Thanks for responding, brantc.
We seem to have a breakdown in communication ... to me, your "description" was not a "hypothesis".
Would you be so kind as to say a few words on what you think a hypothesis is, in physics? Perhaps you could illustrate your understanding by showing the correspondence between the key features of "hypothesis" and your description.
A hypotheses actually could be anything not testable in a terrestrial laboratory.
I could frame my idea as a testable hypotheses.
However I dont think I have introduced anything new.
OK, but how would you - assuming you had the power - decide to allocate resources across the many (dozen? hundred? thousand??) alternatives (plasma cosmology is certainly not the only alternative!)?
And if you feel the decision should not be in the hands of just one person, how should resource allocation decisions be made?
Make everyone sit in the same room and come up with an experiment that benefits everyone.
Stop spending money on war and more on science. I think 5 or 10 billion out of the 500 billion war budget would cover everyone and all their projects. Conserve resources a little better. There is enough money to cover everybody.
Fair enough ... but how should "their observations" be evaluated?
Specifically, how would you go about deciding which are scientific and which are not?
Evaluated implies that they need to fit with some paradigm. This is not so!!!!!
Pure science comes up with a result that may not fit because we are not privy to ultimate knowledge.
Fitting results into a model is not the realm of science IMO. That would be philosophy I believe, which I think is part of the problem with idea of a PHd being true science.
Everybody should have access to the same
RAW data. Not this massaged, been processed, our interpretation artist sketch.
With access to the raw data I think it will be apparent which way to go.
Everything is scientific as long as the method is followed. Right?
If 2 different teams have slightly different methodologies or algorithms then you will have different results. Publish both!!!!
Time will tell.......for sure!!!!
How do you tell which is right upfront? I dont know. I'm not privy to that information.
Imagine you are the editor of a journal which aims to publish just such papers ... how do you go about deciding whether a particular submission is "basically a good paper" (or not)?
The first thing is not journal but journal
s. Why is there only one Nature????
<conspiracy>How else do you control the flow of information.
The thing to notice is not whats there but what is missing. And how do you prove anything on whats missing? Look at media info carefully and you will see what I mean.
</conspiracy>
I would probably start with a wiki type arrangement where the papers are submitted to a real peer review, by Johnny and Sally America.
Once their paper has a passed a certain standard of corrections and form, then it makes it to the first publication. This is first come first serve.
With enough journals(3 tiers) there is a place for everyone.
As far as the top publications go, rigorous science is rigorous science even if your conclusions don't agree..
There definitely should be an allowance for a track record but that doesn't entitle you to do bad science..
There will be more experienced(experts in every field) people reviewing the more complex stuff. People can learn in the process and move up. This also allows checking for conflict of interest. If people could be civil I would allow direct access to the reviewer.
Along with that I think we should change the education system so that people can make better decisions.. But thats a different story.
In terms of cosmology - studying the universe on the grandest of scales - how do you go about determining whether what you see is a magnetic field or not? And, having decided it is, how to go about characterising it (strength, direction, etc)?
Once you've characterised a magnetic field that you see, how do you go about determining what the corresponding electric currents are?
From what you know, what are the most extensive magnetic fields which have been seen (by astronomers)?
With observational astronomy I think that you have 2 basic photon lab methods available. The Zeeman effect and the Faraday effect.
The third method is using the right hand rule and applying it to plasma, with the tubular instability being a current carrying structure surrounded by a magnetic field.
Once you know the magnetic field you can work back to the current flow in the plasma.
"Pervasive throughout the known universe" is the quote I like.
I imagine as long as there is a plasma around there is probably a magnetic field from the movement of the charged particles..
How should a serious scientist go about modifying (the effects of) gravity a little, in terms of doing cosmology?
That is a tough one. We have had discussions on gravity. We even came up with a test for push gravity. For right now I am using the "models" below.
This is the model of interest right now.
Aetherometry and Gravity: An Introduction
http://davidpratt.info/aethergrav.htm
Specifically.
http://davidpratt.info/aethergrav.htm#g3
I believe that this site shows the Aetherometry gravity model to be at least plausible.
TWO-STAGE MECHANICAL OSCILLATOR - PENDULUM-LEVER SYSTEM
- A Mechanical Amplifier of Clean Energy -
http://www.veljkomilkovic.com/
Do you have any idea when your own ideas might be ready to be shared (not necessarily published)?
Dont know. Maybe I will get brave someday soon.
Here is a little taster. See if you can figure out what I would use this for.
From a paper entitled
Mysteries of the Arc Cathode Spot: A Retrospective Glance
D. Plasma Expansion and Ion Acceleration
A further astonishing fact of arc spots is the high kinetic energy of ions leaving the cathodic plasma cloud toward the walls and the anode [21], [22] (i.e., in a direction seemingly opposite to the general electric field in gas discharges; the ion part of the arc current is negative).
A simple theory discloses an explanation [23], [24] that may be considered as sufficiently convincing: The ions are accelerated by three forces: 1) the pressure gradient within the cathodic plasma; 2) the electron-ion friction; and 3) the electric field, which has the opposite direction in the plasma expansion zone, forming a potential hump near the cathode spot.
Electrons are accelerated by the dominating pressure gradient also, but are slowed down by friction and the electric field. Thus, the electrical resistance of the expanding plasma is negative, doubtless a further strange property of arc spots. However, at high currents and in gas environments where a kind of constricted dense plasma column develops, this curiosity disappears, the field retains its normal direction. The generation of multiple charged ions in the dense cathodic plasma by thermal and pressure ionization (under nonideal conditions, e.g., in explosions) and freezing of this composition during plasma expansion was investigated, particularly by Brown, Anders, and others (for instance, [25]).
Stone Temple Pilots - Interstate Love Song. Great song.
