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Damaged computer due to shorts this past Wednesday was replaced. We’re ready to continue experiments tomorrow. A back up scope, used, was ordered from South Korea—just in case, today. A backup data computer was built in addition to the primary replacement. We’ve got an upgraded OS. Scope drivers for the new OS (we're talking old oscilloscopes) were found after some research thanks to Texas Instruments.

There are three peaks in this graph, showing multiple pinch effects (Ampere's Law in action affecting the filaments bonding together as charges travel in the same direction.) That disperses the energy, so a single pinch will get us still higher yield in a future shot (experiment).

This is a high voltage trace from shot 5 of June 26, 2019. This was the second to last experiment this past Wednesday, before our data computer fried (without showing any visible signs of it inside the case.) This is our highest fusion yield so far this year, 1/10th J with the electrodes.

On Thursday we faced a fried motherboard and began quick DIY action...which I will document in a next post as we put the new components together. We expect to be done with this quickly so experiments can resume by Monday. Stay tuned.

Sorry for the noise...basically the interpretation is the green line was not as wild as it looks...the possible shorts are elsewhere (chamber gas line, not shown here, is concerning...but not threatening)...The physical threats do exist, to machine and control room equipment...The IT team identified a high probability of the data computer frying despite the Faraday cage used for all diagnostic devices including the data computer...

Generally the yield trend is showing growth but it takes dozens of shots (experiments) for that trend to continue. It’s a bit of a dance: two steps forward one step back...with unknown steps in between. The images are of data on the scopes after shot 2 from Wednesday, June 26. See the next post for a bit of an "on the spot" interpretation by the chief scientist Eric Lerner.

In case you are wondering, here's the line on the anode we were talking about—it's on the right. It disappeared in the next few shots. We don't know what caused it.

Another way we measure fusion yield is our silver activation counter and a third way is from our bubble detectors (featured in future posts--stay tuned.)

The image is the raw data from our Far Time of Flight detector (FTF) which shows the arrival of the X-ray peak (small peak at left) and the slower neutrons (big peak at right). Vertical scale is volts and horizontal is time in ns (billionths of a second). From shot 6, June 18. The height of the big peak at right is one way we know we have more fusion yield, as we are now working with deuterium, which produces neutrons from fusion reactions.

We tracked them down and fixed them. Also, the appearance of the anode continues to evolve from shot to shot. After one shot, a horizontal line appeared on part of the anode, but then disappeared a couple of shots later. For symmetry the anode has to settle down to the same appearance—and thus the same smoothness—everywhere. This will take some time.

We’re now over 30 shots and we have tripled fusion yield over last week. Not time yet to break out champagne, as we are still a factor of 4 short of our own record yield of ¼ joule. But going in the right direction. We’ve scanned from low to high fill pressure and we have found the sweet spot for now. Improvements are still needed. For one thing, was making too much noise when it fired—from shorts or arcs somewhere outside the vacuum chamber.

The clean-up has to proceed further to get good symmetry. We’re not sure how fast it will go, so patience, focus fusion fans! Other good news is that our new ceramic switches are functioning well, as are three new instruments: two Langmuir probes for the ion beam and an electron beam Rogowski coil.

Beryllium experiment started! In the first week, we fired 13 shots, starting June 4. As anticipated, first shot vaporized thin beryllium oxide layer, creating dust. Good news is that the dust is steadily being cleared off, with very little evidence of additional erosion, in contrast to heavy early erosion with tungsten. We started to get measurable fusion on third shot and fusion yield has gone up ten-fold since then. However, not close to a record yet.

This slide rule belonged to Melvin Lerner, the father of LPPFusion Chief Scientist Eric Lerner. Melvin Lerner was a leading analytical chemist and scientific administrator, for over 20 years Director of Technical Services for the US Customs Bureau. He was a pioneer in the chemical analysis of marijuana and developed new techniques in statistical analysis and sampling.

On June 4, LPPFusion Director of Communications Ivy Karamitsos officially renamed our device “Focus Fusion 2B” or “FF-2B” for short. It is “2B” for its beryllium electrodes and boron fuel (to be used later this year) but also because it is “focus fusion to be”. Traditional renaming of people, such as knighting, used ancestral obsolete weapons (King Arthur’s sword for example). So our peaceful scientific ceremony used an ancestral obsolete scientific calculator—a slide rule!

"Could the Green New Deal Work? The Necessity of Fusion" is available on YouTube. Thanks to David Szalyga for uploading the recording so quickly!

What does it matter what really is? In part 5 of the “Is it Really a Black Hole Series”, LPPFusion Chief Scientist Eric J. Lerner points out that discoveries in astrophysics can have profound impacts here on earth.

LPPFusion President and Chief Scientist Eric J. Lerner will present proposals for “A Faster Route to Fusion” at the Fusion Energy Symposium, a hearing sponsored by NJ State Senator Joe Pennachio (R-26) at the State House Annex in Trenton NJ.

In part 4, LPPFusion Chief Scientist Eric J. Lerner explains that most astrophysicists don’t consider the possibility that condensed objects can be plasmoids because they are using a wrong approximation to calculate plasma behavior.

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