crystal cell research propposal

8/14/2019 Crystal Cell Research Propposal

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Crystal Cell Research Plan

Research Laboratory for Vacuum Energywww.vakuumenergie.de

www.sustainablemedia.co

Environmentally Friendly Energy Technology

Research Plan

for the Innovative Technology:

Crystal Cell

Direct Conversion of Coherent Quantum Fluctuations into Electric Energy


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Content

1 Overview........................................................................................... 3

2 Innovation......................................................................................... 42.1 Project CC Crystal Cell............................................................................. 42.2 Potential applications ................................................................................... 5

3 Research strategy............................................................................ 74 Operational planning....................................................................... 8

4.1 Working principal hypothesis........................................................................ 84.2 Development stages..................................................................................... 104.3 Time scale.................................................................................................... 114.4 Resources .................................................................................................... 124.5 Research proposal Marvan-Chemie............................................................. 13

5 Financing.......................................................................................... 155.1 Profit potential .............................................................................................. 155.2 Laboratory Plan..............................................................................................16

6 Team ................................................................................................. 226.1 Marcus Albert Reid....................................................................................... 226.2 Dr. Jan Marwan............................................................................................ 23

6.3 Dr. Gustav Hans Weber ............................................................................... 256.5 Dr. Frank Lichtenberg................................................................................... 26


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1 Overview

In the last several years it has become clear that the quantum electrodynamic theory has openeddoors for fundamentally new energy technologies. It is known that new energy conversiontechnologies exist which extract energy from the quantum vacuum. These new technologies havethe potential to replace conventional energy technologies.

The project CC (Crystal Cell) stands for a new energy technology and is based on the vision andthe research work of inventor Marcus Reid. He has developed battery-like devices which providean electric power output of 10mW/kg/25C; these devices have been in continuous operation (i.e.producing permanently electrical power) since 1999. The present results support the conclusionthat the electric energy is extracted from the quantum vacuum or space time. The subject of theCrystal Cell project is the implementation of research and development to reach economicstandards for licensing and manufactureing. Crystal Cells, whose operation are based on energyextraction from the quantum vacuum, are able to provide electric energy emission free, in apermanent way and their durability is practically unlimited. A Crystal Cell that has an increasedpower output has the potential to replace all existing energy generating systems.

This research plan describes the actions needed to take this proven technology into themarketplace as perpetual batteries, for which we conservatively expect a market in the order ofhundreds of millions of units. This plan describes the necessary research facilities and resourcessuitable to verify and identify the active process, develop, test, independently verify and createworking prototypes suitable for commercial licencing.

Setup funding of $1.766M in the first year, and $405,000 from the second onwards.


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2 Innovation

2.1 Project CC Crystal Cell

Concerning its basic construction, the Crystal Cell is similar to an electrolytic capacitor. Crystalcells contain a solid polycrystalline silicate instead of an electrolyte. The technology exhibits an

entirely new method of generating electric energy.

Here the statement entirely new method has to be taken literally. All researchers who researchedthe Crystal Cell are convinced that the electric energy is extracted from the quantum vacuum orspace time.

The Crystal Cell can be explained by using a modified form of QED quantum electrodynamicstheory. Since the energy density within the quantum vacuum is basically unlimited a so calledasymmetric electric generator can extract energy from the quantum vacuum for an unlimited periodof time and with extreme power densities.

The stage of development of the Crystal Cell technology has reached a level that smallapplications that use little power can be constantly operated with a Crystal Cell weighing100 grams or more depending on the power needed. Economic viability in the low power area isthus beginning to be realized.

The goal of the next research step is to increase the power output of the Crystal Cell to 500mW/kg.New Crystal Cells have shown that this power output can be reached within approx: 1 year afterthe new laboratory is established.

Once a power to volume ratio of 500mW/kg has been reached houses can be supplied with energy

in a permanently. Since the power consumption of a single-household in Germany amounts toabout 7,000 kWh per year on average (electricity, hot water, heating), in the future it can besupplied by a Crystal Cell of approx. 1,5 2 cubic meters. This leads to a decentralized energysupply that makes households independed from any external energy source.

All participating scientists in the Crystal Cell technology development, along with many researchersfrom the established scientific community consider an asymmetric electric system which is basedupon the energy extraction from the quantum vacuum as the energy technology of the future.

We consider the Crystal Cell technology to be an important contribution to the beginning of a newenergy era with which environmental pollution can be reduced.

Independent test data and endorsements are at hand.


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2.2 Potential applications

Usually new technologies are developed in such a way that the efficiency increases step by step.

The present power densitiy of the Crystal Cell is at 10mW/kg. If the power density of the Crystal

Cell is increased to 20mW/kg only, several battery markets can be supplied with Crystal Cells.

Global battery sales for 2011 were $US: 60 Billion

There are approximately 175 companies including Battery Technologies Inc., BYD Company Ltd.,Duracell, Electrochem Automation Inc., Energizer Holdings, Inc., FDK, GP Batteries InternationalLimited, Hitachi Maxell Ltd., Matsushita Battery Industrial Company Ltd., Sanyo Electric CompanyLtd., Sanyo Energy (USA) Corp., Sony Corp., Spectrum Brands, Inc., VARTA Consumer BatteriesGmbH & Co. KGaA, TCL Hyperpower Batteries Inc., Toshiba America Electronic Components,Inc., Tronic Battery Co. Ltd, TWD Battery Co., Ltd., Ultralife Batteries Inc., and ValenceTechnology, Inc. (source, http://www.electronics.ca/publications/products/Consumer-Batteries-

%252d-A-Global-Strategic-Business-Report.html).

For a single type of battery from a single company, Sony's sales of alkaline button batteries andsliver oxide button batteries totaled approximately 300 million for 2008 (source,http://www.sony.net/SonyInfo/News/Press/200906/09-065E/index.html)


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Some battery applications that could now be replaced with Crystal Cell st present day powerdensity are as follows:

! Bicycle computers

! Calculators

! Chess Computers

! Computer Games

! Construction Lasers

! Digital Multi Testers

! Digital temperature and humidity meters

! Distance Meters

! Door phones, wireless phones

! Emergency lighting for homes

!

Gas detectors! Heart Rate Monitors

! LED - Flashlight and pocket computers

! Letter scales, Foot scales, kitchen scales

! Low power stationery equipment (various)

! Party Items

! Portable radios

! Remote controls for TV, DVD player, stereo, etc.

! Remote controls for measuring devices

!

RPM gages! Scoreboards

! Smoke detectors

! Speedometers

! Timers

! Toys

! Wall clocks, various watches


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3 Research strategy

Research in the past has shown that the electric energy is not created by electrochemical effectsor by the conversion of environmental heat.

It is our intention to verify the precise working principal from current hypothesis and to then developa prototype which is economically viable.

To reach this goal, the Research Laboratory for Vacuum Energy will perform three parallelresearch efforts. Two research efforts shall deliver the necessary foundations from the silicate andnanotechnology research and the third research effort will create a simulation of the workingprincipal based upon these foundations.

The first research effort relates to the identification of the active material/materials and thedevelopment of this silicate or other nano-materials in pure form with the aim to increase the power

output of the Crystal Cell as it is currently built.

The second research effort relates to the development of nanocrystals that are made in nano-layers. The next generation Crystal Cell will be a thin capacitor like sandwich that includesinteractive oscillating silicate molecules. This oscillation will be controlled and forced intocoherence by an external trigger signal. This will lead to a significant increase in power output withthe final goal to supply all energetic applications with Crystal Cells.

The third research effort relates to the complete simulation of the hypothesis. The interactiveoscillation of the silicates and the controlling of the coherence will be simulated with the aim to findmore effective nano-materials in a short time.


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4 Operational planning

4.1 Working principal hypothesis

We can show that the Crystal Cell belongs to a new class of electric power producing devices.

They are called asymmetric electric systems. A model of how an asymmetric electric systemsworks is explained in the essay Asymmetric Electric Systems: Basic Principal found onwww.vakuumenergie.de.

Our working hypothesis to realize such an asymmetric electric system is explained here.

In the Crystal Cell we use a thermal photon (instead of a photon from the visible spectrum) to makewater molecules vibrate.

The vibration of several water molecules, that are in a nano-channel and/or nano-cave

arrangement have the tendency to oscillate in a coherent way. This coherent oscillation causes anelectromagnetic wave that can be used to energise electrons.

The energized electrons are able to tunnel through the silicate to the attached diodes. The diodesdirect the electrons into one way only which leads to a steady electric current.

Since the water molecule within the nano-arrangement oscillates with its own electromagnetic fieldand the electromagnetic field is made up of virtual particles that come from space-time (quantumvacuum) itself, in this way energy flows to the water molecule from space-time. Therefore theCrystal Cell is an energetically open system that extracts energy rom space time to energizeelectrons.

The rest of the working mechanism is similar to a solar cell. Instead of sunlight coherent quantumfluctuations are used to create a charge separation. And since the quantum fluctuatins never stopand have an unlimited energy density they are an ideal energy source that is emission free andnever ends.

The Crystal Cell shows several properties which support this view:

1. Measurements with X-ray diffraction show that the polycrystalline silicate consist of smallmolecular caves in the nano-meter range. These caves are ideal to trigger a coherent watermolecule oscillation and electron excitation. This effect has been observed by the Instituteof Nano Science, State Key Laboratory of Mechanics and Control for Mechanical Structures,Nanjing University of Aeronautics and Astronautics, Nanjing 210016, China,Self-Adjusted Sustaining Oscillation of Confined Water Chain in Carbon NanotubesThis effect creates negentropy!

2. Measurements of a Crystal Cell under load show a direct connection of the temperature andthe power output. The temperature is a measure of the intensity of the molecular motion. Ahigher temperature increases the molecular motion and this improves the excitation of theelectrons and leads to a higher power output.


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3. A Crystal Cell not under load has at a certain temperature at a certain voltage. If this CrystalCell is now put under load then the Crystal Cell does not cool down (calorimetricmeasurements were done in a range of less than one milli Kelvin) which shows that theoutput energy is not drawn from the environmental temperature. According to the poweroutput of a small Crystal Cell of 1mW a cooling of 12 milli Kelvin per hour was expected.There is no heating either.

4. Sensitive temperature and voltage measurements of a Crystal Cell under load have shownthat at a specific temperature and voltage a higher or lower power level is observed whichdoes not fit the expected progression of the curve in the chart.Since the temperature is a measure for the motion intensity, this observation shows thatthere are resonance effects between the water and silicate molecues and space-time.

5. The Crystal Cell generates a broad band noise signal within a Faraday cage. At a changingtemperature and voltage of a Crystal Cell under load an arbitrarily choosen measurementfrequency of 245 mhz shows sudden changes of amplitude. The amplitude of the signalsuddenly changes at a higher temperature and power output to a lower amplitude and viceversa. This observation shows a relation of the molecular vibration and the generated poweroutput.

6. When a Crystal Cell self recharges after a longer dead short then the recovering voltagefirst moves up quickly, then slows down and comes to a halt, then it drops a little bit, then itcomes to a halt again and then it goes up to the constant ambient voltage.

The inverse effect is observed when a Crystal Cell is put under a load with a resistor.

The observation shows that the charge separation occurs everywhere within the silicatematerial at the same time. This means that electrochemical effects may be excluded sincethey can only occur at the surface of the electrodes. It also shows that the charge separationis created in all nano-channels throughout the silicate material at the same time.

The same charging and discharging effect has been observed in Agate stones, which wasresearched by Dr. Staschewsky who was employed at the research centre in Karlsruhe.These effects have no electrochemical origin and clearly point to thermal and/or quantumvacuum energy extraction. The caliormetric tests (3) clearly show these are not thermal.


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4.2 Development stages

The route to economically utilizable prototypes for the Crystal Cell will pass through the following 6stages:

Stage 1 Research assignment Crystal Cell technology

! Optimize current silicate manufacturing process. Take spectroscopic impedancemeasurements to identify possible overlaying electrochemical current.

! Manufacturing of active material(s) in pure form. Analyze the precise energy generating effectin relation to the material. Find related materials which increase this effect.

! Identify the cause for the diode characteristic at the materials surfaces. Find better diodematerials.

Stage 2 Research assignment nano technology

! Create nano layers which have a band gap for example in the infrared range to increasetemperature and quantum vacuum conversion efficiency. Find material combinations whichhave a more effective diode characteristic at the silicate-electrode passages.

Stage 3 Research assignment modelizing working principal

! Create a dynamic model of the complete Crystal Cell system with theoretical andexperimental coefficients.

! Derivation of basic engineering concepts to determine the relevant Crystal Cell-parameters inrelation to the model parameters such as ambient voltage, dead-short-current, temperaturecoefficient, power to weight ratio, self-recharge time, time to power with temperature to power-related resonance coupling effects, broad band radio signal behavior, interactve oscillationfrequencies of water molecules in nano-caves, diode oscillation frequencies, interactiveoscillation of diode- and water molecule oscillation, design of external control signal to enforcecoherent oscillation of the whole system.

! Derivation of the requirements of thematerials used and the Crystal Cell manufacturingprocess.

! Derivation of recommendations for optimizing the manufacturing process.

Stage 4 Optimized Crystal Cell functional model

! Derivation of the necessary engineering principles from the theoretical-quantitative foundationwith regard to increasing the output of the Crystal Cell functional model.

Stage 5 Investigation of Crystal Cell protection

! Evaluate the protection process and apply for patents and/or copyright. Investigatehow licenses can be sold in a technology-secure way.

Stage 6 Create Crystal Cell prototype with power density of 1000mW/kg

! Construction of a Crystal Cell prototype with an intended electrical power density of1000mW/kg as the basis for conversion into marketable licensing.


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4.3 Time scale

Project timetable Crystal Cell development until the creation of a prototype.

1. Three months (depending on local conditions) for the establishment of a laboratory. Apotential site is available on the Goodwood estate south of London

2. The aim after one year after the laboratory has been established, is the identification of theactive materials, improvement of these nano-materials and improvement of diode layers.

An increase in power output is expected of up to 200mW/kg. A Crystal Cell with such apower output could cover a a multi million market. Development of a Crystal Cell prototype,investigate possible Crystal Cell applications and start the development of an industrialmanufacturing process.

3. The aim after two years is the verification of the working hypothesis in such a way that itmust be accepted by the scientific community. Once this is achieved there will be noobstacle anymore because it is clear that the Crystal Cell will bea large part of the future

energy economy. After two years a power increase of up to 1000mW/kg is expected.Households, industry and many electronics applications could be supplied with such apower density and we are looking at a multi bi. market pa. Development of a Crystal Cellprototype, investigate possible Crystal Cell applications and start the development of anindustrial manufacturing process.

4. The aim after 3 years will be identified after the second year. Aim of the research is toincrease the power density in so far that all energetic applications can be supplied.


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4.4 Resources

Dr. Frank Lichtenberg wo has built up the laboratories for physics and chemistry at the Universityin Augsburg and at the ETH in Zrich has done the laboratory planning and will help us to built upthe laboratory.

Electric engineer Eckhard Kantz who has done the measurement laboratory planning will build themeasurement laboratory and will be available as an advisor.

Prof. Dr. Claus Turtur will be available for the simulation process since he has already developed asoftware that can calculate resonances that have a non self-symmetrizing character. A non self-symmetrizing resonance is one of the keys for energy extraction form the quantum vacuum.

Prof. Dr. Jeroen van Bokhovenoffered to participate developing certain alumino-silicate materials.He is working at the ETH in Zrich and is also the leader of the Energy department at the Paul

Scherrer Institute in Switzerland.

The development of certain nano-coatings for the diode layers can be given to the companyDr. Jan Marwan in Berlin (Germany).

Dr. Hans Weber is a nuclear physicist who will work as an adviser concerning the interactiveoszillation of the water- and silicate molecules and the control system to enforce a coherence.

Besides the inventor two scientists and a secretary of operations will be employed on a full timebasis. One physicist with skills in measurement techniques, electronics and programming to

measure the Crystal Cell and design the trigger signal that causes the interactive oscillation. Andone chemist with skills in manufacturing nano-materials, silicates, nano-coatings and diodes. Andthe secretary of operations with skills in resource management.


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4.5 Research proposal Marvan-Chemie

In collaboration with Marcus Reid

This proposal covers two main projects on which, invited by Marcus Reid to collaborate, we wouldlike to carry out continuous work.

1. Electrochemical and thermodynamic characterisation of the excess energy constantlyproduced by the solid state Silicon (Si) - Crystal Cell provided by Marcus Reid and the keyfactors that determine this effect.

2. Electrochemical deposition and fabrication of nanocrystals and silicates, to better exploreand increase the excess energy effect characterised in point 1.

Description

The request for clean energy to sustain economic growth and political stability on the one hand, butalso to confront climate change on the other hand, has become of major concern. Therefore, thesearch for an alternative energy source that, among many others, may help fulfil these criteria is of

particular interest.

The solid state Si Crystal Cell that is claimed to constantly produce energy offers, is in our opinion,a unique chance to discover a mechanism that, if fully resolved and comprehensively worked out,contributes to a new source of energy.

Here, our company (Marwan Chemie) offers profound background knowledge and advancedexperimental experience. Our aim in this project is to theoretically fit the experimental data to aconsistently working model that provides reproducible exploitation of this energy effect at ahighlevel. This finally should direct us to the fabrication of a prototype based on the effect shown.

For detailed investigations we are currently interested how to characterise this energy effect. Here,we focus our attention on the electrochemical and thermogravimetric / thermodynamic analysis. Inaddition to this, we need to exactly measure the excess heat released. This requires the use of acalorimetric cell equipped with an ultra high resolution microscope. As we assume the excessenergy effect to occur accompanied by deformation/vibration of the crystal structure and evennuclear transmutation of the nuclei inside the crystal lattice, we have to carry out well definedspectroscopic measurements to make our studies complete.

One major aspect still to consider is to locate the part within the crystal structure that is responsiblefor the energy effect. With respect to electrochemical impedance spectroscopy (EIS) we will beable to deeply investigate resistance and frequency related to the applied voltage and so to exactly

locate the origin attributable to the excess energy effect. We also need to technically split thecrystal in several parts, and for this reason we will hire additional experienced, highly qualifiedstaff.

The fabrication of nanocrystals requires advanced skill in terms of using nanotechnology that wecan offer. Here, one major advantage that we have is our long term experience in fabricatingnanostructured metals exploiting the physical properties of liquid crystalline media. We are surethat this expertise will be of help to determine the key factors to fabricate Si - nanocrystals to theuse of reproducible release of energy on large scale.


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The company Marwan Chemie is one of the leaders in the widely growing field of Low EnergyNuclear Reactions (LENR). We have been organising and promoting the New Energy Technologysymposium at the American Chemical Society (Environmental Division).

Dr Jan Marwan (Research leader) is the author of several publications on nanostructuredpalladium hydrogen electrochemistry as well as fuel cell and sensor catalysis. He is the editor of

the American Chemical Society LENR Sourcebook volume 1 & 2 (Oxford University Press); LowEnergy Nuclear Reactions - The Information fundamental source (American Institute of Physics) inpreparation and the sole author of Nanostructured palladium electrochemistry (Springer) inpreparation.

To do the silicate and nano research Dr. Marwan Chemie will need additional equipment and laborforce:

! potentiostat VSP 5 channels & EIS

! calorimetric system

! thermogravimetric analysis

!

electrochemical cell/glassware/technique! ultra high resolution microscope

! chemicals

! spectroscopic studies (EDX, EXAFS, XPS, XRD) - extern

! additional lab area 46 sqm

! labor force (2 post docs, 2 technicians)


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5 Financing

5.1 Profit Potential

One market segment is to replace batteries for many applications such as flashlights, pocketcomputers, digital scales, toys, clocks, measuring equipment, radios, mobile telephones, electric

locks, organizers, technologies within the medical area, i.e. medical devices, etc.

In the UK the regular price of non-rechargeable batteries (Size AA) is approx. 1 and arechargeable battery of the same size is up to 20 each. Since the Crystal cell is a permanentenergy source it will outperform the rechargeable ones, we assume a price of 5 each.In addition we will sell licences for manufacturing & distribution of the Crystal Cell.

The next application goal is to provide houses with energy. An average 1 person household inGermany consumes appox: 7 000 kilowatt hours of electric energy per year. (100 per month,including electricity, warm-water and heating).

One Crystal Cell block of 1,5 2 cubic meters could deliver 1000 Watts continuously. This isenough for an average 1 person household. If additional energy is needed (e.g. when cooking), itcould be drawn from capacitors or rechargeable batteries that are chared when little or no energyis used.

The installation costs for an oil or gas heating system is approx. 10,000 depending on localconditions. For a 3 person household a licensee could get a Crystal Cell block for a one-time fee of5,000 and in addition a yearly charge of 800 .

We anticipate that once the public has recognized using a Crystal Cell block technology is less

expensive than other energy sources and is emission free, the market could explode within a shorttime.


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5.2 Laboratory Plan

Laboratory Equipment and Costs

High coating system, tectr 60.511,00 Silikat-StrukturanalyseX-ray, powder diffractometer MPD, Panalytical 168.105,00 Silikat-Strukturanalyse

Element dispersive analysis (REM + EDX), Jeol 166.350,00 Silikat-Strukturanalyse

Thermoanalysis TGA-DSC/DTA, Netzsch 79.475,00 Silikat-Strukturanalyse

Gasanalysis for TGA 72.560,00 Zubehr

High temperature furnace, Linn 15.879,00 Beschichtungen

Pressure redurcer, Carl Roth 3.746,80 Zubehr

Kryo storage tank, fl. Nitrogen, CS120SK, Linde 3.692,00 Zubehr

Gas cabinet, 3 piece, Carl Roth 4.896,00 Zubehr

Glovebox, mbraun 32.428,69 ArbeitsboxAnalysis scale, Mettler Toledo 4.892,00 Zubehr

Fume hood 3 piece, Weidner 26.000,00 Zubehr

Software, Origin 8 1.096,81 Silikat-Strukturanalyse

Software Global Scaling 340,00 Silikat-Strukturanalyse

Software Mathematica 6, Wolfram Research 2.935,00 Silikat-Strukturanalyse

High Pressure Laboratory Reactor 2x 27.927,00 Silikat-Herstellung

676.834,30

Accessories, general equipment

2x Laboratory heater, HTCBasic safety control, Carl Roth 928,00

DC-power supply, 1xEA-PS9080-50T, Brklin 1.919,00

2x Multimeter, 87v Digitalmultimeter, Fluke 864,00

Coil wire 50,00

Wires and cables 500,00

Optic microscope, KA18.1 , Carl Roth 1.005,00

Schwanenhals light conductor, C020.1, Carl Roth 230,00

Wire saw, 3032, Well 12.695,00Forceps 100,00

Glases 250,00

Cups 200,00

Bottles 175,00

5x Exicator (dryer), DN200, Carl Roth 900,00


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Laboratory for Measurements: 537 749,00

See Measurement Laboratory Plan below

Consumption items, running costs per year

Articles and books 2.000,00

Repairs, maintenance, spare parts 18.000,00

20.000,00

External workings per year

Custome made products and materials 80.000,00

Special measurements (e.g. dielectric measurements, Synchrotron) 20.000,00100.000,00

Laboratory space

Staff and Laboratory

3 - 4 rooms Total 120sqm 1800.- Euro, pm

Salaries, Physicist, Chemist, Scientists

22 000.- Euro, pm

1 - Company car (used) 8000.- Euro


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Costs Total

Laboratory equipment 1 361 111.-

Running costs, materials, salaries approx: 405 000.- pa.

Total, first year approx: 1 766 111.-

Running costs from second year approx: 405 000.- pa.

Investment for 2 years phase:

2 171 111,- Euro or 1 836 000,- Pound


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Measurement Laboratory Plan:

Positi

on

Bezeichn

ung

Beschreibung Link Komponenten Anzahl

Einzelpreis Gesamtpreis mon

atlich

1 Laptop DELL XPSM1730

DELL Laptop 5 1969 9.845

2 Software Entwicklung

stools frMessanalyse

MSVS2008MindMa

nagerFPGALabWindows

MS VisualStudio2008 MindMana

ger FPGA DSP

Software Messw

ertsoftware

2 51 2

850356 1.100 2

.400

9.380

3 Monitor NEC

MultiSync

Monitor 5 2100 10500

4 InternetFlat

MobileFlatrate 7

MBit

Mobile Flat 5 20 100

5 R&S

FSU67

Spectrum

Analyzer20Hz..67

GHz

FSU67 FSU67SpectrumA. FSU-B4

OCXO FSU-B21

LO/ZF DCV-2Kalibrier. M.

1

1 11 1

98.9502.920

3.060

315 4.7308.150

105245

6 R&S

ZVA50

Vector

NetworkAnalyzer

bis 50 GHz

ZVA50 ZVA50 NetworkA. ZVA-K8 Anst.Konv. DCV-2

Kalibrier.M. ZVA50-B16

Steuer. ZV-Z36

Kalibr. Satz

1

1 1 1

1 1

139.720

5.480315

5.700

9.980

161195

8 HM8150 Funktionsgen. 10

mHz..12,5MHz

HM8150 2 1.022 2.044

9 Thermosta

t

PC-

gesteuerterThermostat

Thermostat SmartlineSulenthermostat

10

2.408 Rabatt

24.080 -

2.408

10 MKT 50 MillikelvinThermomet

erMKT 50

Przisionsthermom. Sensorkabe

l Messfhler

100..220C

10

10 1

0 10

3.125

294 555

39.740

12 Internet Internetanschluss 16

MBit

Internet 35

13 Datenserver

Datenserver(lokal, pro

Jahr)

Terraserver 4 ca. 8.000 32.000

14 Switch Netzwerkswi

tch 48-Ports

Switch 4 ca. 6.000 24.000


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15 Datensam

pler

Datensampl

er 2x16-bit@125MHz

Sampler

XtremeDSPEXP

AdapterAD9

461Gehuse

Spartan-3A

DSP EXP AnalogDevices 2x

AD9461

16b/130MS Gehuse Buchsen,

Kabel,ca. Fertigung,

ca.

50

50 50 10

0 50

5050

215125 195

50 75

350

50.500

16 Netzteil Labornetzteil fr

Datensampler

Netzteil 10 258 2.580

17 Messgert Vielfachmessgert

10 100 1.000

18 Null-Gau Null-Gau-

Kammer

Null-Gau ZG1 - 335mm ZG2 670mm

3

1 2 3.980 5.980

15.940

19 Abschirmu

ng

NF+HF

AbschirmungMesskamme

rn

Aaronia

Shield

200

m2

50 EUR/m2 10.000

20 Serverschrank

Netzwerkund

Serverschrank

Klimatisierte

rServerschra

nk

19"

RackPatchpanelPatchkab

elDoseVerle

gekabel

Serverschrank P

atchpanel24x Patchkabel

Netzwerkdose N

etzwerkkabelCat6a Kabelkan

le

2 8

50 25 10

00m

80m

3.674 35

7 10810 400

9.438

21 GPSource2000

GPS-gesteuertes

Zeitnormal1ns

GPS Clock 3 4.350 13050

22 N-Stecker HF-Stecker,

N-Norm

N-Stecker 200 6 1.200

23 Load Abschlusswi

derstand 50Ohm

Load 100 13 1.300

24 DL9240 Oscilloscope DL9240L 1 15.900 15.900

25 Werkzeug Elektronikw

erkzeug

Werkzeug 1 160 160

26 HM8123X Frequenzzh

ler DC-3GHz

HM8123X 1 1060 1060

30SUMME

537749


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6 Team

6.1 Marcus Albert Reid

Personal data Marcus Albert Reid

Ligsalzstrasse 11

D-80339 Munich

Born on 12/27/1968 in Cape Town, South Africa as aGerman citizen.

Moved to Germany in 1978.

Telefone ++49 (0) 152-53 53 26 30

E-Mail: [email protected]

Professional

career

Since 1998 he has engaged in the research of asymmetric electric systems as a

theorist and inventor. Work done by Dr. Thomas Bearden has a formative influence.Marcus Reid is a mainly a self taught researcher.

In 1999, the idea of a permanent "electron pump", which he calls the "crystal cell",evolved. At the end of 2000, the crystal cell project was, for the time being, put on hold.

Subsequently, the "Bowman" permanent magnet motor was replicated.

In the years from 2001 to 2003, he developed the Magnetsternmotor.

The "Research Laboratory for Vacuum Energy" was founded in 2004.

In the same yearhe started to examine a 2.5-dimensional, 1:1 gear transmission withdifferent diameters, which is an invention of Karl Heinz Goebel (DE10105835A).Marcus Reid took this invention to the next stage, a 3-dimensional gear transmission

with improved running behaviour.Subsequently an elliptical 1:1 gear transmission with an asymmetric gear tooth shapewas developed for the Magnetsternmotor.

The Linearmotor which proves Newton's third law was realized in 2005.

In the beginning of 2006, the crystal cell project was revived.

Since 2005 he has been developing theories with which the basic energetic interactionbetween electric systems and the quantum vacuum are demonstrated. This revealswhy electric systems are "energy-symmetric" in relation to their energetic exchangewith the quantum vacuum.

With regard to this symmetry-causing phenomenon, he speaks of: "The self-

symmetrizing mechanism within electric systems". Subsequently he identified twotheoretical methods by which this self-symmetrizing mechanism can be bypassed. Forboth methods an experimental approach has been identified. He also developedtheoretical concepts for other energy conversion devices such as the A-DMSGenerator (Asymmetric-Dynamic Magnetic Spin-based Generator) and the AMNOGenerator (Asymmetric-Magneto Nuclear Oscillator) and propulsion systems called the

AFDC System (Active Frame-dragging Control System) and the A-DMSIA(Asymmetric-Dynamic Magnetic Spin-based Inertial Accelerator) and anelectromagnetic shielding system called the IFSI (Intelligent Frame SpinningInterferometer.

He also developed a theoretical approach that relates to information transfere throughspace.


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6.2 Dr. Jan Marwan

Personal data Dr. Jan MarwanRudower Chaussee 2912489 Berlin

GermanyBorn on 04/22/1972.

Citizenship German.

Phon ++49 30 6392-2566

[email protected]

Professionalcareer

since 2005established my own company: Dr. Marwan ChemieResearch & Development Electrochemistry & New Energy Technology

2003 2004Postdoctoral fellow:Research and Teaching at Universit du Qubec Montral (UQM), CanadaResearch Director: Prof. Daniel Blanger

2000 2003PhD in electrochemistry (surface/materials science); University ofSouthampton, UKProject title: Electrodeposition and electrochemical properties ofnanostructured metal films; Research director: Prof. Philip N. Bartlett

1999Diploma (MSc) in Chemistry :specialized in Biophysical Chemistry;

Technical University Berlin, Germany;Project title: Amperometric investigation of the Photosystem II

1988 1998Business Accountant:full and later part-time job; working for a fewcompanies.


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Publications Author / Co-author of several scientific papers:

Bartlett PN, Marwan J;The effect of surface species on the rate of H sorption into nanostructured Pd PHYSICAL CHEMISTRY CHEMICAL PHYSICS 6 (11): 2895-2898 JUN 7 2004

Bartlett PN, Marwan J;Preparation and characterization of H-1-e rhodium films

MICROPOROUS AND MESOPOROUS MATERIALS 62 (1-2): 73-79 AUG 14 2003

Bartlett PN, Marwan J;Electrochemical deposition of nanostructured (H-1-e) layers of two metals in which pores withinthe two layers interconnectCHEMISTRY OF MATERIALS 15 (15): 2962-2968 JUL 29 2003

Bartlett PN, Gollas B, Guerin S and Marwan J.The preparation and characterisation of H-1-e palladium films with a regular hexagonalnanostructure formed by electrochemical deposition from lyotropicliquid crystalline phasesPHYSICAL CHEMISTRY CHEMICAL PHYSICS 4 (15): 3835-3842 2002

Marwan J,Ghodbane O, Lascombe E, Chamoulaud G, Blanger D and Touaibia MFunctionalization of nickel onto 4-aminothiophenol modified electrode and the enhancedkinetics towards the oxidation of ethanol;

AMERICAN CHEMICAL SOCIETY, FUEL CHEMISTRY, REPRINT, PHILADELPHIA 2004

Marwan J,Blanger D;Electrochemistry and grafting of 4-aminothiophenol onto GC electrode surfaces

ABSTRACT ELECTROCHEM. SOC.; SAN ANTONIO AND HONOLULU 2004

Marwan J;Re-evaluation of the Pons-Fleischmann experiment in light of cold fusion reactions

ABSTRACT AMERICAN CHEMICAL SOCIETY WASHINGTON 2005

Marwan J;Addou T, Belanger D;Functionalization of glassy carbon electrodes with metal based speciesCHEMISTRY OF MATERIALS, 2005, 17. 2395 - 2403


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6.3 Dr. Gustav Hans Weber

Personal data Gustav Hans WeberDr. sc. nat. ETHHubwiesstrasse 8CH-8427 Freienstein

Born on 10/15/1941 in Zurich, Switzerland

Phon ++41 (0)43 266 65 82

E-Mail [email protected]

Professionalcareer

since 2005Working in the area of unification of the fundamental physicalinteractions (in cooperation with Rudolf Fehlmann).

since 2005Consulting in R&D-Project Semiconductor cooling.

1999 2004Tutor for medical measument technique at the Technical Akademia ofEsslingen, branch in Sarnen (CH).

1985 2006Several research projects for the private industry (e. g. Boeing Seattle)and federal office in the area of environmental industry, measuringtechnique, weapons development and energy technology.

Development of a patented waste recycling plant for highly toxicmaterials.

1984Set up for independence and foundation of the first laboratory in bionics

with focus on waste recycling and renewable energy1974 1983Physicist in the research laboratory of the swiss federal institute forReaktorforschung in Wrenlingen (EIR, today PSI).Working in the areas of reactor safety and energy storage.

1973 1974Research scientist at the Institute of physical chemistry at the ETHZurich.

1968 1973Leader of the research group Kalorimetrie at Mettler Instrumente AG(today Toledo) and development of a very sensitive calorimetric device in

the frame of the dissertation.Education 1973

Doctorate in experimental thermodynamic at the institute for physicalchemistry at the ETH (Technical College) Zurich.

1965 1966Post graduate study in High Energy Physics at Imperial College, London.

1961 1964Study in theoretical physics at the ETH (Technical College) Zurich.

1957 1960Kantonsschule (Cantonal School) in Zurich, completion with senior high-school diploma


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6.4 Dr. Frank Lichtenberg

Personal data Frank LichtenbergDr. sc. nat.Bleigsschen 4

D-86150 AugsburgBorn on 11/06/1962 in Bremen (Germany).

Phon ++49 (0)821 50 83 301

E-Mail [email protected]

Publications Author / Co-author of 70 scientific papers und 6 patents.

Professionalcareer

since 2008Consulting in the special interest area Superconductors.

Attending R&D concerning Silicate Cell (SIBA) with Marcus Reid.

1997 2007Research scientist at the Institute of Physics at the University of

Augsburg (Germany) in the area of synthesis of melt-grown crystals.

1996Guest scientist in Tokyo (Japan) at the Technology Laboratory of theTOSHIBA Battery Company within the framework of a collaborationbetween VARTA und TOSHIBA

1992 1997Research scientist at the Research and Development Centre of thebattery company VARTA in Kelkheim (Germany) in the Nickel-Metal-Hydride Technology Department.

Education 1989 1992Thesis work at the IBM Zurich Research Laboratory (Switzerland) in thearea of solid state physics / chemistry.

1983 1988Study of physics at the University of Heidelberg (Germany).

crystal cell research propposal

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