The Borealis family of companies can convert popular cold fusion (LENR thermal) energy to desired electrical current at over 50% Carnot efficiency with their Power Chips. This matches, and may nearly double, known industrial electricity production efficiencies.

Then with their Chorus group of advanced polyphase induction motors they can provide every range of torque needed; more efficiently, with decreased size and weight, and with an increase in reliability in both low rpm and high temperature conditions.

Take into account LENR thermal energy at 1000X greater than chemical, plus the thermal/electrical conversion at an amazing 50% to 80%, and then figure in the “harmonic 12 phase” motors with up to 30% improvements in size, efficiency, and safety. Sum it all up however you want and you will see that the Borealis affiliates are roaring and ready to join LENR energy engineers as they race to market a new energy era.

LENR open source projects may benefit from a Borealis relationship as well.

Here is the Borealis LENR thermal electric conversion proposal, a recent patent abstract.

“A system and method are provided for generating electric power from relatively low temperature energy sources at efficiency levels not previously available. The present system and method employ recent advances in low energy nuclear reaction technology and thermionic/thermotunneling device technology first to generate heat and then to convert a substantial portion of the heat generated to usable electrical power. Heat may be generated by a LENR system employing nuclear reactions that occur in readily available materials at ambient temperatures without a high energy input requirement and do not produce radioactive byproducts. The heat generated by the LENR system may be transferred through one or more thermionic converter devices in heat transfer relationship with the LENR system to generate electric power.”


Ancient cultures around the Mediterranean knew that certain objects, such as rods of amber, could be rubbed with cat’s fur to create static electricity. In 1600, the English scientist William Gilbert coined the New Latin word electricus (“of amber” or “like amber,” from ήλεκτρον [elektron], the Greek word for “amber”). This association gave rise to the English words “electric” and “electricity,” which made their first appearance in print in Thomas Browne’s Pseudodoxia Epidemica of 1646.

“Industrial electricity production at present is done primarily with gas and steam turbine technology. Absolute conversion efficiencies with these technologies are in the range of 30%-40%…” see pg. 9 of ’Thermal to Electric Energy Conversion‘, by Dr Peter Hagelstein of MIT.

In light of this, one could venture to say that the Borealis proposal to the LENR energy community, at an impressive 50% to 80% thermal electric conversion, is like a precious energetic gem of amber (elektron).


Electricity is one of the wonders of our times, enabling the second industrial revolution as well as the information and space age. How dense will the proposed Borealis LENR electricity be at 60% Carnot? Let’s look at the size of the 6 kilowatt LENR thermoionic electrical generator (75 cubic centimeters). It is quite small compared to the size of a typical 6 kilowatt natural gas home electrical generator, 48L x 25W x 29H (Inches).

From the Borealis LENR Patent

An illustrative reactor core with a volume on the order of about 50 cubic centimeters (cm3) can use a few grams of nickel or other metal powder and a very small amount of hydrogen to safely produce about 10 kilowatts of heat. …and can continue to produce this amount of heat for six months or more. …and the thermionic converter preferably may have a longest dimension in the range of about one inch (2.2 cm), the overall size of the present high efficiency electricity generating system can be quite small. The size of the system can be increased by connecting modules of LENR system reaction vessels and thermionic converters.


Power Chip efficiency: Power Chips can achieve in excess of 50% of Carnot (ideal) efficiency, compared to a maximum of 36% for single stage power plants, 50-60% in conventional two stage power systems, and 5-8% for thermoelectric devices.

The Borealis affiliates have worked hard to master these technologies. Recent breakthroughs have come to them through advanced techniques of nano engineering. Their discoveries within the world of nano particles has lead to atomic architecture designed for specific quantum effects. For a complete representation of their expertise in the field peruse their sites portfolio of patents granted and google Borealis Technical for recent patent activity.

“The new technology results from the discovery that quantum interference, which reduces quantum state density at a material’s surface, can be achieved on a macroscopic scale. Simply by modifying the surface texture of a material in precise ways, using methods commonly applied in the manufacture of semiconductor devices, engineers should be able to exploit this Avto Effect (TM) and transform existing materials into materials with precisely engineered properties for many new applications. When we fully understand the Avto Effect, we could possibly be able to custom design work functions for multiple different applications.” – Borealis CEO – press release.


From the Borealis Power Chip Patent

The present invention utilizes a wafer bonding technique to create the conditions required for thermoelectric conversion. This involves bringing two conductive planes to within 10-1000 nm without causing electrical or thermal “shorts”. Silicon on insulator techniques are widely used to bond two silicon wafers with thin oxide layers in between. However, the thermal leakage of a 10 nm SiO2 layer is 4-5 orders of magnitude too large for effective thermo-electric conversion.

This can easily be mitigated by not bonding the entire surface. If a small particle is trapped in between two silicon wafers, due to the mechanical properties of silicon, a non-bonded area (void) of 5000 times the size (height) of the particle is created. For example, if a particle of height Z is trapped between two silicon wafers, a void with an area of approximately 5000Z2 is formed. Consequently, if two particles are spaced a distance apart, whereby the size of the distance is less than 2×5000 the size of the particles; an even larger void is created. Using this idea, it is possible to form small “spacers” that maintain a gap between the wafers.


This invention sets and maintains a gap between the electrodes of a thermotunneling device without the use of active elements, and therefore problems of thermal conduction between its layers are reduced or eliminated. Furthermore, using this method to create gap diode devices is inexpensive as it does not require active elements such as piezoelectric actuators to create and maintain the gap.

Furthermore, this invention discloses methods for manufacturing thermotunneling converters on a large scale, thus reducing costs and increasing possibilities for potential applications.

The mechanical properties of silicon are such that if a small particle is trapped in between two silicon wafers, a non-bonded area (void) of 5000 times the size (height) of the particle is created. For example, using a 3-dimensional axis of coordinates X, Y and Z, a particle of height Z leads to a void in the X and Y dimensions of approximately 5000 Z in each of X and Y. Therefore the spacers consist of a dot of silicon oxide topped by a protective layer and will have the effect of keeping the two silicon wafers at a desired distance without the use of active elements.


This forms a structure in which the thermal flux across the assembly is reduced by the ratio of surface area of these spacers to the remaining surface area. A spacer of about 1 micrometer height leads to a gap with a diameter of approximately 5000 times that size, namely, 0.5 cm. These approximations are effective for typical 4 inch diameter silicon wafers, with a thickness of about 525 micrometers. It is understood that the invention is by no means limited to these measurements or approximations, and they are mentioned merely by way of example.

The layers on the active wafer can be introduced using approaches commonly used in the art. For example, an active layer can be introduced on to the electrode by vacuum deposition, using materials such as zinc, lead, cadmium, thallium, bismuth, polonium, tin, selenium, lithium, indium, sodium, potassium, gallium or cesium. Another possible method is sputtering, using materials such as titanium and silver. In a further example, an active layer such as copper is grown electrochemically onto the silicon layer. In another example, an electrically conducting paste, preferably silver, may be applied onto the electrode, or a thin film may be introduced using MEMS techniques. It is to be understood that the invention is in no way limited to these specific methods and they are mentioned only by way of example. Accordingly, any other suitable method may be used.

Manufacturing of electric cars, ships, and aircraft will surge with an electric power plant of this density available; one that requires no fuel tanks or refueling for 6 months!


These manufacturers may also gain an edge with the use of Borealis advanced harmonics control and the ensuing advantages within motors. The following is from the Borealis website.

The Chorus Difference

“The Chorus Motor’s patented employment of electrical drive harmonics unlocks a power-to-weight ratio of almost 10:1 over conventional AC induction solutions. This incredible power density, and the use of patented control logic, allows the motor to function efficiently in both low-speed/high-torque and high-speed/low-torque configurations. In other words Chorus handles very fast starts and ‘power jumps’ as well as smooth, continuous high-speed operation with equal elegance.”


“As a high-phase order motor, the amount of current running through each phase is reduced, enabling a 20-30% reduction in the size and weight of the power electronics module.”

From the Borealis Chorus Motor Patent

The most important result of the method of the present invention is that the use of many phases reduces substantially the problems associated with harmonic rotating fields. Specifically, in a fashion novel to the art, the use of many phases causes harmonic fields up to a number equal to the number of phases to rotate in synchronism with the fundamental rotating field. Both spatial harmonic rotating fields and temporal harmonic rotating fields are still developed, but such rotating fields add beneficially to the fundamental rotating field of the machine. Harmonics of higher order than the number of phases still excite non-synchronous rotating fields; however such high order harmonics are in general very weak. Thus motor efficiency losses associated with harmonic rotating fields are reduced.


The method of the present invention allows for the use of drive wave-form with high harmonic content, and in an embodiment of the present invention, square wave inverters are used in place of the more complex and expensive sine wave inverters to drive the induction rotating machine. The method of the present invention allows for the use of high saturation levels, and in an embodiment of the present invention high voltage is used to produce high flux densities, thus increasing the overload output capabilities of the induction rotating machine.

An advantage of the present invention is that rotating machinery with low pole counts, and thus greater efficiency and capability, can be used where high pole count machines are currently being used.

An advantage of the present invention is that the use of multiple inverters will enhance system fault tolerance. Should an inverter leg fail, only a single motor winding will cease to function, and most of the motor capacity will remain available.


An advantage of the present invention is that currently available inverter technology may be used to enhance the efficiency and performance of electrical rotating machinery.

It is an object of the present invention to enhance the stall torque and reduce the stall power consumption of electric motors.

An advantage of the present invention is that a given size electric motor will be more capable of starting inertial loads. When operated as a generator for regenerative braking purposes, a given size induction machine will be more capable of stopping inertial loads.


An advantage of the present invention is that inertial loads will be more quickly brought up to running speed.

An advantage of the present invention is that less energy will be dissipated when starting and stopping electrical rotating machinery.

An advantage of the present invention is that a smaller motor may be used on large inertial loads, allowing the motor to operate much nearer to full power after said inertial load is accelerated to operational speed. This will enhance the efficiency of such systems as motors are more efficient when operated nearer to full power.


It is an object of the present invention to reduce the zero load power consumption of electric motors.

An advantage of the present invention is that motor operation will be more efficient, especially so at low duty factors.

An advantage of the present invention is that stator heating will be significantly reduced.


It is an object of the present invention to provide greater reliability through redundancy in drive electronics

An advantage of the present invention is that the motor and drive system will continue to function although a single inverter may fail.

An advantage of the present invention is that the winding copper is more effectively used.


Patents Sourced

Borealis LENR Patent - Published Nov. 14, 2013

Method and System for High Efficiency Electricity Generation Using Low Energy Thermal Heat Generation and Thermionic Devices


Borealis Power Chip Patent - Granted Sept. 24, 2013

Thermionic/Thermotunneling Thermo-Electrical Converter

Borealis Chorus Motor Patent - Granted April 25, 2000

Polyphase Induction Electrical Rotating Machine


All over the world, engineers hold the “Ritual of the Calling of an Engineer” in high regard. It was written and presented by Kipling in the early 1920 ‘s, at the request of a group of seven retired presidents of the Engineering Institute of Canada. They had decided that there needed to be a ceremony and standard of ethics for graduating engineers. The Corporation of the Seven Wardens administers the oath to this day.


“The Ritual of the Calling of an Engineer has been instituted with the simple end of directing the young engineer towards a consciousness of his profession and its significance, and indicating to the older engineer his responsibilities in receiving, welcoming and supporting the young engineers in their beginnings.” — Rudyard Kipling

Advances in well engineered physical constructs have improved living conditions since the time of Kipling. Excellence in engineering has become the standard of our day. Recent social constructs have also improved life since the days of Kipling. His poems often reflect the harshness of life before the advent of the 40 hour work week, minimum wage standards, and workplace safety and child labor laws.

Perhaps with the era that popular cold fusion, LENR energy, ushers in we will see our social engineers making the quantum leap that our physical engineers are making today. They did so in the Victorian era.


Honoring those who ensure that all things are in working order and engineered correctly; penned during the writing of the “Ritual of the Calling of the Engineer”.

This poem alludes to the the division of the labor and privileged classes of his day.

The Sons of Martha – by Rudyard Kipling

The Sons of Mary seldom bother, for they have inherited that good part; But the Sons of Martha favour their Mother of the careful soul and troubled heart. And because she lost her temper once, and because she was rude to the Lord her Guest, Her Sons must wait upon Mary’s Sons, world without end, reprieve, or rest.


It is their care in all the ages to take the buffet and cushion the shock. It is their care that the gear engages; it is their care that the switches lock. It is their care that the wheels run truly; it is their care to embark and entrain, Tally, transport, and deliver duly the Sons of Mary by land and main.

They say to mountains, ‘Be ye removed’. They say to the lesser floods, ‘Be dry’. Under their rods are the rocks reproved – they are not afraid of that which is high. Then do the hill-tops shake to the summit – then is the bed of the deep laid bare,

That the Sons of Mary may overcome it, pleasantly sleeping and unaware. They finger death at their gloves’ end where they piece and repiece the living wires. He rears against the gates they tend: they feed him hungry behind their fires. Early at dawn, ere men see clear, they stumble into his terrible stall,


And hale him forth like a haltered steer, and goad and turn him till evenfall. To these from birth is Belief forbidden; from these till death is Relief afar. They are concerned with matter hidden, under the earthline their altars are; The secret fountains to follow up, waters withdrawn to restore to the mouth,

And gather the floods as in a cup, and pour them again at a city drouth. They do not preach that their God will rouse them a little before the nuts work loose. They do not teach that His Pity allows them to leave their work when they damn-well choose. As in the thronged and the lighted ways, so in the dark and the desert they stand.

Wary and watchful all their days that their brethren’s days may be long in the land. Raise ye the stone or cleave the wood to make a path more fair or flat: Lo, it is black already with blood some Son of Martha spilled for that: Not as a ladder from earth to Heaven, not as a witness to any creed,


But simple service simply given to his own kind in their common need. And the Sons of Mary smile and are blessed, they know the angels are on their side. They know in them is the Grace confessed, and for them are the Mercies multiplied. They sit at the Feet – they hear the Word – they see how truly the Promise Runs:

They have cast their burden upon the Lord, and – the Lord He lays it on Martha’s Sons.


Thales, the earliest known researcher into electricity:

Long before any knowledge of electricity existed people were aware of shocks from electric fish. Ancient Egyptian texts dating from 2750 BC referred to these fish as the “Thunderer of the Nile”, and described them as the “protectors” of all other fish. Electric fish were again reported millennia later by ancient Greek, Roman and Arabic naturalists and physicians. Several ancient writers, such as Pliny the Elder and Scribonius Largus, attested to the numbing effect of electric shocks delivered by catfish and torpedo rays, and knew that such shocks could travel along conducting objects. Patients suffering from ailments such as gout or headache were directed to touch electric fish in the hope that the powerful jolt might cure them. Possibly the earliest and nearest approach to the discovery of the identity of lightning, and electricity from any other source, is to be attributed to the Arabs, who before the 15th century had the Arabic word for lightning (raad) applied to the electric ray.


Ancient cultures around the Mediterranean knew that certain objects, such as rods of amber, could be rubbed with cat’s fur to attract light objects like feathers. Thales of Miletos made a series of observations on static electricity around 600 BC, from which he believed that friction rendered amber magnetic, in contrast to minerals such as magnetite, which needed no rubbing. Thales was incorrect in believing the attraction was due to a magnetic effect, but later science would prove a link between magnetism and electricity. According to a controversial theory, the Parthians may have had knowledge of electroplating, based on the 1936 discovery of the Baghdad Battery, which resembles a galvanic cell, though it is uncertain whether the artifact was electrical in nature.

Benjamin Franklin:

Benjamin Franklin conducted extensive research on electricity in the 18th century, as documented by Joseph Priestley(1767) History and Present Status of Electricity, with whom Franklin carried on extended correspondence.


Electricity would remain little more than an intellectual curiosity for millennia until 1600, when the English scientist William Gilbert made a careful study of electricity and magnetism, distinguishing the lodestone effect from static electricity produced by rubbing amber. He coined the New Latin word electricus (“of amber” or “like amber”, from ήλεκτρον [elektron], the Greek word for “amber”) to refer to the property of attracting small objects after being rubbed. This association gave rise to the English words “electric” and “electricity”, which made their first appearance in print in Thomas Browne’s Pseudodoxia Epidemica of 1646.

Further work was conducted by Otto von Guericke, Robert Boyle, Stephen Gray and C. F. du Fay. In the 18th century, Benjamin Franklin conducted extensive research in electricity, selling his possessions to fund his work. In June 1752 he is reputed to have attached a metal key to the bottom of a dampened kite string and flown the kite in a storm-threatened sky. A succession of sparks jumping from the key to the back of his hand showed that lightning was indeed electrical in nature. He also explained the apparently paradoxical behavior of theLeyden jar as a device for storing large amounts of electrical charge.

Michael Faraday formed the foundation of electric motor technology:

In 1791, Luigi Galvani published his discovery of bioelectricity, demonstrating that electricity was the medium by which nerve cells passed signals to the muscles. Alessandro Volta’s battery, or voltaic pile, of 1800, made from alternating layers of zinc and copper, provided scientists with a more reliable source of electrical energy than the electrostatic machines previously used. The recognition of electromagnetism, the unity of electric and magnetic phenomena, is due to Hans Christian Ørsted and André-Marie Ampère in 1819-1820; Michael Faraday invented the electric motor in 1821, and Georg Ohm mathematically analysed the electrical circuit in 1827. Electricity and magnetism (and light) were definitively linked by James Clerk Maxwell, in particular in his “On Physical Lines of Force” in 1861 and 1862.


While the early 19th century had seen rapid progress in electrical science, the late 19th century would see the greatest progress in electrical engineering. Through such people as Alexander Graham Bell,Ottó Bláthy, Thomas Edison, Galileo Ferraris, Oliver Heaviside, Ányos Jedlik, Lord Kelvin, Sir Charles Parsons, Ernst Werner von Siemens, Joseph Swan, Nikola Tesla and George Westinghouse, electricity turned from a scientific curiosity into an essential tool for modern life, becoming a driving force of the Second Industrial Revolution.In 1887, Heinrich Hertz discovered that electrodes illuminated with ultraviolet light create electric sparks more easily. In 1905 Albert Einstein published a paper that explained experimental data from the photoelectric effect as being the result of light energy being carried in discrete quantized packets, energizing electrons. This discovery led to the quantum revolution. Einstein was awarded the Nobel Prize in 1921 for “his discovery of the law of the photoelectric effect”. The photoelectric effect is also employed in photocells such as can be found in solar panels and this is frequently used to make electricity commercially.

The first solid-state device was the “cat’s whisker” detector, first used in 1930s radio receivers. A whisker-like wire is placed lightly in contact with a solid crystal (such as a germanium crystal) in order to detect a radio signal by the contact junction effect. In a solid-state component, the current is confined to solid elements and compounds engineered specifically to switch and amplify it. Current flow can be understood in two forms: as negatively charged electrons, and as positively charged electron deficiencies called holes. These charges and holes are understood in terms of quantum physics. The building material is most often a crystalline semiconductor. The solid-state device came into its own with the invention of the transistor in 1947. Common solid-state devices include transistors, micro processor chips, and RAM. A specialized type of RAM called flash RAM is used in flash drives and more recently, solid state drives to replace mechanically rotating magnetic disc hard drives. Solid state devices became prevalent in the 1950s and the 1960s, during the transition from vacuum tube technology to semiconductor diodes, transistors, integrated circuit (IC) and the light-emitting diode (LED).