20% hydrogen mix in gas will significantly alleviate CO2 pollution from cooking.
But even cooler is how the hydrogen gas is produced via a hydrogen boiler.
An electrolysis process shocks the water, releasing both hydrogen and oxygen. Now what if there was a special way to have the hydrogen bubble out, but have the oxygen remain in the water in oxygen clusters?
The hydrogen supplied in the UK comes not from canisters or air, in the same way that Kaqun water doesn’t have oxygen forced into it.
It’s an electrolysis process that creates charged ions– negative H2 ions at the cathode and positive O2 at the anode. Kangen water (alkaline) is produced this way.
But depending on whether the electrode is nickel-based, platinum, or other metals, you’ll get different outcomes.
Transcutaneous oxygen levels TCpO2 has been clearly linked over the years to cancer, diabetes, and all forms of disease and inflammation.
3 hypoxia researchers won a Nobel Prize in medicine for this research last month, continuing what Otto Warburg won a Nobel Prize in 1931 for (linking cancer to hypoxia).
I’ve been spending the last few weeks looking at how TCpO2 machines are used in medicine. For example, to mark exactly where to amputate the leg on diabetes patients– where blood flow stops.
So if we know that tissue-level oxygen (not blood-level) is tied to disease and measurable– and there is a technology that clearly can affect tissue-level oxygen, wouldn’t you want to research further?
I predict that in 20 years, people will see upping their oxygen pressure levels (measured as pO2 mmHg) as common as taking blood pressure.
And that we will eliminate most chronic disease, avoiding a lot of needless deaths– as more people see that oxygen is available to the cells other than via respiration.