tide satellites gravitometry
wicking proppants pH adjust to move hydrocrabons ish
sticky tape on cores then tape cassetteified gives superreadable geology sample data to create better hydrocarbon prediction databases

Compare the metal detector type electrical log to the distance resonance tuned nducor like the janiceiwc MIT light up a bulb at 300 feet technology. That electrical form could measure deep capacitance as well as microstructure. Last I read it delivered
300 watts a large number of meters obvious yet a much much more detailed well electrical log
Oil retroreflected has obvious polarization nterfeometry colors, when compressed between polarizers that measures things

--- SoupGate-Win32 v1.05
* Origin: fsxNet Usenet Gateway (21:1/5)

electret frascing
puff fracing
horizontal -||||||-- with side areas produced at drill head
soliton geophysics
the month sized super tides tidal petrofluid describes reservoir size
bismuth well contrast enhancer
antinodal distance effect furthers sensing
element 16 volume changes with surroundings, also the element 16 travel effect describer. crystal liquid crystal crystal
tectonic equidistance from plate edge as a chronomapper of geologic era of hydrocarbon resource like
PA|North sea
TD |N
water well drilling could have atomatic sensing of mineral value to create larger databases
lengthways on well isotope labels show actual horizontal microarea of hydrocarbon resource motion, then database suggests modify
h3po4 dissolves rust, sedimentary things have "bands" thus po4 or electrolized ion water could create bands of hyperpermeability permitting more rapid hydrocarbon travel to well
drillhead adjusts angle to go with prefeerred orientation of sedimentary grain to make more permeable
actual fluid reservoirs even water or mineral fluids could have well robots visit the perimeter of the fluid areas then sample at the spherical perimeter to characterize resource
algal goop freshwater delta streambed size blobs as a suggestor of geophysical resource at certain distance like KM
oil seep locating bacteria make gfp when they meet hydrocarbons thus characterize large surface seas or possibly fluid reservoirs


(nifty) removing histones from oilseeds makes them grow 3 or 4 times more rapidly some halophile seed oil species may compete with mineral oil if grown more rapidly


drillheads
narrow then elevator like side cleaving, a little like underbalance avoids gooping up microstrcuture
contests,
gradual 24 hour chirp provides crisper data


Notepad notes, the previous material was notes taken at yahoo correspondence

Russian oil appears to freshwatergenic as with plate tectonics the russian landmass reshapes yet is always nonmarine
I keep trhinking about a way to cheaply dissolve quartz because then porosity goes way up also I wonder if ther are hydraulocatalytic chemical processes where fluid pressure actually rises as a result of decomposition of minerals as that would create
greater fluid motion pathways along with hydraulic pressure. some very coomon weird things like the lessening of the hydration of iron oxides could produce a volume effect
of
im getting the clue here about source beds n gravitometers where tracing paleozoic gravity variations (fancy way to say mineral densities) would likely map which general direction petroleum migrated during the paleozoic

(nifty) people feel as if they know all the ways to crumple a plane yet from reading geometry sometimes there are new approaches a computer math thing that came up with more ways to crumplea plane than people now know about then searches something like a
google earth stratigraphy database to find near similars could find unthought of ^ that have sequestered petroleum
noting that reservoir is described as 5 billion $ of oil, finding new geometries of plane crumpling that suggested previously hidden ^ near shale is of value Like what if a nonpermeable mineral layer is somehow 5 pct more elastic along one cartesian
direction than another, then theres a temporycrumple event, then a relaxation, (another way to say that is, what is the go back to source shape tendency of different nonpermeable mineral layers, if is even .o1 pct, that might accumulate anisotropically
creating ^ from a new process not previouslydescribed . does that create sideways striation of ^

well, wheni was doing form programming I noticed that html textfields actually supports 32k of characters so ill just make my suggestion here I think mit complimentary courseware could be modifiedslightly to be even more effective there is a simple way
to record how often a person uses a scroll bar with html, when you measure scollbar use you can tell if they are reading the text pages as they will ncrement ahead every few seconds Heres how to do this, just place an array of transparent gifs next to
the right side of the page every time there isa mouseover event the javascript program noticesthat then fills a clientside database with the users mouse motion activity, then ocassionally send this back to server to nvisibly trace actual page ntentional
scrolling, which suggests active human learning, then to improve the actual course comprehension put up two or three versions of each course notes then see which students get the farthest nto the reading suddenly you are reaching people with more
information Yay MIT

so apparently making cheap natural gas liquefaction technology would make LNG vastly cheaper. ive wondered why they do not pipe it to sealevel far offshore could go _____________| seabed then up rather than surface then put it at weird polymer flexi
containers, then let gravity compress it to liquid as it drops to ocean floor, then flexy container has a different float up mechanism. It liquefies natural gas, has very few parts is also kind of amusing

(nift)when I think of LNG transport or any cryogenic transport I think of how any physical link causes warmth movement I think it is possible electroosmosis could be used at the surface of a fluid to reduce evaporation, redirecting surface molecules to
the bulk of the fluid where the coolness would rapidly develocitize them thus electrosmosis could be a way to reduce evaporation as well as the possibility of spreading area evapofountain spouts (fizzy areas) as a result of a hyperegularized surface
Thinking of keeping things cool at a dewar its possible electrosmotic motion, or motion reduction could effect more efficient cryostorage of LNG
also think of the nsulator around the dewar, like the styrocrate, the outer surface of the styrocrate could use electrosmosis of a layer of something like vacuum oil to always minimize surface thermal outward flows (perpendicular to surfaceish, even
though of course many atom movements would be tangential to surface) to create surface stillwind creating greater nsulating ability



so is there a geometrical or other formulaic ncrease n the number of kinds of time with higher dimensionality 3d1t has linear chrono 4d2t 5d3t string theory numberD number-2T at systems with >1 T does T have interactive forms I think I read that the
strong or weak nuclear force gets asymptotically tinier the neaer you get, wheas oth fields get larger, at numberD t>=2 does time nearness form what kind of shape


One problem with the mean is that the tails of the size distribution, which are hard to measure accurately (fine stuff gets lost; big stuff is too “lumpy” statistically) have a strong effect on the computation.
notably the fine stuff affects percolation while the big blobby stuff permits rapid fluid flow, thus the usenet oracle distribution notation 7bgr3 describes a normalish distribution along (0 to z) quintiles petroleum geology softaware might be rather
thrilled to compare quintiles (0-10) (n)(n)(n) (r to z) being an identifier that says minimal occlusive silt, lots of huge blobs its kind of like digital kurtoses

rather than looking at the size of the distribution of the mineral microchunks one could look at the size of the noncontinuous oil blobs, spread out per area unit of space, possibly divided with the porosity of the umm general mineral formation, to give
an amount/mobility number where explosions could change either mobility, or create geometrically predictable bands of clumped newly linked oil blobs. so a petroleum geologist is then directing a "unite the blobs" or "porositize the substrate" frac or
explosion effect to create a higher pertroleum flow rate

sediment size decreases progressively downstream. (This is called downstream fining.) If this obviously detectable at sedimentary minerals then petroleum geologists could possibly find upstream of a particular sediment to finder larger grained petroleum
deposits where (larger grains would be likely to have larger gaps) (online says finer sediment is more porous, wow) permitting different petroleum flow rates, this would be true even at currents at open seas, so a directionality of previous fluid flow
likely already informs petroleum geologists

to my amazement reelasticity may be part of crumple hydrocarbon resources, sort of comically, the meteor crater oil may have had a big migration effect from simply doubling the porosity as a result or shifting overminerals, thus permitting particular
direction flow. I do not knoqw of other geologic effects where lots of mass was lifted off a petroleum area, suddenly doubling porosity, from re elasticity, permitting new flows to concentrate

iffy yet fun wow mica flaces create pseudomatrix, yet mica flakes are suberply frequency responsive, if you ultrasonicate mica at the right frequency it is likely to cleave rapidly as a result of the very uniform laminar spacing, so ultrasonics aimed at
mica minerals could actually affect porosity

goofy sonic scanning explosive geotextile geotextiles are large area fabrics that frequently lay on the ground. giant fabrics that stabilize hillsides so an acoustic imaging seismologist just specifies, lay that large area geotextile along the ground,
then the software uses the large area grid to create small acoustic microsiesmic sounds with explosives that are part of the geotextile, that permits an imaging scientist to coincide 2, 3 ,4 or a huge plurality of wave sources at a preferred time
interval to do acoustic imaging, creating fabulous nodal energy effects at depth which the software then figures out, the purpose is also to create a micromapped area at depth to create much higher resoltion drilling, having noted that a few meters
difference affects actoil oil production a lot. so at an oil well location acre, you would use an acoustically emitting geotextile to superoptimeze where on that acre to drill to find hydrocarbons, also the geotextile could be reusable, its kind of
amusing to think of the distributed explosives or sonicators being activated from a laser at a distance rather than being wired or CPU wifi communicated people at MIT geosciences are doing awesome things with data this gives them more data from a
controllable simultaneous dimensional transducer

not petroleum geology yet it is possible the electro osmotic effect where the actual size of the electro osmotic area near a surface is kinda little 3 dby lengths, could be gotten around with a focal electron source like a rod moving near the surface of
a liquid, to produce an electro osmotic motion, far from a side area, a plurality of these could create a larger fluid motion. like if you toss glitter onto liquid then electrify the glitter, the fluid moves, if you electrify the floating glitter
patternistically you get patterned fluid motion, ncluding macromotion from multicombined tiny motions so this is kind of a way of moving fluid with moving the fluid near the microconductors floating at the surface, yet a colloid would have possible
conductors disperesed throughout the goop, so a planar em wave might be patternable to move the goop at the middle of the amount. a nifty calculation would be, if you do electrophesis like thing on a bunch of differently nanosized conductors, then do
electrosmosis on them at their particular em antenna frequency could you get them all to move at the same time, that would be like robot motion impelling goop

so as kind of pointless application if you paint a chunk of mineral like an oilshale with photovoltaic paint, on a layer of microsized metal antenna chunks that could absorm em energy then are rather calm that would very gradually pull ooze out of the
chunk from sunlights energy. this could make a fun approach to art restoration, electrosmosis of oil stains out of famous old paintings at about 10,000 seconds per linear meter of moving oil, or 10 to 100 seconds per mm of goop motion or as the mit
paper says 30 micrometers per second

what would look kind of like magic, yet would be science, is to use the way a wire about 10 to 40 feet above the ground has a potential difference with the ground, then use that very gradual electrical motion to make electroosmosis at the top of a
container full of fluid which em frequency sorted to electrosmosis pull certain ions up then to a channel, gradually a concentration of that ion would occur at whatever the channel led to, possibly giving a elfish no moving parts way to separate sea
water to metals it would process 1 meter of fluid every 10,000 seconds, which as a kind of multiyear honored sculpture would create big accretions of metal


One problem with the mean is that the tails of the size distribution, which are hard to measure accurately (fine stuff gets lost; big stuff is too “lumpy” statistically) have a strong effect on the computation.
notably the fine stuff affects percolation while the big blobby stuff permits rapid fluid flow, thus the usenet oracle distribution notation 7bgr3 describes a normalish distribution along (0 to z) quintiles petroleum geology softaware might be rather
thrilled to compare quintiles (0-10) (n)(n)(n) (r to z) being an identifier that says minimal occlusive silt, lots of huge blobs its kind of like digital kurtoses

rather than looking at the size of the distribution of the mineral microchunks one could look at the size of the noncontinuous oil blobs, spread out per area unit of space, possibly divided with the porosity of the umm general mineral formation, to give
an amount/mobility number where explosions could change either mobility, or create geometrically predictable bands of clumped newly linked oil blobs. so a petroleum geologist is then directing a "unite the blobs" or "porositize the substrate" frac or
explosion effect to create a higher pertroleum flow rate

sediment size decreases progressively downstream. (This is called downstream fining.) If this obviously detectable at sedimentary minerals then petroleum geologists could possibly find upstream of a particular sediment to finder larger grained petroleum
deposits where (larger grains would be likely to have larger gaps) (online says finer sediment is more porous, wow) permitting different petroleum flow rates, this would be true even at currents at open seas, so a directionality of previous fluid flow
likely already informs petroleum geologists

to my amazement reelasticity may be part of crumple hydrocarbon resources, sort of comically, the meteor crater oil may have had a big migration effect from simply doubling the porosity as a result or shifting overminerals, thus permitting particular
direction flow. I do not knoqw of other geologic effects where lots of mass was lifted off a petroleum area, suddenly doubling porosity, from re elasticity, permitting new flows to concentrate

iffy yet fun wow mica flaces create pseudomatrix, yet mica flakes are suberply frequency responsive, if you ultrasonicate mica at the right frequency it is likely to cleave rapidly as a result of the very uniform laminar spacing, so ultrasonics aimed at
mica minerals could actually affect porosity

goofy sonic scanning explosive geotextile geotextiles are large area fabrics that frequently lay on the ground. giant fabrics that stabilize hillsides so an acoustic imaging seismologist just specifies, lay that large area geotextile along the ground,
then the software uses the large area grid to create small acoustic microsiesmic sounds with explosives that are part of the geotextile, that permits an imaging scientist to coincide 2, 3 ,4 or a huge plurality of wave sources at a preferred time
interval to do acoustic imaging, creating fabulous nodal energy effects at depth which the software then figures out, the purpose is also to create a micromapped area at depth to create much higher resoltion drilling, having noted that a few meters
difference affects actoil oil production a lot. so at an oil well location acre, you would use an acoustically emitting geotextile to superoptimeze where on that acre to drill to find hydrocarbons, also the geotextile could be reusable, its kind of
amusing to think of the distributed explosives or sonicators being activated from a laser at a distance rather than being wired or CPU wifi communicated people at MIT geosciences are doing awesome things with data this gives them more data from a
controllable simultaneous dimensional transducer

not petroleum geology yet it is possible the electro osmotic effect where the actual size of the electro osmotic area near a surface is kinda little 3 dby lengths, could be gotten around with a focal electron source like a rod moving near the surface of
a liquid, to produce an electro osmotic motion, far from a side area, a plurality of these could create a larger fluid motion. like if you toss glitter onto liquid then electrify the glitter, the fluid moves, if you electrify the floating glitter
patternistically you get patterned fluid motion, ncluding macromotion from multicombined tiny motions so this is kind of a way of moving fluid with moving the fluid near the microconductors floating at the surface, yet a colloid would have possible
conductors disperesed throughout the goop, so a planar em wave might be patternable to move the goop at the middle of the amount. a nifty calculation would be, if you do electrophesis like thing on a bunch of differently nanosized conductors, then do
electrosmosis on them at their particular em antenna frequency could you get them all to move at the same time, that would be like robot motion impelling goop

so as kind of pointless application if you paint a chunk of mineral like an oilshale with photovoltaic paint, on a layer of microsized metal antenna chunks that could absorm em energy then are rather calm that would very gradually pull ooze out of the
chunk from sunlights energy. this could make a fun approach to art restoration, electrosmosis of oil stains out of famous old paintings at about 10,000 seconds per linear meter of moving oil, or 10 to 100 seconds per mm of goop motion or as the mit
paper says 30 micrometers per second

what would look kind of like magic, yet would be science, is to use the way a wire about 10 to 40 feet above the ground has a potential difference with the ground, then use that very gradual electrical motion to make electroosmosis at the top of a
container full of fluid which em frequency sorted to electrosmosis pull certain ions up then to a channel, gradually a concentration of that ion would occur at whatever the channel led to, possibly giving a elfish no moving parts way to separate sea
water to metals it would process 1 meter of fluid every 10,000 seconds, which as a kind of multiyear honored sculpture would create big accretions of metal

Compare the metal detector type electrical log to the distance resonance tuned nducor like the janiceiwc MIT light up a bulb at 300 feet technology. That electrical form could measure deep capacitance as well as microstructure. Last I read it delivered
300 watts a large number of meters obvious yet a much much more detailed well electrical log

Oil retroreflected has obvious polarization nterfeometry colors, when compressed between polarizers that measures things

--- SoupGate-Win32 v1.05
* Origin: fsxNet Usenet Gateway (21:1/5)