Conference 7.286::space

    re .0
    
    also posted in PHYSICS

    	I agree with you.
    	Having studied chemistry (only to A'level admittedly) I find
     this concept hard to swallow. `Plastics', by the common definition,
     just don't do that ! When subjected to such intense heat, they will
    degrade.
    	A friend of mine is studying Materials Science, at Manchester
    University, and after reading this, I immediately got on the phone to
    him for his opinion. 
    	What he said, isn't really suitable for the notesfile, but to give
    you a clue, they're possesed by men and not women !!!
    	He told me that in normal plastics (carbon chains... polymers) the
    carbon-carbon bond cannot take such an influx of energy. The bond will
    break and the plastic will revert to its consituent parts, mainly
    carbon. From my experience (please correct me if I'm wrong), the
    carbon-carbon bond is one of the strongest there is. For example, diamond,
    the hardest substance known to man, is constructed of pure carbon, in a
    tetrahedral arrangement. Does anyone know what temperature diamond goes
    `poof' at ? Is this the measurement that they refer to in the article ?
    	So, if this type of bond can't take such a heat increase, then I'd
    like to know how he constructed his polymers without using some
    carbon-carbon bonds !!!    
    	If, and in my opion it is a BIG if, this is real, then it truely
    does redefine the laws of physics (well at least for plastics anyway).
    	With such potential importance, ranging, as you say, from household
    matters to space exploration (staying with the conference title !) then
    regardless of the cost, the government would surely go to great lengths
    to get there hands on it. I mean, how much did they spend on Stealth
    technology alone ???
    	Faced with all these `facts' I believe it is a hoax, but I will be
    interested to hear more about it, as will my Materials Science friend !
    
    Best Regards,
    
    
    Dan.
    

This does not directly answer the question in .2, but they used a diamond
windows in one of Pioneer Venus's surface landers to allow the instruments to
peer out even in the intense heat.

Burns

re .2
    
>From my experience (please correct me if I'm wrong), the carbon-carbon bond is
>one of the strongest there is.
    
    I don't think that is correct. I will try and remember to look up an
    old chemistry book for a table of bond strengths.
    
    I believe that the presence of other atoms can make quite a difference
    to the strength of a bond or at least to the properties of the material
    e.g. alloys.

    I wonder whether the shuttle's tiles could be replaced by a coating of this
    stuff.

    	The temperature at which carbon melts (its melting point) is
    actually 3,800 C and its boiling point is 5,100 C. I couldn't find
    anything which can remain either solid or liquid above those two
    temperatures respectively.
    	As such, this leads me to believe that the carbon-carbon bond is
    one of the strongest. However, I haven't found a table of actual bond
    strengths as such yet. But, as it is temperature tolerence that is the
    question here, I think this confirms my suspicions.
    	A polymer (which is what a plastic is) is only as strong as its
    weakest bond. So lets say, just for argument's sake that the
    carbon-carbon bond isn't the strongest, or indeed anywhere near to it.
    This still means that if this `plastic' does posses any carbon-carbon
    bonds at all, then it will begin to melt (and so degrade) at, or around
    3,800 C. Further, it will begin to boil, so becoming gaseous, at, or
    around 5,100 C. This is only half the temperature it is claimed it can
    withstand !
    	Re. 1 
    	I'm interested about one of the qualities the author of the article
    mentioned. The article states that the Starlite is "waxy to the touch".
    	To me, if something is "waxy to the touch" it means that molecules
    are being removed from the surface of the material, and deposited on
    your fingers. It is these molecules on your fingers that give the
    felling of being "waxy".
    	For molecules to be removed from the surface of a material just by
    touch indicates that there are some very easily broken bonds at molecular
    level here. This is assuming, of course, that this is the material
    itself that has this property, and it is not simply a coating of some
    other substance on it.
    
    	Returning to the topic of this conference though, if this `plastic'
    is real, and does posses these heat resistant qualities, it would
    indeed be very useful for insulation against the heat experienced by
    vehicles upon re-entry. 
    
    Dan.	

I think the other part that you're not calculating in is the 
statement from the original posting:

	A Foulness
    scientist says he is stumped for why, despite photos showing that a thin
    layer of ionized gas formed on the surface and seemed to insulate the
    plastic. 

When a material sloughs off layers, heat is carried away with it as 
well. Is it possible that this ionized layer becomes a dense enough 
stable plasma that it collects the heat and brings it away from the 
surface? You can put an awful lot of energy (read heat) into a plasma
state. If this is true then this might be a candidate for fusion 
containment chamber linings as well as heat sheilds/tiles

    It sounds kind of funny that this guy says he started this project
    and worked on it for several years because he was concerned about
    the lives/safety of people,  then he sits on the formula.  Makes
    you think that there is a catch somewhere.  Like maybe this is the
    only piece he has been able to produce or you can't shape the stuff.

    I'd think that he government should go make this guy an offer of
    something like "if it works we'll pay you a $1B cash".  If the
    stuff works, it would be well worth it for the space program alone.

    fred();

    This is really hard to buy.  The concept challenges several existing
    paradigms; about plastics, physics, reality.  That is not to say 
    someone could stumble across something new.  In fact, establish a brand
    new paradigm(s).  Mathmatically, I suppose it's in the odds, but they
    must be awfully high.
    
    Frankly, I have a serious credibility gap with the story.  After all,
    it's not like it was in the Inquirier; only Business Week.  I would
    think if there was some validity to it, there would have been something
    in the Inquirier...   8-)  8-)
    
    -Bill
    

re the "waxy" business, the the apparent plasma formed on its surface:

I wonder if it might be ablative?  Another possibility is that the top layer of
the material forms a highly conductive layer of some sort at the first touch of
the laser.  This layer procedes to conduct the heat away very quickly across a
large enough area to radiate away before the surface reaches its bond-breaking
point.

If either of these theories is correct, the material would not work well in
applications like shuttle tiles.  If it is truly ablative, it would have to be
replaced frequently.  If it forms a thin conductive layer, then we have two
problems: 1) the layer gets blown away by a hypersonic air stream making it
effectively ablative, and (2) there is no place to radiate the heat if there is
a large area of heated Starlite, as opposed to just a point heat source.

Burns

    re .5

    You need to distinguish between inter-molecular bonds and intra-molecular
    (i.e. inter-atomic) bonds (although there are substances where the
    distinction is blurry).

    When a molecular solid (such as ice) melts, it is inter-molecular bonds that
    are being broken. When a substance like salt melts, there being no molecules
    anyway, it is inter-atomic bonds that are broken. When a compound (of
    either nature) undergoes chemical change, it is inter-atomic bonds being
    broken.

    In any case, as promised, a table of (intra-molecular) bond strengths.

    Single Bonds	    Double Bonds	    Triple Bonds

    H-F		135	    C=O		177	    N#N		225
    O-H		111	    C=C		146	    C#C		200
    H-H		104	    O=O		119
    H-Cl	103
    C-H		99
    N-H		93
    H-Br	87
    C-O		86
    C-C		83
    H-I		71
    Cl-Cl	58
    Br-Br	46
    N-N		39
    O-O		35
    I-I		35

    (Units: kcal/mole. I apologise for the obsolete units.)

    e.&o.e.

    In diamond, being a non-molecular solid, there would be four single (C-C)
    bonds to break. I have no idea of the "form" of liquid diamond so can't
    comment on what you might "get back" by reforming bonds if the liquid is
    molecular.

    re .?

    I wondered when I read the original report whether enough of the substance
    ionises/vaporises (whatever) to get a sample for mass spectroscopy i.e.
    obviously the inventor takes away the test sample but maybe some material
    "splattered" around or condensed on the test apparatus, not to mention
    samples from the "waxed fingers". Of course, knowing the composition might
    not be enough if the manufacturing process is tricky, and not that I would
    condone dishonesty. (-:
 

    Ok, so the carbon-carbon bond isn't the strongest !                 
    
    	However, do you agree that a polymer is only as strong as its
    weakest link or bond ? Do you agree that to create a plastic, by the
    common definition, you have to generate some sort of carbon chain ? If
    you answer yes, then you must agree that this concept of such a
    heat/energy resistant plastic seems hard to swallow. If more than
    the said amount of energy required to break that bond is supplied, then
    I'm afraid you can kiss goodbye to your polymer and plastic !
    	Yet, if this thin layer of ionised gas is the secret to the
    plastic's heat resistant properties, then I'd like to know how and
    where it is generated. Does it come from the plastic's surface. Is this
    the product of the "waxy coat" ? Is this the "waxy coat's" response to
    huge heat influx ? If it is, then hasn't he found a new protective
    coating, rather than a heat resistant plastic ?
    
    Regards,
    
    Dan.

Strength of the bond may not be the issue if there is some abalation

    But what controls abalation ?

What controls abalation?

Could be many things.  Including nearby airflow.

I seem to remember someone stating that the starlite appeared to create a
boundary layer that acted as a reflector.

Tony

    If starlite works as described then, it would also make good rocket
    engine lining. Reducing or eliminating the the need for dynamic cooling.
    
    I go more with the theory that it is reflecting the heat, rather
    then being ablated. Is a heat mirror possible ... 
    
    Gil

    Right, I understand ablation to be the removal of the surface layer(s)
    of this material. Correct ? Now why/how this occurs, I'm a little fuzzy
    on. But, if this plastic's heat resistant/reflective properties are a
    result of this ablation, then I can't see that much use for it.
    	In any dynamic situation, this plastic's special property would
    prove to be useless, unless this insulating/reflective layer can adhire
    to the surface in some way.
    	If this material is applied in any environment where this layer
    will be removed by external forces (shuttle tiles,rocket engine
    lining, etc.) then your plastic will disentigrate before your very
    eyes.
    	Ablation would account for the surface marks seen on the original
    sample (re. 0). These marks could be the areas where material was
    removed by this process.
    	Overall though, this concept still seems hard to swallow.
    
    Dan.

      One of the demonstrations listed was pointing a blowtorch at it for
    five minutes, after which the rear side of the 'tile' remained cool
    enough to touch. If true, this surely scotches both ablation and very
    good heat conductivity (one guy quoted in .0 suggested SiC might be an
    ingredient) as means of explaining its properties. The flame from a
    blowtorch would surely carry ablated material away rapidly, preventing
    any protective layer from forming. If heat were being conducted
    rapidly away through the material, the other side of it would get hot.
    
      The same thought occurred to me as to the author of an earlier reply,
    that if Ward developed the stuff to help improve aircraft safety,
    then keeping it out of commercial production is not serving his stated
    original aim any.
      Has anyone heard of the named professors and others mentioned in the
    basenote? Are they genuine, respectable scientists?
    
    Ken
           

    Can't say that I've heard of any of the scientists !
    
    	Anyway, this is goodbye, as I'm going back to university at the end
    of the week, and this is probably the last time I'm going to get chance
    to write.
    	I've had a great time with Digital over the summer, but I'm afriad
    I've got to return to the parties and the night life and the...**sigh** !
    	It has been really good participating in the notesfile discussions.
    I hope you lot didn't mind a part timer sticking his nose in !!
    	I'll keep my eye out for this starlite stuff, huh, maybe it is
    true!
    	Well, I'm outa here, I'm gone, I'm history...
    
    	Good luck to you all,
    	Best Wishes,
    
    	Dan.
                                                                   

Reproduced without permission from AvLeak/Feb 1, 1988 (p. 75)

MATERIALS TECHNOLOGY

Laboratories Test Material That Blocks Laser Energy

LANCASTER, CALIF.

Several Air Force, Army, university, and aerospace industry laboratories are
evaluating a new man-made material that effectively blocks a wide range of
laser wavelengths and energies up to a certain level, then exhibits "black
body" absorbent characteristics.

Trademarked under the name Laser Shield, the opaque material is an "isotropic
engineered polymer matrix" that up to some undetermined level neither transmits
nor reacts to laser energy, according to its developer, Slava W. Harlamor,
president of Harlamor-Schadeck (AW&ST Jan. 11, p. 11). The small California
research firm has been pursuing aerospace propulsion concepts for several
years, and the company-proprietary Laser Shield material evolved from these
studies.

A sample of the material visually resembles a high-density urethane foam, but
is harder and slightly heavier than an equivalent-sized piece of foam. By
changing the Laser Shield's molecular properties, physical characteristics such
as density can be tailored during the production process. One model of the
engineered polymeric material - named "AELITA" - was designed to emulate the
density of hardwood. It has a density of 40 lb./cu. ft. and can be cut or
machined with standard woodworking tools.

Precision cuts in the homogeneous sample are well-defined, and thin sections
resist bending much better than hardwood does. Numerically controlled machining
equipment can handle the material at "good speeds," Harlamor said, and produces
smooth shavings with very little dust. However, a water jet cutter used for
shaping composite materials produces a rough edge on the AELITA.

The U.S. Army Materials Technology Laboratory began conducting tests on Laser
Shield samples last year, and confirmed that the material acts as a "diffuse
reflector" - incident coherent laser light is reflected from the material's
surface in a diffuse pattern. This diffusing phenomenon appears to occur at the
material's outer surface, but why the laser energy is diffused instead of
absorbed (at the energy levels tested) is not understood yet. Several different
sections of the Army laboratory - including the Laser Hardening unit - are
conducting additional tests.
Recent tests by a major aerospace company indicate that, at some as-yet-
undefined energy level, the materials properties shift and the Laser Shield
begins to act like a "black body," absorbing all incident radiation instead of
breaking down. This observed characteristic, though, is based on very
preliminary test results.

The Air Force Strategic Air Command is sponsoring a series of tests on the
material at Wright-Patterson AFB and at the Kirtland AFB weapons laboratories.
SAC is interested in several possible applications for the material, including
the protection of aircraft fuel tanks, Harlamor said.

The USAF Space Command will monitor the tests, as well. "We are interested
in the material for several [long-lead time] reasons - as protection from
lasers on orbital payloads and for a number of SDI-related applications,"
an officer at the command's Colorado headquarters said. "There are a lot of
questions, though, that we hope [the Wright-Patterson] tests will answer: How
thick does it have to be to protect? Can it withstand the temperature
variations of space? Can it be made to spray on and coat something? How will
it react to radio, radar and microwaves?"

At the moment, the material can only be formed in blocks under a high-pressure
process, then machined to a desired shape, Harlamor said.

Princeton University's Plasma Physics Laboratory is planning to run a variety
of high-power tests with a one gigawatt carbon dioxide laser and, possibly,
a 20 gigawatt X-ray laser.

In an early, very preliminary test conducted by A-B Lasers, Inc., with its
Model LBU laser marking system, the AELITA material was only slightly
discoloured by the beam's 10 successive passes over the same area, according to
Gerhard Marcinkowski, sales manager for the Acton, Mass., company. The 60 W
continuous wave Nd:YAG (neodymium-doped yttrium aluminium garnet) laser marking
system was programmed to write 25 characters over the same location at a speed
of 5 mm/second for 1 min. Operating at a wavelength of 1.06 microns, this system
is routinely used for high-volume marking of metals and plastics such as drill
bits, precision tools and computer keyboard keys.