Richard Feynman Portrait Done and Drying.

Richard Feynman Portrait Acrylic Paint.

Used Gesso and Black 2.0 which is interesting, but a little delicate while it’s drying I think the problem was a that I was painting over a gessoed and already painted surface and some of the canvas teeth were not allowing paint in. But it’ll do for now, and I can finally say after years of this dang things reference sitting in my collection that I got a version of it done. It’s not the photorealistic 6×8’ version I had planned but it was a worthwhile nonetheless. Now I’ve got a huge canvas to tackle and then I think I’ve run out of canvas’s to work with and finally start to get rid of them for the move.

Hope you’re well.
-J.

Which subjects would you like me to write about?

I have plenty of time to learn about things while I’m not sleeping.

Things I wish I had. A diamond anvil cell, with multiple rubies and perhaps a pulse laser to force greater pressure down. Something to build carbon structures with like a u.v. laser printer. An x-ray analyzer to understand flow better. A CVD I could reformat to do what I want to show you the new materials I can make from an altered one.

Let me know and I’ll see what I can do.

-J.

Some basic piano improvisations I’ve been tinkering with.

Found out mum was in hospital again.

There was going to be more pieces but soundcloud cut me off at my 3 hour mark.
I have about roughly 130 songs between my phone and ipad, but I only learned about trying to get your heavy breathing out of the track in the last week or so, so a lot of the music is what I would call ruined by a fat mans breath. Oh well. Learn and get better hopefully.
-J.

Quantum computers using photons and electrons.

Quantum computers using photons and electrons.

Photons have spin-1, electron 1/2. Meaning you could condense the number of way electrons at certain speeds and qutrits by using photons to cancel out the spin of unneeded number increasing output speed. At least for spun waves.

Wikipedia.

Quantum entanglement means there would be a -1/2, +1/2 electron spin. If a proton was spun at it +1 it would become 1/2 and +1.5 for the +1/2, while a quantum entangled proton with -1 become -1.5, -1/2. Meaning you could divert three +/-1 times the number of electrons into the proton entanglement getting up to 4 times the output (certainty of randomness?) As the single entanglements would negate to zero or be interfered again with light.

Would it also mean that if the entangle particles collapsed before the photon affected ones did you would lose the effect of their interaction or would the new state remain constant to become something useable as a boundary box for the qubit and qutrits inside?

Especially if you combine layering of qutrits and qubits.

Couldn’t you arrange the three in staggered stages so that as they collapse in their given direction the peaks combined with the spun protons carry information further into the system juicing the qubits and qutrits much further than pure quantum entanglement.

Need to learn about the Bell states more. And Not gates.

Quantum connection (not all gates shown). I realised I forgot some negative signs. I was thinking of this as a layer in a multilayered stack offset to each other diagonally around the center 1.5/-1.5.

So this doesn’t include all not gates drawn nor regular gates drawn but to give an idea of what photons could do increasing the spin of an electron without being an electron spun up to light speed (cooling advantage. May be able to run off new leds). But we have

14 1.5 transactions. (1/2, -1.5, -1/2, +1/2)

12 1/3 transactions. (1 1/3, -2/3, -1/3, +1/3)

56 1/2 transactions. (28 1/2, 28 -1/2)

Of which the

1.5, 1.3, 2/3, 1/3, 1/2 positives also have

-1.5, -1.3, -2/3, -1/3, -1/2 negatives.

Some of bonds are due to quantum entanglement and could create new reversible and non reversible gate types as well as length the entanglement between bits as they are produced.

Then again couldn’t quantum dots be shown down through a material to not expend as much heat and you run it off various leds types and it’s a room temperature quantum computer.

Wikipedia.

Quantum dot gets excited and releases electron into conductance band first into the system to get electron spin then lowered back to valence band to get (with uv help) emitting light so you can get different size quantum artificial atoms as well as colors for emittance. Multilayered quantum computing at the true speed of quantum dots light limited by uv pulse output.

Just an idea.

-J.

A Friend Overdosed on Heroin a few days ago.

So I made these for one of his memorials my brother is fielding.

Colour Version.
Black on White Version.
White on Black Version.
To make something like this to remember him by.

The reason for making all three is so that if you pick a different colour you’ll have the chance to have the design. Basically so you can put it on both dark or light material and see the image. I personally like the triple version of the piece as it sort of reminds me of him more for some reason. Perhaps it’s the multiplication of things sort of deal; seeing more of someone makes you think of them deeper.

I couldn’t afford to send one to my little brother, who was good friends with this man– but I was able to send him the files to create the shirts for him and his friends, or at least get them print outs somewhere as seat fillers so everyone can remember him fondly.

I have to say he suits that jacket.

Bye man,
Sorry for the short life.
-J.

Getting back to work after a small hiatus. Also Carbyne/Graphyne Prism Ropes.

Sorry again for the lack of updates. I’m sitting here listening to Andy, you’re a star by The Killers. It plays along with my illness and seems to keep me stable enough to get work done.

What I’m wondering is what to work on now. I’ve been futzing with super capacitors and talking with Professor Sadoway at MIT about a dry electrolyte batteries, just starting my self education on them. I got it wrong the first time thinking that Quantum Tunneling would take care of the voltage transfer of Lithium+ between Mg+2, so I followed his instruction and tried again using a material developed by another group within my Cathode and Anode. I’m unsure if they work as of yet since he’s not gotten back to me, but I’m assuming he’s a much busier man than I would ever be.

I never heard back from Ravenda at Duracell so they must not be interested in the super capacitor or stretchy AC->Semiconductor->full insulator if given enough material (though I likely did the maths wrong for that amount needed part–I hadn’t slept for a while on my new medication). They’ve given me Ritalin in small doses to help with weight loss and it’s hopefully working. Waking up at 3 a.m. is odd but I’m used to it now. But that’s not the point of this message.

I should be working on my comic but my first patent will be hopefully ready for submitting on October 23rd since it’s finally out of my slow ass hands. I keep waking up with new ideas.

A second form of Carbyne Prism came to me today. It should offer the same properties as the first version but only need one form of stretch to reach the same output, but be three times as effective as it’s not limited to one line of the material repeated, but joined between itself. And whats great is that you can fold the bonds in a triangle to get 6x the times of connections and still close of the ends and get some real interesting flow states. Think of it as prismatic rope. Each unit can minimally be 6 carbon atoms long, but unlimited by an additional 3-1 bond conditional arrangement. Minimum arrangement times 3 by 2 shown. You could even make a new form of lattice with the middle bond where you could join the ropes. Though those would be Graphyne. 2-2 bonds.