FAQ
Technology
Hydrogen has a quantum matter state, H(0)?
Yes, Professor Leif Holmlid discovered this as the first in the world in 2009. H(0) is a quantum fluid, and behaves in ways like no other matter.
For instance its electron cannot be excited (orbital angular momentum l = 0), so it does not emit any light and is thus invisible to our eyes, but it can be studied with other instruments.
It is also the most dense form of matter with an extremely high density of 130 kg/cm^3 and interatomic distance of only 2.3 pm. In this state spontaneous nuclear processes happen, and these processes can be controlled and intensified.
Is there any problem to create H(0)?
We have created H(0) thousands of times. It is not a difficult process, but you need the right equipment to do it.
Most of this research has been done by researchers at Gothenburg University, Sweden. But also researchers in Norway and Iceland have worked on H(0) reactors.
There is a review article from 2021, peer-reviewed, about the production of H(0): https://www.sciencedirect.com/science/article/pii/S0360319921008144
Where can I read more about H(0)?
There are now about 65 published and peer-reviewed articles about H(0), with extensive documentation. In 2019 a review article, peer-reviewed, was also published about H(0) and how this relates https://iopscience.iop.org/article/10.1088/1402-4896/ab1276/pdf
Matter-antimatter annihilations - how does that happen?
We observe nuclear processes in H(0). These radiate high energetic subatomic particles, that are extensively documented as kaons, pions, muons and leptons. And the subatomic particles are identical to the matter-antimatter annihilations seen at CERN.
The energy output is equal to matter-antimatter annihilations, explained in this peer-reviewed article: https://www.sciencedirect.com/science/article/pii/S0360319921004080
The creation of inexpensive antimatter - how does that happen?
In 1999 NASA said that the cost of 1g antihydrogen was $62.5 trillion. The cost has been extremely high because it requires large particle accelerators, and the amount created has been very small.
At LazeraH we can produce antimatter very inexpensively. Once we have created H(0) the antimatter is formed spontaneously in our reactors. And within 1 nanosecond it reacts with matter to transform the atomic mass to energy. The extensive documentation of high energetic subatomic particles is solid evidence.
Professor Leif Holmlid believes the mechanism is an electron capture (beta capture) in H(0), which forms a fee neutron or anti-neutron, or that the neutron oscillates between neutron and antineutron – like for instance the D0 meson has been documented to do.
Are there any problems with radiation or nuclear waste?
The beauty with the process is that all the atomic mass is transformed to energy. So there is no dangerous nuclear waste and very little radiation.
We constantly check for gamma and for neutrons, and we see only low intensities, and it is not dangerous for people.
Are there any third party validations?
There have been 2 research groups in Norway and Iceland documenting and validating key parts in peer-reviewed published articles:
- 21st August 2024: Experimental apparatus for condensed excited hydrogen research, by S.A. Zeiner-Gundersen and S. Olafsson. Science Institute, University of Iceland. https://iopscience.iop.org/article/10.1088/1748-0221/19/08/P08014
- May 17th 2024. Nature of spontaneous signal and detection of radiation emitted from Hydrogen Rydberg, S. Zeiner-Gundersen∗ and S. Olafsson. Science Institute, University of Iceland. https://pubs.aip.org/aip/adv/article/14/5/055124/3294027/Nature-of-spontaneous-signal-and-detection-of
- April 2024. Properties of laser-targeted Rydberg Matter with changes in pressure and magnetic field. Tor Håvard Aasen, Kaiying Wang. University of South-Eastern Norway https://www.sciencedirect.com/science/article/pii/S2468023024003900
- 2019 – Decay of muons generated by laser-induced processes in ultra-dense hydrogen H(0). Sveinn Olafsson, PhD physics, Professor at University of Iceland and Professor Leif Holmlid at Atmospheric Science, Department of Chemistry and Molecular Biology, University of Gothenburg. https://www.researchgate.net/publication/333618942_Decay_of_muons_generated_by_laser-induced_processes_in_ultra-dense_hydrogen_H0
June 15th 2021 – Laser-induced annihilation: Relativistic particles from ultra-dense hydrogen H(0). Sveinn Olafsson, PhD physics, Professor at University of Iceland and Professor Leif Holmlid at Atmospheric Science, Department of Chemistry and Molecular Biology, University of Gothenburg. https://www.sciencedirect.com/science/article/pii/S1574181821000185?via%3Dihub
Market Potential
How big is the market potential for our technology?
The market potential is to provide a superior energy solution to the world, addressing a $7-8 trillion global market.
Are there any competitors operating in your field of proton-antiproton annihilations?
No, there are no commercial players in this area today. Research institutions like CERN have conducted successful experiments on annihilations, using their $4b particle accelerators. The difference is that LazeraH has found and invented a way to create anti-matter inexpensively.
What is your business model?
In the first phase LazeraH will develop energy reactors suitable for households and small to medium-sized industries. The business model will be selling reactors and recurring revenues from energy generation.
What is the biggest challenge ahead, and how are you addressing it?
The biggest challenge is building up credibility for the company and the technology, as it sounds too good to be true, and it involves anti-matter physics that is not well-understood or well-studied in the scientific community.
We address this by documenting the experimental results thoroughly, publishing articles that are peer-reviewed, being open for lab-visits, and we seek 3rd party validation of results.
What key characteristics are you looking for in investors to support your next phase?
Trust. We seek investors who actively want to support us, help build credibility, and who wants to find solutions when problems arise. Also experience in deeptech and physics would be an advantage, or deep experience from the energy world, to help us navigate in the years ahead.
Why is 2025 the right moment to invest in LazeraH’s innovative technology?
In 2025 our goal is to demonstrate Net Positive Energy and to have it 3rd party validated. This milestone is a game changer not only for LazeraH but for the world, and with comparable valuations of other fusion companies (all far from this milestone) it is reasonable to believe that LazeraH will reach a multi-billion dollar valuation for the next round. Tier-1 investors are likely to be very interested in investing after hitting this milestone, thus the timing of 2025 is the right moment for investors in search of outlier returns.
Recommended research articles
- 249: ”Energy production by laser-induced annihilation in ultradense hydrogen H(0)” L. Holmlid. Int. J. Hydrogen Energy 46 (2021) 14592-14595.
- 250: “Production of ultra-dense hydrogen H(0): a novel nuclear fuel” L. Holmlid, A. Kotarba and P. Stelmachowski,. International Journal of Hydrogen Energy 46 (2021) 18466-18480.
- 243: ”Ultradense protium p(0) and deuterium D(0) and their relation to ordinary Rydberg matter: a review”. L. Holmlid and S. Zeiner-Gundersen, Physica Scripta 74 (7) 2019
- 251: “Laser-induced annihilation: relativistic particles from ultra-dense hydrogen H(0)”. L. Holmlid and S. Olafsson, High Energy Density Physics 40 (2021) 100942