impossible” Device?

151. Uniform Heat Surrounds Evacuated Tube
Hot
~425 degrees C ~800 degrees F -
“Snout” Outside +
Jasper James, US 4,368,416

152. Heat Lifts Electrons into Conduction Band of Silicon Carbide
Electron Energy Level
Conduction
Gap
Valence
Low Temperature
High Temperature

153. Heat Excites Electron Plasma into Gap of Tube
Anode +
Cathode -

154. Electron Plasma + Conduction Band Electron Cloud Unstable Equilibrium?

155. Avalanche Discharge Fires the Tube
SiC +
Anode +
Cathode -
C -

156. Switching Triggers Avalanche
Anode + -
Output Capacitor
Cathode
Pulsed Electron Movement

157. Pulse Charges Capacitor
Anode + + - -
Output Capacitor
Cathode
Pulsed Electron Movement

158. Similar Rectify RF Noise?
Capacitor
Load
Antenna
Ground
Diode

159. Heat Creates High Energy State
Extracted in Pulse Event

160. Torus Heat Flux
Heat Energy Exits through Snout

161. Zero-Point Energy Involved?

162. Glow Discharge Buildup
Anode
Cathode
Correa Tube

163. Pulse Event Launches Microscopic Ball Lightning
Anode
Cathode
Correa Tube

164. Plasma Hot Spots Launch EV’s
SiC C + -
During Pulse Event

165. Jasper James Device Manifested Huge Electric Output
US Patent 4,368,416
4 inches
22 inches
Output: 20 KW pulsed DC, 400 Hz
Temperature: degrees C

166. From Uniform Heat Hot ~425 degrees C ~800 degrees F - “Snout” Outside+
Jasper James, US 4,368,416

167. Most Peculiar!

168. 2001
1989

169. 2005

170. 2017
AdventuresUnlimitedPress.com

171. Paradigm Shifts Google: Paradigm “Moray King”
Paradigm Shifts is my discussion with Gary Hendershot on the implications of a zero-point energy technology. It focuses on what is really stopping humanity from making the breakthrough discovery.
Google: Paradigm “Moray King”
171

172. Questions? Download this presentation from
All my Power Point presentations on this topic can be downloaded from the shown web site. The links are listed under Subsequent Materials.
To own a video presentation of this slide show, order the DVD “The H4 Hydrogen Project” from
For more information Goggle: emedia Moray nanobubbles
Download this presentation from
Google: Rex Research King
172