Our Technology & Venture
Solar WAVE (e.m.) Nano-Antenna Project
Our Current Goals:
+ Electromagnetics (EM) of Sunlight Waves:
Investigate how sunlight waves interact with specific materials or are emitted under certain conditions along orbital paths.
+ Optical Nano-Antennas Made of Plasmonic Materials
Focus on nano-antennas composed of plasmonic materials (e.g., metals and certain semiconductors).
Key details:
- Nonlinear plasmonic nano-antennas hold great promise for efficiently generating and controlling nonlinear optical responses at deeply subwavelength, nanometer-scale dimensions.
- Plasmonics involves the manipulation of optical signals at the nanoscale (on the order of a billionth of a meter), particularly at metal-dielectric interfaces.
- Inspired by photonics, plasmonics leverages the unique properties of metallic nanostructures to route light signals at near-atomic scales.
+ Our Solar WAVE (e.m.) Electricity Project Research was invited to present at major conferences in the United States: IEEE (2016) in Porland, Oregon and AIChE (2022) in Phoenix, Arizona.
We hope Our DISCLOSE to public this research will bring this SOLAR FREE to LIFE QUICKLY.
Call INVESTORS for $2 Million Dollars.
+ The Sun is an unlimited, God-given, free hot pot.
+ The current state of solar photovoltaic (PV) semiconductor panels is characterized by relatively low efficiency and high material and production costs.
+ Notably, Silicon Valley- the capital of electronics and communication technologies- dropped out of the race to become the next breakthrough "Solar Valley." This left behind a wealth of valuable research. In 2013, I (Winston Vo) jumped at the opportunity to pick up where it left off. I started by buying a lot of books and leasing an office in Green Hills (Nashville, Tennessee), even though I was working with a limited budget from my technician job.
+ Electricity is beamed back to Earth's surface using high voltage (as planned by NASA), but this could potentially destroy or make a large area uninhabitable. In the future, with advances in technology, we might even be able to "zip" or compress electricity- similar to how we compress large files for storage on computers. This is just my assumption.
+ A nano-antenna technology was already developed by 2010 through a collaboration between the Department of Energy (Contract DE-AC07-05ID14517) and the Idaho National Laboratory (D. K. Kotter & S. D. Novack). However, it was not utilized at the time, as researchers believed the electromagnetic energy from sunlight was too weak- based on longstanding assumptions dating back to Newton and even Einstein’s quantum physics.
+ In 2011, a group of researchers at the University of Michigan found that, at the right intensity, when light travels through a material that does not conduct electricity, the light field can generate magnetic effects that are 100 million times stronger than previously expected.
The concept of the Optical Antenna was initially introduced in the 1970s and revisited in 2012 with the development of the Rectenna. However, both technologies are still considered relatively weak and remain uncompetitive compared to modern photovoltaic (PV) semiconductor panels.
+ The dual wave-particle nature of sunlight has been recognized since Newton's time and was later reinforced by Einstein's quantum theory of light.
+ In 2011, a group of researchers at the University of Michigan found that, at the right intensity, when light travels through a material that does not conduct electricity, the light field can generate magnetic effects that are 100 million times stronger than previously expected.
+ The wavelength or type of sunlight influences a photon-drift effect in a solar cell. However, the strength of this drift is primarily determined by the cell’s material—typically a compound semiconductor or thin film. Our understanding of these materials is largely inherited from current practices in solar photovoltaic (PV) semiconductor panel research. This existing body of knowledge offers valuable resources that can accelerate and refine our efforts in the Solar Wave Project Research Business.
+ In 2011, a group of researchers at the University of Michigan found that, at the right intensity, when light travels through a material that does not conduct electricity, the light field can generate magnetic effects that are 100 million times stronger than previously expected.
+ Research into the wave-particle characteristics of sunlight and nano-antennas was conducted long ago, but the resulting electromagnetic output was considered weak. Yet I recognized its potential as my fortune- back in 2013. Even now, I remain alone in this pursuit.
Since losing my engineering position with Honeywell's Control Systems Consulting in Houston, Texas, I’ve held many jobs, but only in technician roles. That’s been a frustrating limitation for someone with my background: I graduated cum laude from Vanderbilt University in May 1998 with a double major in Chemical Engineering and Applied Mathematics. I was also among the first 28 newly graduated chemical engineers selected for a six-month training program by Honeywell Inc., preparing for the Y2K Millennium transition.
+ Seeking investors to fund the selection of valuable insights from books and articles, with the option to outsource further research to graduate students and faculty at select universities.
+ Will not build a large internal team.
+ The nano-antenna and electromagnetics (E.M.) returned to the stage in 2010, but faded out again shortly afterward. I am alone, but I enjoy these enriched resources and also find the ongoing technology useful.
+ Caltech [California Institue of Technology] is actively participating in the space race for solar electricity, leveraging photovoltaic semiconductor panel technology in line with current market trends and research. At the same time, it continues to pursue traditional research in materials science, fabrication techniques, and nanotechnology.
Website: https://www.spacesolar.caltech.edu
+ Fraunhofer Institute for Solar Energy Systems (ISE) and University of Freiburg, Germany that I was formerly affiliated with:
- The Training & Research Center for Photovoltaic Technologies, focusing on materials, fabrication, nanotechnology, energy storage, production, and system integration.
- The leading organizer of solar energy conferences in Europe and the United States, and a key provider of industry exhibitions.
Website: https://www.ise.fraunhofer.de/en.html