I thought director Budil made a good case for the unique value of public
funding of science and advanced technology. Rockets are understood, Musk and
others can build them. Decades of investment to do something like this is, it
is just different. And they were not timid about mentioning the defense side.
Concurrent with the test of a U.S. hypersonic too.
https://www.defensenews.com/air/2022/12/12/air-force-conducts-first-operational-launch-of-arrw-hypersonic-missile/
On Dec 13, 2022, at 10:16 AM, Steve Smith <sasm...@swcp.com> wrote:
Great synopsis... thanks.
I'm fascinated at how long we've been "on the cusp" of "lighting up" a
micro-star in the laboratory.
My first awareness was in the early 70s when a Radio Engineer I worked with had
just come from the early MFE Livermore efforts to my tiny hometown AM RAdio
station... He described what they were up to as I was taking my first physics
course (Junior in HS)... and thinking about the implications both for science
(as little I knew it) and society (cheap/ubiquitous energy). Working at LANL
for 3 decades (starting with the high energy Proton Storage Ring) put me close
to lots of this as an "educated layman".
I can't say "nothing's changed" but it is mind boggling how long one can "hang
on the cusp" of something. Or how quickly we can go from burning coal to make
steam to drive mechanical devices to replace animal and human (and water and
wind) labor to lighting up tiny stars for the same purpose.
- Steve
"some days just drag on, but the years they just fly by"
Awesome. Thanks. I'm still trying to catch up with the QC Wormhole kerfuffle.
Who knew Quanta was so click baity?
What is "DT"?
On 12/13/22 09:02, Marcus Daniels wrote:
In case no one wanted to get up at 7:00am to watch DOE administrators talk:
1. Controlling the laser in space and time was important for maintaining
symmetry. Timing precision of 25e-12 secs and laser spatial precision of 5e-12
meter were needed. This was thought to be the main explanation for the
achievement.
2. 8% more power on the laser this time
3. x-ray tomography is used to find flaws in the capsules. Developing software
to do the counting.
4. They have ongoing efforts to study the fabrication systems and their
components (done in Germany) to find idiosyncrasies of each.
5. Laser technology improvements since NIF was built which are 20% more
efficient.
6. Target cost is from labor, and it takes 7 months each
7. 4% of DT is burned in a shot
8. Machine learning ties together radiation hydrodynamics and experimental
data. (It sounded preliminary.)
9. The (successful) capsule had more defects than previous experiments.
However, previous experiments did show benefits from capsule quality.
10. 15% of experiments are indirect drive of this kind, 15% of experiments are
other approaches to ignition. The rest are weapons and materials
characterization.
11. Anomalous laser directional control were problems in the summer runs.
Fixed that.
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