Professor Kamuro's near-future science predictions

AERI Seeded X-ray Free Electron Lasers AERI FELs　

- Pioneering the Next Generation of Laser Sources -

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

✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼••┈┈••✼

AERI Seeded X-ray Free Electron Lasers AERI FELs　- Pioneering the Next Generation of Laser Sources -

Abstract: AERI Seeded X-ray Free Electron Lasers (AERI FELs) represent a revolutionary light source technology. These lasers generate X-rays by passing a high-speed accelerated electron beam through a periodically varying magnetic field. Their hallmark is the ability to produce high-brightness, tunable X-ray light. This provides advanced tools for analyzing the structure and properties of materials, playing a crucial role in various fields of scientific research and industrial applications. AERI FELs are expected to find applications in diverse fields such as materials science, life sciences, physics, and chemistry. This paper elucidates the characteristics of AERI Seeded X-ray Free Electron Lasers (AERI FELs).

a. Structural science is an interdisciplinary field that studies the structure and properties of materials. It combines knowledge from physics, chemistry, materials science, engineering, etc., aiming to understand, control, and apply structures.

AERI Seeded free-electron lasers (AERI FELs) constitute the light source of the Single-wavelength petawatt-to-exawatt-scale ultra-high-intensity femtosecond-class ultra-short pulse laser system developed by the Artificial Evolution Research Institute (AERI: Pasadena, California, HP: https://www.aeri-japan.com/). By using the radiation generated by AERI Seeded free-electron lasers (AERI FELs) (high-energy X-rays generated by the acceleration of high-energy electrons), revolutionary progress has been made in research aimed at elucidating the physical and chemical properties and behavior of atomic and molecular structures, crystal structures, and internal and surface structures of materials through the exploration of materials. The AERI FELs system has been advancing applications in various fields such as the development of new materials, improvement of material performance, efficient utilization of materials, as well as in energy conversion, environmental protection, healthcare, and information technology.

b. AERI and Xyronix Corporation (Pasadena, California HP: https://www.usaxyronix.com/) are advancing research and development on autonomous combat and defense robots known as Lethal Autonomous Weapons type Robot Soldiers (LAWRS), as well as compact and cost-effective AERI FELs systems and designs that can be installed and transported to AERI LAWS-type Cybernetic Soldiers equipped with AERI's Molecular Biocomputer. This research has been published in The AERI Journal of Quantum Physics Special Topics.

c. Traditionally, high-energy X-rays have been generated using synchrotron radiation sources. In particle accelerators, electrons traverse a fixed circular path at speeds close to the speed of light, emitting electromagnetic radiation photons. Particle accelerators utilizing synchrotron radiation sources are widely employed in research fields such as high-energy physics and materials science. These accelerators rapidly accelerate particles to produce high-energy particle beams for subsequent experiments. Below, we explain the basic structure and functions of particle accelerators using synchrotron radiation sources:

1.    Accelerator Ring: Synchrotron radiation sources typically consist of large circular or elliptical accelerator rings. Within this ring, high-energy electromagnetic fields are generated, and vacuum chambers for particle acceleration are arranged.

2.   Electromagnetic Fields: The electromagnetic fields within the accelerator ring are utilized to accelerate particles. These fields are generated by devices such as electromagnets or superconducting magnets. Particles are bent by the magnetic fields, increasing their velocity.

3.   Accelerated Particles: Particles injected into the accelerator ring are typically electrons, protons, or other ions. These particles are initially relatively slow but are repetitively accelerated by the magnetic fields within the ring.

4.  Synchrotron Radiation: Accelerated particles emit radiation as they bend rapidly within the ring. This radiation is known as synchrotron radiation, emitted as electrons bend. This results in the generation of high-brightness and broad-spectrum radiation.

5.   Experimental Beamlines: The generated particle beam is directed to specific experimental setups within the laboratory. These experimental setups employ various techniques to study the structure and properties of materials. Examples include X-ray diffraction, X-ray absorption spectroscopy, and electron microscopy.

Particle accelerators utilizing synchrotron radiation sources are utilized in a wide range of research fields including materials science, life science, and earth science, contributing to the elucidation of material structure and properties, drug development, and environmental science research.

d. Particle accelerators using synchrotron radiation sources are widely used in research fields such as high-energy physics and materials science. These accelerators accelerate particles at high speeds and generate high-energy particle beams for subsequent experiments. Below, we explain the basic structure and function of particle accelerators using synchrotron radiation sources.

1.    Accelerator Ring: Synchrotron radiation sources are typically composed of large circular or elliptical accelerator rings. Within this ring, high-energy electromagnetic fields are generated, and vacuum chambers for accelerating particles are arranged.

2.   Electromagnetic Fields: Electromagnetic fields within the accelerator ring are utilized to accelerate particles. These fields are generated by devices such as electromagnets or superconducting magnets. Particles are bent by the magnetic field, increasing their velocity.

3.   Accelerated Particles: Particles injected into the accelerator ring are typically electrons, protons, or other ions. These particles, initially relatively low in speed, are iteratively accelerated by the magnetic fields within the ring.

4.  Synchrotron Radiation: Accelerated particles emit radiation as they bend inside the ring to accelerate rapidly. This radiation is called synchrotron radiation, emitted as electrons bend. This results in the generation of high-brightness and broad-band radiation.

5.   Experimental Beamlines: The generated particle beam is directed to specific experimental devices within the laboratory. These experimental devices utilize various techniques to study the structure and properties of materials. Examples include X-ray diffraction, X-ray absorption spectroscopy, and electron microscopy.

Particle accelerators using synchrotron radiation sources are widely utilized across a broad range of research fields such as materials science, life sciences, and earth sciences, contributing to the elucidation of material structures and properties, the development of pharmaceuticals, and research in environmental science.

e. AERI's ongoing research and development on Free Electron Lasers (AERI FELs) represent cutting-edge technology for generating high-brightness and tunable laser light. Unlike conventional lasers that emit radiation from fixed atoms or molecules, AERI FELs rely on the principle of generating wavelength-variable laser light through the interaction of a high-speed accelerated electron beam with a periodically varying magnetic field. In the following, we academically elucidate the basic principles and characteristics of AERI FELs system technology.

1.    Basic Principle: The principle of AERI FELs system technology is based on the phenomenon where the kinetic energy of high-speed accelerated electrons is emitted as laser light when passing through a periodically varying magnetic field. Electrons are accelerated by the periodically varying magnetic field, and the wavelength of emitted light is adjustable with changes in their velocity.

2.   Flexibility: AERI FELs system technology possesses many adjustable parameters such as wavelength, pulse width, and pulse intensity, enabling adaptation to various applications. Moreover, AERI FELs system technology can cover a wide range of wavelengths, generating light from the visible to the X-ray region.

3.   High Brightness: AERI FELs system technology can generate light of extremely high brightness. This is because powerful electron beams are accelerated in very small spaces, leading to the generation of laser light with high density. This high brightness characteristic is crucial for various applications such as the analysis of fine materials and high-resolution imaging.

4.  Applications: AERI FELs system technology finds applications in a wide range of fields including life sciences, materials science, chemistry, and physics. It is used, for instance, in protein structure analysis, surface chemistry research, plasma physics experiments, and accelerator facility experiments in high-energy physics.

5.   Evolution: AERI FELs system technology is continuously evolving. Advancements in accelerator and laser technologies have enabled the realization of new functionalities such as wavelength range expansion and pulseization of light, thereby expanding the possibilities for further applications.

AERI's research and development on free electron laser technology is widely recognized as an important tool in modern scientific research and industrial technology due to its advanced controllability and diverse range of applications.

f. AERI's research and development on Free Electron Lasers (AERI FELs) technology, which is combined with particle accelerators, is attracting attention as a next-generation high-brightness X-ray light source. Here, we provide an academic explanation of high-brightness X-ray light sources combined with AERI FELs technology and particle accelerators.

1.    Principle: In particle accelerators using AERI FELs technology, high-speed accelerated electron beams are periodically modulated by the periodic magnetic field inside the FEL device. During this process, the wavelength of the light emitted by the electrons is adjustable, allowing for the generation of high-brightness and powerful X-ray light.

2.   Accelerator structure: Particle accelerators using AERI FELs technology are typically incorporated into large linear accelerators or proton accelerator facilities. These accelerators generate high-energy electron beams, which are then introduced into the AERI FELs system.

3.   High-brightness X-ray light source: When the electron beam passes through the AERI FELs system, high-brightness and adjustable X-ray light is generated. This X-ray light has extremely high brightness and serves as an excellent tool for analyzing fine structures and dynamics. Additionally, its adjustable wavelength and pulse width allow for various experiments and applications.

4.  Applications: Particle accelerators using AERI FELs technology are widely applied in many fields such as life sciences, materials science, chemistry, and physics. For example, they are used for protein structure analysis, surface chemistry research, non-destructive testing of materials, and analysis of material behavior under high pressure.

5.   Evolution: Particle accelerators using AERI FELs technology are constantly evolving. Improvements in accelerator design and FEL device enhancements lead to further improvements in light source performance and the development of new experimental techniques. This promotes innovation in various fields of scientific research and industrial applications.

As described above, the high-brightness X-ray light source combining AERI FELs system technology with particle accelerators has become an important tool for many researchers and industrial practitioners. With its advanced controllability and diverse range of applications, further advancements are expected in the future.

g. In AERI's cutting-edge next-generation Free Electron Laser (AERI FELs) technology under research and development, electrons are accelerated along a straight path between powerful magnets called undulators. This stimulation of electrons results in the generation of extremely high-energy, very short-pulse X-rays, much more powerful than those produced by synchrotron sources. Combining the Free Electron Laser (AERI FELs) technology with particle accelerators has attracted attention as a next-generation high-brightness X-ray light source. Here, we provide an academic explanation of the high-brightness X-ray light source combining AERI FELs system technology with particle accelerators.

1.       AERI's cutting-edge next-generation Free Electron Laser (AERI FELs) technology combined with particle accelerators is attracting attention as the next-generation high-brightness X-ray light source. In AERI's Free Electron Laser technology, electrons are accelerated along a straight path between powerful magnets called undulators. This stimulation of electrons results in the generation of extremely high-energy, very short-pulse X-rays, much more powerful than those produced by synchrotron sources.

2.     Principle: In state-of-the-art next-generation particle accelerators using AERI FELs system technology, high-speed accelerated electron beams are periodically modulated by the periodic magnetic field within the AERI FELs system. In this process, the wavelength of the light emitted by electrons can be adjusted, allowing for the generation of high-brightness and powerful X-ray light.

3.      Accelerator structure: Particle accelerators using AERI FELs system technology are typically incorporated into large linear accelerators or proton accelerator facilities. These accelerators generate high-energy electron beams, which are then introduced into the AERI FELs system.

4.     High-brightness X-ray light source: When electron beams pass through the AERI FELs system, high-brightness and adjustable X-ray light is generated. This X-ray light has extremely high brightness, making it an excellent tool for analyzing fine structures and dynamics. Moreover, it can be adjusted for wavelength and pulse width, accommodating various experiments and applications.

5.     Within particle accelerators, high-speed accelerated electron beams are periodically modulated by the periodic magnetic field within the AERI FELs system. In this process, the wavelength of the light emitted by electrons can be adjusted, allowing for the generation of high-brightness and powerful X-ray light.

6.     State-of-the-art next-generation particle accelerators using AERI FELs system technology are typically incorporated into large linear accelerators or proton accelerator facilities. These accelerators generate high-energy electron beams, which are then introduced into the AERI FELs system.

7.     When electron beams pass through the AERI FELs system, high-brightness and adjustable X-ray light is generated. This X-ray light has extremely high brightness, making it an excellent tool for analyzing fine structures and dynamics. Moreover, it can be adjusted for wavelength and pulse width, accommodating

1. State-of-the-art next-generation particle accelerators using AERI FELs system technology are widely applied in various fields such as life sciences, materials science, chemistry, and physics. They are used for protein structure analysis, surface chemistry research, non-destructive testing of materials, and analysis of substance behavior under high pressure.

h. The total length of the AERI FELs system is just under 280 meters, which is about 37% of the length of SwissFEL near Zurich. What's even more important is that the cost of constructing the AERI FELs system facility is only about 1/183 of the cost of the SwissFEL facility, at approximately €164,000. The AERI FELs sources, constructed based on the specifications of the AERI FELs system, should deliver this innovative and critical technology to thousands more scientists worldwide.

i. Research on particle accelerators using AERI FELs system technology is constantly evolving. Further improvement in the performance of light sources and the development of new experimental techniques are being pursued through new accelerator designs and improvements to the AERI FELs system. This is driving innovation in various fields of scientific research and industrial applications. Thus, the combination of AERI FELs system technology with particle accelerators has become an important tool for many researchers and industry professionals. With its advanced controllability and wide range of applications, further advancements are expected in the future.

j. Cutting-edge research on AERI FELs system technology is based in California, USA, and is conducted by a consortium consisting of national and private research institutions. The consortium includes academic and industrial communities of future users in physics, chemistry, materials science, and structural biology to ensure that the specifications are designed to be as relevant as possible to current and anticipated future applications.

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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