Professor Kamuro's near-future science predictions
Research on Prediction and Forecasting of Precursors and Omens of Natural Disasters such as Volcanic Eruptions and MEGA Earthquakes
AERI Wideband UV Dual Comb Spectrophotometer
AWUDS
- Innovative UV Broadband Spectrophotometer Bringing Real-Time Analysis of Volcanic Gases -
Quantum Physicist and Brain Scientist
Visiting Professor of Quantum Physics,
California Institute of Technology
IEEE-USA Fellow
American Physical Society-USA Fellow
PhD. & Dr. Kazuto Kamuro
AERI:Artificial Evolution Research Institute
Pasadena, California
HP: https://www.aeri-japan.com/
and
Xyronix Corporation
Pasadena, California
HP: https://www.usaxyronix.com/
Foreword
A. Professor Kamuro's near-future science predictions, provided by CALTECH professor Kazuto Kamuro(Doctor of Engineering (D.Eng.) and Ph.D. in Quantum Physics, Semiconductor Physics, and Quantum Optics), Chief Researcher at the Artificial Evolution Research Institute (AERI, https://www.aeri-japan.com/) and Xyronix Corporation(specializing in the design of a. Neural Connection LSI, b. BCI LSI(Brain-Computer Interface LSI) (Large Scale Integrated Circuits) , and c. bio-computer semiconductor technology that directly connects bio-semiconductors, serving as neural connectors, to the brain's nerves at the nano scale, https://www.usaxyronix.com/), are based on research and development achievements in cutting-edge fields such as quantum physics, biophysics, neuroscience, artificial brain studies, intelligent biocomputing, next-generation technologies, quantum semiconductors, satellite optoelectronics, quantum optics, quantum computing science, brain computing science, nano-sized semiconductors, ultra-large-scale integration engineering, non-destructive testing, lifespan prediction engineering, ultra-short pulses, and high-power laser science.
The Artificial Evolution Research Institute (AERI) and Xyronix Corporation employ over 160 individuals with Ph.D.s in quantum brain science, quantum neurology, quantum cognitive science, molecular biology, electronic and electrical engineering, applied physics, information technology (IT), data science, communication engineering, semiconductor and materials engineering. They also have more than 190 individuals with doctoral degrees in engineering and over 230 engineers, including those specializing in software, network, and system engineering, as well as programmers, dedicated to advancing research and development.
Building on the outcomes in unexplored and extreme territories within these advanced research domains, AERI and Xyronix Corporation aim to provide opportunities for postgraduate researchers in engineering disciplines. Through achievements in areas such as the 6th generation computer, nuclear deterrence, military unmanned systems, missile defense, renewable and clean energy, climate change mitigation, environmental conservation, Green Transformation (GX), and national resilience, the primary objective is to furnish scholars with genuine opportunities for learning and discovery. The overarching goal is to transform them from 'reeds that have just begun to take a step as reeds capable of thinking' into 'reeds that think, act, and relentlessly pursue growth.' This initiative aims to impart a guiding philosophy for complete metamorphosis and to provide guidance for venturing into unexplored and extreme territories, aspiring to fulfill the role of pioneers in this new era.
B. In the cutting-edge research domain, the Artificial Evolution Research Institute (AERI) and Xyronix Corporation have made notable advancements in various fields. Some examples include:
1. AERI・HEL (Petawatt-class Ultra-High Power Terawatt-class Ultra-High Power
Femtosecond Laser)
◦ Petawatt-class ultra-high power terawatt-class ultra-short pulse laser (AERI・HEL)
2. 6th Generation Computer&Computing
◦ Consciousness-driven Bio-Computer
◦ Brain Implant Bio-Computer
3. Carbon-neutral AERI synthetic fuel chemical process
(Green Transformation (GX) technology)
◦ Production of synthetic fuel (LNG methanol) through CO₂ recovery system (DAC)
4. Green Synthetic Fuel Production Technology(Green Transformation (GX) technology)
◦ Carbon-neutral, carbon-recycling system-type AERI synthetic fuel chemical process
5. Direct Air Capture Technology (DAC)
◦ Carbon-neutral, carbon-recycling carbon dioxide circulation recovery system
6. Bio-LSI・Semiconductors
◦ Neural connection element directly connecting bio-semiconductors and brain nerves
on a nanoscale
◦ Brain LSI Chip Set, Bio-Computer LSI, BMI LSI, BCI LSI, Brain Computing LSI,
Brain Implant LSI
7. CHEGPG System (Closed Cycle Heat Exchange Power Generation System with
Thermal Regenerative Binary Engine)
◦ Power generation capability of Terawatt (TW), annual power generation of
10,000 TWh (terawatt-hour) class
◦ 1 to 0.01 yen/kWh, infinitely clean energy source, renewable energy source
8. Consciousness-Driven Generative Autonomous Robot
9. Brain Implemented Robot・Cybernetic Soldier
10. Generative Robot, Generative Android Army, Generative Android
11. High-Altitude Missile Initial Intercept System, Enemy Base Neutralization System,
Nuclear and Conventional Weapon Neutralization System, Next-Generation
Interception Laser System for ICBMs, Next-Generation Interception Laser System
for Combat Aircraft
12. Boost Phase, Mid-Course Phase, Terminal Phase Ballistic Missile Interception System
13. Volcanic Microseismic Laser Remote Sensing
14. Volcanic Eruption Prediction Technology, Eruption Precursor Detection System
15. Mega Earthquake Precursor and Prediction System
16. Laser Degradation Diagnosis, Non-Destructive Inspection System
17. Ultra-Low-Altitude Satellite, Ultra-High-Speed Moving Object
Non-Destructive Inspection System
✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼
Research on Prediction and Forecasting of Precursors and Omens of Natural Disasters such as Volcanic Eruptions and MEGA Earthquakes
AERI Wideband UV Dual Comb Spectrophotometer AWUDS
- Innovative UV Broadband Spectrophotometer Bringing Real-Time Analysis of Volcanic Gases -
A. Volcanic gas is composed primarily of gases emitted from the crater or vents of a volcano, among the components (volcanic ejecta), often with temperatures exceeding several hundred degrees Celsius and higher density than air, making it prone to accumulate in low-lying areas. Volcanic gas (including gases containing a large amount of water vapor and carbon dioxide) is sometimes referred to as volcanic gas.
1. The main components include water vapor and carbon dioxide, along with sulfur dioxide (sulfurous gas). Typically, small amounts of hydrogen gas, carbon monoxide, hydrogen sulfide, and hydrogen chloride are present. Depending on the volcano, gases such as hydrogen fluoride, silicon tetrafluoride, methane, ammonia, carbonyl sulfide, helium, radon, and mercury may also be present in volcanic gases, which may contain steam as well. Components with toxicity and the risk of asphyxiation can pose significant hazards to the life of animals and plants. Moreover, the heat from these emissions often has a significant impact on surrounding ecosystems, sometimes resulting in immediate death for animals or humans who inhale them. Additionally, fatalities can occur due to poisoning that goes unnoticed until it is too late. Many volcanoes emit only volcanic gases continuously or intermittently, even without erupting.
2. Volcanic gas collectively refers to gases released into the atmosphere during volcanic eruption activity, with their composition varying depending on the type of volcano and the stage of eruption. The main components include water vapor, carbon dioxide, sulfur compounds, nitrogen, and small amounts of hydrogen. These gases are ejected from the volcano's interior towards the surface and disperse into the atmosphere.
3. Water vapor is the most abundant component during volcanic eruptions, as underground water vapor evaporates and is released into the atmosphere during eruptions. Carbon dioxide, dissolved in magma beneath the ground, is released from magma during eruptions. Sulfur compounds are hazardous components released during volcanic eruptions, primarily consisting of sulfur oxides and hydrogen sulfide.
4. These volcanic gases undergo chemical reactions in the atmosphere, potentially forming compounds such as sulfates and nitrates. These compounds, along with volcanic ash, can float in the atmosphere and react with light and water to produce acid rain. Moreover, an increase in volcanic gas emissions may influence the Earth's climate, especially if large amounts of carbon dioxide are released, contributing to global warming and climate change.
5. Analyzing volcanic gases is crucial for monitoring volcanic activity and predicting eruptions. Using Earth observation satellites and ground-based sensors, monitoring the quantity and composition of volcanic gases allows tracking changes in volcanic activity and implementing appropriate measures to ensure people's safety.
B. Analysis of volcanic gas: Various methods are used for the analysis of volcanic gas. First, Mass Spectrometry is commonly used to precisely analyze the components of volcanic gas. Additionally, analytical techniques such as Gas Chromatography and Fourier transform infrared spectroscopy are also utilized. These methods allow for the identification of the types and quantities of components such as water vapor, carbon dioxide, and sulfur compounds, enabling the assessment of volcanic activity. Furthermore, remote sensing devices installed on Earth observation satellites are used to observe the distribution of volcanic gas over wide areas and monitor volcanic activity in real-time. These analytical methods are essential for understanding volcanic activity and predicting eruptions, contributing to the prevention of volcanic disasters and minimizing their impact.
C. Overview of Analytical Methods:
a. Mass Spectrometry: Characteristics:
1. High resolution: Mass Spectrometry has high resolution and can detect trace components.
2. Wide-ranging analysis: Capable of simultaneously analyzing various components.
3. High reliability: Provides high reproducibility and reliability. Advantages:
· Detection sensitivity: For example, sulfur oxide concentrations can be measured at 1 ppb levels.
· Measurement time: Analysis is typically completed in several minutes to tens of minutes. Disadvantages:
· High cost: Mass Spectrometry is expensive, incurring high costs.
· Sample pre-processing required: Time and effort are required for sample pre-processing.
· Analytical limitations: There are limitations on the number and types of components that can be analyzed at once.
b. Gas Chromatography: Characteristics:
1. High separation power: Able to separate components with high resolution and obtain individual peaks.
2. High sensitivity: Can detect trace components.
3. Quantitative capability: Possesses good quantification and low detection limits. Advantages:
· Detection sensitivity: For example, sulfur oxide concentrations can be measured at 1 ppb levels.
· Measurement time: Analysis is typically completed in several tens of minutes to several hours. Disadvantages:
· Sample pre-processing required: Time and effort are required for sample pre-processing.
· Equipment maintenance required: Regular maintenance and column replacement are necessary.
c. Fourier transform infrared spectroscopy (FTIR): FTIR is an optical spectroscopic method used to measure the absorption spectrum of infrared radiation to examine molecular structures and chemical compositions. It provides information related to molecular vibrations. Characteristics:
1. Non-destructive analysis: Enables analysis without sample destruction.
2. High resolution: Allows analysis at the molecular level.
3. Wide wavelength range: Covers a wide range of wavelengths and can analyze various components simultaneously. Advantages:
· Detection sensitivity: For example, sulfur oxide concentrations can be measured at 10 ppb levels.
· Measurement time: Analysis is typically completed in several minutes to tens of minutes. Disadvantages:
· Dependent on equipment accuracy: Accurate calibration of equipment is necessary to obtain precise results.
· Sample preparation required: Sample preparation requires effort.
d. Remote Sensing on Earth observation satellites: Characteristics:
1. Wide area surveillance: Can monitor a wide range of land surfaces in real-time.
2. Long-term observation: Allows for long-term data collection.
3. Non-contact measurement: Measurement is possible without access to the ground, allowing for non-contact measurement. Advantages:
· Broad coverage: Can simultaneously observe a wide range of areas.
· Long-term observation: Enables tracking of long-term volcanic activity changes. Disadvantages:
· Spatial resolution limitations: Detailed observations are limited by the resolution of Earth observation satellites.
· Dependence on weather conditions: Data quality may decrease depending on weather conditions.
D. Solar radiation has a significant impact on chemical processes. Particularly, high-energy ultraviolet radiation is strongly absorbed by various substances, causing photochemical reactions of greenhouse gases and volcanic gases such as carbon dioxide (CO2), sulfur dioxide (SO2), sulfuric acid gas (SO2), methane (CH4), nitrous oxide gas (N2O), hydrogen gas (H2), carbon monoxide gas (CO), hydrogen sulfide gas (H2S), hydrogen chloride gas (HCl), hydrogen fluoride gas (HF), silicon tetrafluoride (SiF4), ammonia gas (NH3), and carbonyl sulfide gas (COS) in the atmosphere. A well-known example is the formation of ozone at ground level when ultraviolet radiation interacts with nitrogen oxides (NOx).
1. The volcanic eruption, MEGA earthquake precursor and precursor prediction research team led by Professor Kazuto Kamuro, the chief research officer of the Artificial Evolution Research Institute (AERI: Pasadena, California, HP: https://www.aeri-japan.com/), is currently utilizing this high reactivity in new methods for remote monitoring of greenhouse gases and volcanic gases in the atmosphere to track short-term and long-term changes in volcanic activity and predict and forecast precursors and precursors of volcanic eruptions and MEGA earthquakes before they occur. They have announced the AERI satellite-based volcanic gas detection system, which utilizes remote observation and monitoring with ultra-low altitude artificial satellites, with a time resolution of a few minutes and 24-hour constant, real-time, in-situ remote observation and monitoring of the occurrence and movement of greenhouse gases and volcanic gases in the early stages, such as carbon dioxide (CO2), sulfur dioxide (SO2), sulfuric acid gas (SO2), methane (CH4), nitrous oxide gas (N2O), hydrogen gas (H2), carbon monoxide gas (CO), hydrogen sulfide gas (H2S), hydrogen chloride gas (HCl), hydrogen fluoride gas (HF), silicon tetrafluoride (SiF4), ammonia gas (NH3), and carbonyl sulfide gas (COS).
2. Simultaneously, the world's first and cutting-edge artificial satellite-mounted remote sensing and analysis method (optical spectroscopy), the AERI Wideband UV Dual Comb Spectrophotometer (AWUDS), for continuous measurement of the components, composition, and concentration of greenhouse gases and volcanic gases, as well as other climate-related trace gases (greenhouse gases) such as nitrogen oxides (NOx), ozone (O3), carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), hydrofluorocarbons (HFCs), perfluorocarbons (PFCs), sulfur hexafluoride (SF6), etc., have been announced. These observations can be conducted remotely and in real-time from ultra-low altitude artificial satellites, allowing for observation and monitoring of reactions with the climate change environment.
3. The AERI satellite-based volcanic gas detection system uses remote sensing equipment consisting of (1) the AWUDS and (2) MEGA Quantum Interferometric Vector Dynamics Systems, (3) chirped pulse amplification (CPA) - off-axis parabolic mirror (hyperbolic secondary focal point matching rotating hyperbolic mirror) interpolation-type single-wavelength, petawatt-class ultra-high-intensity, femtosecond-class ultra-short pulse laser system (AERI HEL) and other equipment, mounted on Earth observation satellites such as ultra-low altitude artificial satellites, to continuously measure the gas properties of a wide range of greenhouse gases and volcanic gases. It can monitor (optical spectroscopic observation and monitoring) volcanic activity remotely and in real-time, with a time resolution of 1 billion samples per minute (10 giga samples/minute) and a spatial resolution of 100 million sampling points per square meter, 24 hours a day.
4. The analysis methods employed by the AERI satellite-based volcanic gas detection system are essential for understanding volcanic activity and predicting eruptions, contributing to disaster prevention and mitigation of volcanic disasters (natural disasters, calamities), and are indispensable cutting-edge core technologies for disaster prevention and national resilience enhancement.
E. The AERI Wideband UV Dual Comb Spectrophotometer (AWUDS) is a tool for exploring a wide spectrum of light and plays an important role in the field of optical analysis. This device is used to analyze the properties and structures of substances in detail by measuring the absorption and radiation of light in the UV region. Below, we will provide a detailed explanation of the principles, applications, and significance of the AWUDS.
1. Principles of AWUDS: The AWUDS is a device that spectrally disperses incident light into various wavelengths. Its basic principle involves using optical elements such as diffraction gratings or prisms to disperse incident light. The dispersed light is measured by a detector, generating a spectrum that indicates the intensity of light at each wavelength, reflecting the absorption and emission characteristics of the sample.
2. Applications of AWUDS: The AWUDS has a wide range of applications in various fields:
· Biochemistry and medicine: It examines the absorption spectra of biological samples such as proteins, DNA, and RNA, analyzing the structure and interactions of biomolecules. This contributes to the development of new therapies and diagnostic methods in the fields of medicine and pharmacology.
· Environmental science: It is used for the inspection of greenhouse gases and volcanic gases such as carbon dioxide (CO2), sulfur dioxide (SO2), methane (CH4), nitrous oxide (N2O), hydrogen sulfide (H2S), and ammonia (NH3) in the atmosphere, as well as water quality. The AWUDS measures the concentrations of greenhouse gases and volcanic gases composed of organic and inorganic substances in water bodies and the atmosphere, contributing to environmental pollution monitoring and management.
· Materials science: It is used to examine the optical properties of specific materials and understand their structure and characteristics, aiding in the design and development of semiconductor and optical materials.
3. Significance of AWUDS: The AWUDS plays an indispensable role in scientific research and industry due to its high sensitivity and wide wavelength range. The data obtained by these devices form the basis for new discoveries and innovations. Furthermore, they serve as valuable sources of information for researchers and engineers to analyze materials and biological samples in detail and address problem-solving.
Conclusion: The AWUDS is widely used as an essential tool in the field of optical analysis. Understanding its principles and applications is essential for the advancement of optical analysis in scientific research and industry. With continued technological innovation, UV broadband spectrophotometric systems are expected to become more advanced, opening up new areas of application in the future.
F. The AWUDS (AERI Wideband UV Dual Comb Spectrophotometer) is an advanced spectroscopic system (spectrophotometer) for detailed analysis of light absorption and radiation in the UV region. Below, we will explain its principles, applications, and scientific significance.
1. Principles of AWUDS: The AWUDS is an abbreviation for "Dual-beam, double monochromator" and is installed in the AERI satellite-borne volcanic gas detection system. It monitors the generation and movement of greenhouse gases and volcanic gases on the Earth's surface from ultra-low altitude satellites, with a time resolution of 10 billion samples per minute and a spatial resolution of 100 million sampling points per square meter, continuously and in real-time, monitoring volcanic activity remotely (optical remote spectroscopic observation). Its basic principles are as follows:
· Dual-beam: Incident light passes through two different paths, allowing for correction of light source instability and fluctuations during measurements.
· Double monochromator: Two monochromators are placed inside the spectrometer, each selectively passing light of different wavelengths. This allows for simultaneous comparison of absorbance at two different wavelengths of the target being measured.
2. Applications of AWUDS: The AWUDS, as an optical remote spectroscopic observation system, is widely used in various fields through its installation in the AERI satellite-borne volcanic gas detection system. It is a core technology for monitoring volcanic activity remotely (optical spectroscopic observation) in real-time, 24 hours a day, continuously, from ultra-low altitude satellites, at a time resolution of 10 billion samples per minute and a spatial resolution of 100 million sampling points per square meter.
· Biology and Medicine: It examines the absorption spectra of biological samples such as proteins, DNA, and RNA, analyzing the structure and interactions of biomolecules. This contributes to understanding disease mechanisms and developing new treatment methods.
· Environmental Science: It is used for inspecting greenhouse gases and volcanic gases in the atmosphere and water quality. The AWUDS measures the concentrations of greenhouse gases and volcanic gases composed of organic and inorganic substances in water bodies and the atmosphere, contributing to environmental pollution monitoring and management.
G. Robust Percolation Transition (RPT) is an important concept in network theory and complex systems science, essential for understanding the impact of changes in connections within a network on the system's robustness.
1. In the AWUDS installed in the AERI satellite-borne volcanic gas detection system, the light source emits light over a wide range of wavelengths. When this light passes through gaseous substances (for example, greenhouse gases and volcanic gases in the atmosphere) samples, molecules therein absorb some of the light. By analyzing the changed wavelengths of light, conclusions can be drawn about the composition and optical properties of the analyzed gas.
2. Robust Percolation Transition is an important concept in network theory and complex systems science, essential for understanding the impact of changes in connections within a network on the system's robustness.
3. The light pulses generated by the AERI HEL (peta-exa watt class ultra-High Energy Laser) system, developed by Professor Kazuto Kamuro - the chief research officer of AERI, installed on AERI's ultra-low altitude satellites, induce rotation and vibration of gas molecules of greenhouse gases and volcanic gases in the atmosphere. A special feature of the AWUDS developed by Professor Kazuto Kamuro - the chief research officer of AERI is that the AERI HEL system emits dual light pulses in the ultraviolet spectrum. When these dual light pulses (UV light) encounter gas molecules of greenhouse gases and volcanic gases in the atmosphere, they electronically excite the gas molecules, causing rotational and vibrational transitions (Robust Percolation Transition) specific to the gaseous substance. The AWUDS, with its high spectral resolution, will enable investigation of complex gas mixtures such as greenhouse gases and volcanic gases molecules on Earth in the future. The measurement time for analyzing gas samples will be prolonged.
4. Robust Percolation Transition is one of the important concepts in complex systems and network theory. This transition is a phenomenon caused by changes in connections within a network, and its characteristics are related to the robustness and durability of the system.
5. To understand the background of Robust Percolation Transition, let's consider network percolation. Percolation is the study of how connected components in a network behave by randomly destroying or adding connections within the network. Percolation transition refers to the threshold at which a giant connected component arises in the network due to the addition or destruction of connections.
6. In general percolation, random addition or destruction of connections significantly affects the behavior of the system. However, in Robust Percolation Transition, specific additions or destructions of connections in the network occur under circumstances where they have little effect on the overall structure of the system. Such situations indicate that the system is robust and resistant to external perturbations.
7. Robust Percolation Transition is generally closely related to the characteristics and structure of the network. For example, specific network structures such as scale-free networks and small-world networks are known to exhibit Robust Percolation Transition more prominently. These networks tend to behave as "hubs," where some nodes have more connections than others. Therefore, additions or destructions of connections to hubs may have a greater impact on the overall connectivity.
8. Understanding Robust Percolation Transition is useful for various applications such as optimizing network design and structure, as well as analyzing vulnerabilities. For example, it plays an important role in considering strategies to improve robustness in real-world systems like communication networks and biological networks.
H. The AWUDS installed in the AERI satellite-borne volcanic gas detection system combines three characteristics that conventional spectroscopic systems (spectrometers) have only been able to provide partially until now. The broad bandwidth of emitted UV light means that a large amount of information about the optical properties of gas samples can be collected in a single measurement. "'AERI's AWUDS is suitable for highly sensitive measurements that can accurately observe and monitor changes in gas concentration and the progress of chemical reactions," explained Professor Kazuto Kamuro - the chief research officer of AERI.
I. greenhouse gases and volcanic gases in the atmosphere are generated not only during the combustion of fossil fuels and wood but also from vapors of adhesives used in furniture indoors. AERI's research team developed the AWUDS using formaldehyde and tested it.
J. "Using AERI's AWUDS, the volcanic gas detection system mounted on the AERI satellite, emissions of formaldehyde in industries such as the textile and wood processing industries, as well as in cities with increased smog levels, can be monitored remotely in real-time, 24/7, with in situ monitoring (optical spectroscopic observation and surveillance), enabling improved personnel and environmental protection, thanks to the wide range of greenhouse gas and volcanic gas distributions with a time resolution of 10 billion samples per minute and a spatial resolution of 100 million sampling points per square meter. The AWUDS can also be applied to greenhouse gases and volcanic gases in the atmosphere, such as nitrogen oxides NOx, ozone O3, carbon dioxide CO2, methane CH4, nitrous oxide N2O, hydrofluorocarbons HFCs, perfluorocarbons PFCs, sulfur hexafluoride SF6, carbon dioxide CO2, sulfur dioxide SO2, methane CH4, nitrous oxide N2O, hydrogen H2, carbon monoxide CO, hydrogen sulfide H2S, hydrogen chloride HCl, hydrogen fluoride HF, silicon tetrafluoride SiF4, methane CH4, ammonia NH3, and carbonyl sulfide COS, among others. By enabling AERI's satellite-borne volcanic gas detection system to monitor volcanic gas emissions at a time resolution of 10 billion samples per minute and a spatial resolution of 100 million sampling points per square meter, we expect to make new discoveries about the effects of greenhouse gases and volcanic gas molecules. Based on this, it will be possible to monitor the accurate emissions of greenhouse gases and volcanic gases and derive new strategies for regulating greenhouse gas and volcanic gas emissions on a global scale in real-time, with a time resolution of minutes and 24/7 in situ regulation," emphasized Professor Kazuto Kamuro - the chief research officer of AERI, highlighting future prospects.
END.
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Quantum Brain Chipset & Bio Processor (BioVLSI)
♠♠♠ Kazuto Kamuro: Professor, PhD, and Doctor of Engineering ♠♠♠
・Doctor of Engineering (D.Eng.) and Ph.D. in Quantum Physics, Semiconductor Physics, and Quantum Optics
・Quantum Physicist and Brain Scientist involved in CALTECH & AERI
・Associate Professor of Quantum Physics, California Institute of Technology(CALTECH)
・Associate Professor and Brain Scientist in Artificial Evolution Research Institute( AERI: https://www.aeri-japan.com/ )
・Chief Researcher at Xyronix Corporation(HP: https://www.usaxyronix.com/)
・IEEE-USA Fellow
・American Physical Society Fellow
・email: info@aeri-japan.com
----------------------------------------------------
【Keywords】
・Artificial Evolution Research Institute: AERI, Pasadena, California
HP: https://www.usaxyronix.com/
・Xyronix Corporation, Pasadena, California
HP: https://www.usaxyronix.com/
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