use liquid hydrogen or carbon electrode at LNG to do something like electrolysis to ch4, this would actually be dialectric disintegration as ch4 is nonpolar, yet with a hydrogen or hydrogen carbon electrode recombination products would be longer more
valuable alkanes

noting the effect where some materials have narrow angle pressure fracture, like autosharpening depleted uranium It seems possible to create a drillhead that autosharpens petroleum drillheads ive viewed online have multiple synthetic bits

One approach to creating this effect with carbon nitride bits or similar is to hypercool drillhead nserts with lasers shining on them or possibly overlapping microwave warming during mnufcture to create artificial cleavage planes that autosharpen as
compared with dulling. basically 3d variable annealing, possibly responsive to some very specific occurence to cleave

autoswelling proppants could actually be string shaped to create a longer area of uplift so as to sufficientize the length of porosity path at a percolation theory model of what an optimally porous material should be

another methane clathrate gathering technology is just to apply the cassion technology to a clathrate bed, however rather than an actual cassion that reaches the surface a few hundred meters up, is to create a water filled cassion or tubular structure
full of methane converting microorganisms as well as growth nutrients like Fe that are rarer at the less biotic areas of the ocean, then the clathrates are bulk food to a mechanically gatherable autofloating when full of liquid lipid microorganism. the
amount of released clathrates is linked to the presence of the size of the nutrient cassion or tube which is much more ecologically conservative than "surface mining"



(nifty) at some situ process like oil shale the hydrocarbons are warmed awhile I think a chemical tracer that visualizes the actual warmth at a variety of places as well as fluid motion as well as actual possible hydrocarbon modifications could be
accomplished with a hydrocarbon that had a number of thermosesnitive groups on it. amazingly dextrose which is basically hydroxylated 11acane might be a model of compounds that could change color or isotopic ratio with gradual thermal activity.
creating these tracer chemicals permits the gathering of lots of data on which part of a situ well, at what temperature, at what duration, produces the highest yield. noting that even with combusting gas at a car cylinder micromapping the activity
profile causes large efficiency from engineering modifications accurately describing the situ process with a chemical tracer is likely to be beneficial

(nift) Noting that the US can have as much 40 to $70 USD per bbl Canadian Tar sand or possibly shale oil if a pipeline is built, the creation of better cheaper pipelines as well as cheaper oil transport containers creates cheaper petroleum at the actual
user. a simple pipeline modification which may reduce environmental risk is simply a \-O-/ pipe with a tray around tube shape, where the tray would typically direct possible spillage to a lined micro reservoir. This system absent moving parts could
create greater pipeline permissability, 40 to $70 oil from canada competes with 100$ valuations, pipeline technology thus reduces oil costs 20 to 30 pct. (note the multiyear average however determines the actual applicability of pipeline technology
) a sensor variation of greater pipeline functionality uses a flow sensor with a tiny storage loop, if the presure fluctuates the storage loop fills, which gives sufficient pressure variation reduction as well as timing cushion to keep the rest of the
pipeline from reacting to an under or overpressure event.
(better with image)

(nifty) surface oilshale or tar sand could have the hydrocarbons concentrated with rapidly flinging the oilshale or tar sand at either snow or warm salt, which may be available at the immediate area. basically grinding the oil shale or tar sand with
salt of some temperature transfers the material from the mineral chunks to the salt chunks, then dissolve the salt with water, the hydrocarbons then float or otherwise accumulate, then the salt can be recrystallized. Noting that Canada has a vast snow
resource, it could actually be that flinging tar sand at crystallized water then then grinding may actually concentrate hydrocarbons as well much more cheaply. depending on the chemical engineering warmable salt or plentiful water crystals should adsorb
much hydrocarbon from the mineral surface

(nifty) I think they noticed already yet it was fresh to me, a blob of hydrocarbons frequently floats on a pool of melted hydrocarbons (butter on melted butter oil) thus there may be zones of hydrocarbon concentration at a situ oil process from oil
shale or tar sand where higher concentrations of particularly valuable hydrocarbons occur, that gives the possibility of "slurping" just that part of the resource that is more highly valued at a particular time. If oil is cheap then slurping lighter
hydrocarbons from heptane to 11ane might be economically functional to maintain economic competence then when the price fluctuates the larger mass of heavier hydrocarbons is of sufficient value to area slurp basically if you structure a situ process
right the "soup" generates areas of sustained "cherry picking" while the oil company waits a few months such that the main resource is valued at at a sufficient margin

I already partially described this an opportunity to create carbon neutral hydrocarbons from methane hydrates would be to use Fe enrichment at a cassion over an area

compressing a slightly spreadable chunk of oil shale or tar sand causes it to have crenellated edges, (cookie squish then rotate away the edges) then placing a force tangent to the compression causes the microedges to come apart this could be a cheaper
approach to getting smaller chunks or particles to make fluidized bed applications

modifying the specific warmth of water vapor when they do situ hydrocarbon gathering they frequently use warm water vapor "steam" is there a way to get water vapor to carry greater specific warmth


describing sedimentary minerals
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 of petromodels.
(at the time I wrote this I was thinking) notably the fine stuff affects percolation while the big blobby stuff permits rapid fluid flow, thus the usenet oracle (“orrie”) 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

(nift) viewing the oil then grouping the oil or making oil movement channels 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

porosity changes with depth, suddenly changing depth with a geoevent could reelasticize porosity permitting hydrocarbon travel as well as accumulation
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 from reelasticity. 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

zapping highly laminar minerals at their laminer spacing frequency em resonce or acoustics might do things to porosity

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

(nifty) 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

this is some old idea from the 90s when I was figuring ways to make mineral products cheaper. some previous methods of grinding rocks caused similar sized clumps I think that remixing different sizes of rock clumps causes a different microarea pressure distribution resulting as a highe proportion of littler blobs produced with
less energy further theres the asymettric impinging press surface approach [][] [] would always tend to produce varied chunk sizes, if these are remix preferred sizes that is a benefit any petroleum geology style we apply these to oil shale to
make nuggests the right size to do fluidized bed processing which is more efficient

crinkle at ancient biomass approach with petroresource at nonhydrated paleozone when water meets hydrocarbond it washes them away, so to find hydrocarbons its beneficial to find the dryer side of a after paleozoic crinkle. water causes the biomass at
the first place, yet then if there is a dry side to the surface geofeature after then thats the area with the less rinsed away hydrocarbons further those hydrocarbons have had the opportunity to migrate further, ncreasing the number of ^ where it may be
found from /5\ on the moist side of the crinkle to /3\ /5\ /3\ on the dry side where there was hydrocarbon migration without washing (higher numbers suggest more oil)

I think they could put gravitometers the size of ICs on combines to map large areas of land to find possible hydrocarbon as well as mineral resource areas

some amazing oceanic hydrocarbon areas have chewels gum like blobs of pure oil, I think those oil filled blobs haqve resonance frequencies, so to characterize a resource area they could use a component frequency acoustic pulse tuned to the oil blobs,
while thats obvious the benefit comes from more carefully mapping the path of a horizontal well to optimize resource finding path

wicking petroleum at the well foot I think some hydrocarbons wick better than they pump as 14psi it all a a vacuum can produce, thus its possible that putting fluffy fibers on the nterior of certain oil wells could pull hydrocarbons to the pump area,
which then brings the oil up to the surface. thats better than one cycle pumping because one cycle pumping has a nonvacuum nterval

visualize a horizontal oil well where the horizontal is actually the radius of a deep area planar circle. each area that is at an angle from the preferred horizontal wellpath has a likelihood of producing oil so if the oil is at 3:00 there mmight be
30 pt chance of oil at 12 or 6, with 10 pt chance of oil at 9:00 To make oil cheaper to get, there with all the drilling equipment, staff, paperwork, a software model can decide if another horizontal well at 1:00 (with 40 pct likelihood of oil) is
economically valued as cheaper than the first well. if it is then the average expense per well goes down while producing more oil. The thing that makes this a little different is that the software evaluates the economics at drill time rather than
iteravely with days or weeks between opportunity realization, thus it makes an advantages of having all the drilling equipment, people, permits there to reduce costs.

I think that petroleum geologist know that some hydrocarbon formations as a result of their vastness yet mild concentrations of hydrocarbons regenerate rather gradually, that gives a shares opportunity where a petroleum geologist legitimately predicts a
gatherable resource half a century away, then the petroleum company makes a public offering of that petroresource to fund current projects

fiscal reward on publishing full data on well logs. scientists also value negative findings, what didnt work. with the creation of software models the geology of the wells that dont work has value to build more effective oil location prediction
software thus they could give a few hundred thousand $ on the well records of nonproducing wells that cost more than 5 or 7 million to drill.

"oil well finding procedure" am still wondering about this one its different than the regen shares thing

methane hydrates may go well with nernst battery effects. the nernst battery uses a plurality of microareas with different concentrations of the same ion to make electricity, warmed methane hydrates produce fluid motion with varied ionicity at ocean
water, thus nernst battery warmers could lay on methane hydrates spontaneously generating electricity to warm or mill methane hydrates under a transport tube.

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

at some situ process like oil shale the hydrocarbons are warmed awhile I think a chemical tracer that visualizes the actual warmth at a variety of places as well as fluid motion as well as actual possible hydrocarbon modifications could be accomplished
with a hydrocarbon that had a number of tremosesnitive groups on it. amazingly dextrose which is basically hydroxylated 11acane might be a model of compounds that could change color or isotopic ratio with gradual thermal activity. creating these tracer
chemicals permits the gathering of lots of data on which part of a situ well, at what temperature, at what duration, produces the highest yield. noting that even with combusting gas at a cylinder micromapping the activity profile causes large efficiency
from engineering modifications accurately describing the situ process with a chemical tracer is likely to be beneficial
Noting that the US can have as much 40 to $70 USD per bbl Canadian Tar sand or possibly shale oil if a pipeline is built, the creation of better cheaper pipelines as well as cheaper oil transport containers creates cheaper petroleum at the actual user. a
simple pipeline modification which may reduce environmental risk is simply a \-O-/ pipe with a tray shape, where the tray would typically direct possible spillage to a lined micro reservoir. This system absent moving parts could create greater pipeline
permissability, 40 to $70 oil from canada competes with 100$ valuations, pipeline technology thus reduces oil costs 20 to 30 pct. (note the multiyear average however determines the actual applicability of pipeline technology
) a sensor variation of greater pipeline functionality uses a flow sensor with a tiny storage loop, if the presure fluctuates the storage loop fills, which gives sufficient pressure variation reduction as well as timing cushion to keep the rest of the
pipeline from reacting to an under or overpressure event.
(better with image)
surface oilshale or tar sand could have the hydrocarbons concentrated with rapidly flinging the oilshale or tar sand at either snow or warm salt, which may be available at the immediate area. basically grinding the oil shale or tar sand with salt of some
temperature transfers the material from the mineral chunks to the salt chunks, then dissolve the salt with water, the hydrocarbons then float or otherwise accumulate, then the salt can be recrystallized. Noting that Canada has a vast snow resource, it
could actually be that flinging tar sand at crystallized water then then grinding may actually concentrate hydrocarbons as well much more cheaply. depending on the chemical engineering warmable salt or plentiful water crystals should adsorb much
hydrocarbon from the mineral surface
I think they noticed already yet it was fresh to me, a blob of hydrocarbons frequently floats on a pool of melted hydrocarbons thus there may be zones of hydrocarbon concentration at a situ oil process from oil shale or tar sand where higher
concentrations of particularly valuable hydrocarbons occur, that gives the possibility of "slurping" just that part of the resource that is more highly valued at a particular time. If oil is cheap then slurping lighter hydrocarbons from heptane to 11ane
might be economically functional to maintain economic competence then when the price fluctuates the larger mass of heavier hydrocarbons is of sufficient value to slurpbasically if you structure a situ process right the "soup" generates areas of sustained
"cherry picking" while the oil company waits a few months such that the main resource is valued ab at a sufficient margin
I already partially described this an opportunity to create carbon neutral hydrocarbons from methane hydrates would be to use Fe enrichment at a cassion over an area
compressing a slightly spreadable chunk of oil shale or tar sand causes it to have crenellated edges, then placing a force tangent to the compression causes the microedges to come apart this could be a cheaper approach to getting smaller chunks or
particles to make fluidized bed applications
modifying the specific warmth of water vapor when they do situ hydrocarbon gathering they frequently use warm water vapor "steam" is there a way to get water vapor to carry greater specific warmth

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

clathrates, methane hydrate crystals spontaneously occur at ocean depths where pressure is sufficient to crystallize them, now along with currently known clathrates it occurs to me that there may be ancient clathrate deposiots where a coating of material
has accumulated on them to keep them from redissolving on pressure fluctuation perhaps then these ancient clathrates near sunduction zones may have been warmed to the point where they became longer hydrocarbons like oil, thus the novel idea of finding
ancient clathrates, at early paleozoic deeper parts of the early paleozoic ocean that are near plate tectonic edges may have oil
ocean coasts are where lots of nutrients fill the water creating greater biomass that could turn nto hydrocarbons Mapping the ancient coasts at the early or possibly prepaleozoic era gives a kind of area representation of where previous biomass
accumulations may have occured. Then with that data finding the staigraphic crumples that accumulate mobile hydrocarbons suggests places oil may be located.
Noting that of half the giant meteor craters surveyed apparently half have petroleum accumulations as the result of fresh stratigraphic crumple permitting accumulation, it is possible that early or prepaleozoic giant meteor craters that have ceased being
physical features may exist as hidden crumples, these could be found with isotope profiles of mineral cores
wikipedia says there are two or three times as much hydrocarbons at oil shale than there is known liquid petroleum thus thinking about ways to make oilshale as well as tar sands give useful petroleum more cheaply I think that these techniques may be of
benefit
Ionic Water conducts electricity, magnetohydrodynamics is a well establishied field, perhaps mass produced coils of icewater painted on blobs of tar sand or chunks of oil shale would absorb electromagnetic energy, as conductors, then develop a magnetic
field railgunning the blob of tar sand or chunk of oil shale at a cruncher or absorptive surface. although water based electromagnetic windings would be rather unefficient, the process warmth from the electricity could be used to warm the tar sand or oil
shale anyway. the advantage of suddenly flinging tar sand blobs or oil shale chunks at high velocity is that creating microparticles creates greater surface area to benefit hydrocarbon gathering. there is a weird possibiity of hypercentrifuging tar sands
this way as well to gather fluids
I have wondered if warm tar sand or oil shale tumbled on an absorbent surface could gather hydrocarbons as a goop transfer process creating the most efficient cheap reusable goop transfer surface might go like this There is an ngredient at 0w40 motor oil
that starts with lauryl, basically it is like an alkane that likes to be coiled up at one temperature, then lengthens at another temperature, permitting identical viscosity at a wide range of temperatures so basically you make a polymer sheet of a
material with a similar wads up at a particular temperature polymer, have the warmed tar sand coat the absorber, then run the absorber through another temperature area where the lauryl alkaneish like polymer changes shape, releasing the absorbed oil

(nift) Mixing tar sand with salt to transfer the goop onto the salt then dissolving the salt at water then floating up the hydrocarbons to purify them may be an effective way to concentrate hydrocarbions from tar sands. Another approach would be
flinging tar sand at high velocity nto snow which would abrade off the hydrocarbons, then melt the snow to gather hydrocarbons on water snow or ice may be a plentiful resource at some areas, salt occurs at geologic deposits



another possibility of this is haloplastics or trhings like a PVDF (pvdf pizeoelectric polymer) variation where under an electric field the stickiness of the absorbant sheet varies
another possibility of this that might be radically cheap is to engineer or breed a custom diatom surface where the little siO2 covered creatures act like oil velcro, yet you can grow massive amounts of them cheaply, with any kind of surface
configuration is most effective, similarly CaCO3 surfaced microcreatures could be used, with the possibility that pH treating the CaCO3 absorbent surface could yield oil with co2 plus some CaO
an approach that seems ncredible to me, yet I wrote it is to put tar sand on a taffy puller, which linearizes the longer alkanes at the goop, sort of like the way polyethylene goop is algned to be strong along a filamentous dimension. after you have
massively linearized tarsand goop you bring a chemical like ethidium chloride, or some kind of ethidium bromide workalike that is very cheap, ethidium bromide ntercalates between dna strands as it is just the right shape, so a cheap chemical that visited
the nterstitices between massively parallel tar sand would also happen to have a reactive metal atom near its core, thus reacting to divide the lengthy alkanes of the tar goop, which produces lighter more highly valued hydrocarbons like octane
I have read that during the 20th century much water was used to clean hydrocarbons (remove ions, sulfur etc) it seems pretty simple to float up the oil then gather it yet there is another approach as well, have the wastewater travel to a vegetation based
water treatment area where the plants or microorganisms actually absorb or accumulate petroleum, then some of this could be regained. ridiculous.
large amounts of natural gas ch4 have been found with much larger amounts available creatring a process to turn ch4 to liquid hydrocarbons would be of strong benefit one approach is a methl chloride reaction approach chlorine gas from electrolysus of
ocean water is available anywhere notably at ocean ch4 deposits, chlorine gas with ch4 will spontaneously react to form ch3cl or cl-ch2-cl although the reaction is hundreds or thousdanmds of times more rapid with UV radiation to wiggle the orbitals up Mg
very prevelent at ocean water may be a catalyst here as well Thus I suggest making methyl chlorides from ocean water with natural gas using a big UV harvester from sunlight or possibly some human source. the methyl chlorides are liquid whichg makes them
cheaply transportable as compared with billion dollar gas ocean cargo things I have heard of. what to do with the methyl chloride at port to make higher length alkanes like octane well, its my impression that the chlorine groups are removable with
electricity to build longer hydrocarbons an important risk of this technology though is that cl-c-cl hydrocarbons are powerful greenhouse gases
if you place to containers of water at sunshine one with blue liquid will warm faster as it absorbs radiant IR IO have wondered if the rapidity of travel of warmth through situ warmed hydrocarbon wells (there are multiple patents on artificially warmed
oil wells) depends on the IR radiant warmth absorptivity of the minearl or mineral water medium If it does, which would make sense, then there may be a very cheap IR absorptive water soluble colorant that causes underwater flows near oil wells to conduct
warm,th noticeably faster noting that the patents on situ warming of oil wells sometimes spend 300 days to warm a well a warmth conduction fluid technology that reduces that even 10 pct could be of noticeable value

this ones pretty peculiar as i feel some other method of mapping geologic features muast have previously been used, yet it is an approach to finding oil resources of a certain macroscopic size things of a particular size have a resonant frequency, thus
something like a ^ crumple that collect hydrocarbons actually has a size based resonant frequency even though the feature is very large, similarly a valuable nonpermeable layer under a ^ particularly absent flowing water has a greater likelihood of
storing hydrocarbons. this is a way to find previously unfound ^ all over the earth rather than from observational geology or near area mapping efforts the period of a wave that matches a thing like a ^ hundreds of feet or possibly a third of a kilometer
large is kiind of near (or I think its kind of near) a third of cycle per second, I think at the shore a big artificial wave shaper (kind of like a breaker) could create these third of cycle per second resonant waves. these huge masses of water would
then thud against a big transducer, like 10 or 20 I beams welded toger, where the I beams were actually attached to a nonpermeable stratigraphic layer underwater, then because sensors are pretty good, you could look to find resonant ^ macroscopic
features hundreds or thousands of kilometers away locating large numbers of previously unknown petroleum accumulating geostructures at farther distances

creating a new catalyst that turns long goopy alkanes to littler more preferred alkanes like octane may go like this create a big loaf pan sized molecule that a 20 carbon or similar sized alkane could fit at, where the higher energy tips of the big
alkane might tend to linger slightly near the Cl which would have a tendency to briefly residencize the lengthy alkane on the structure, if that occurs, then the midarea has a catalytic metal atom, or group of atoms, which sometimes encourage the long
alkane to divide. Now basically as this loaf pan molecule is visited billions of times a second with hydrocarbons, ocassionally it will work. if it were a protein, a protein chemist would say "obviously" that a normal procedure. yet at a mostly
nonorganic molecule this might be a new idea at petroleum catalysis this version uses Chlorine to preferentialize the tips of the long alkane lingering, with an Si-kane (partial silane) on the way to the catalytic metal core to be as unnteresting to the
c-c-c-c alkane as possible, with Mg as the metal atom at the core cause its cheap, yet is known to affect carbon carbon links (kind of it is published as c=c to c-c) then I made the midarea from two long identical parts so it would be more stronger that
the visiting alkane

from( c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c to two c-c-c-c-c-c-c-c-c )

c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c-c
Cl Cl
C-Si-Si-Si-Si-Si-Mg-Mg-Mg-Si-Si-Si-Si-Si-C C-Si-Si-Si-Si-Si-Mg-Mg-Mg-Si-Si-Si-Si-Si-C
Cl Cl


methane hydrates known as clathrates occur underwater where oceanic pressures are sufficient to cause them to crystallize merely bringing them near the surface liberates ch4 gas which is an opportunity as well as a risk at a different idea I wrotew
sabout using cassions to isolate an area, I think that building an underwater, water filled, cassion on top of a methane hydrate deposit would create a biological reprocessing opportunity. one company says it has a microorganism that converts
hydrocarbons a ch4 bubble filled macrocassion could be a hige bioreactor where the bacteria or algae convert all the bubbling or dissolved ch4 to another product yet only at the circled area, with the fluid moving from the top measured as being
environmentally benign. the bacteria are then harvested for products or hydrocarbons

custom sustained explosion fracing The square of the distance law suggests that a pulse of pressure an order of magnitude higher than the usual fracing pressure would drive the microfractures as well as their maintaining proppants much deeper creating a
much larger area permeabalized to gas flow Thus I suggest a kind of new sustained explosion that lasts say an entire second, rather than a few milliseconds Most nitrogen based explosives just ncrease their volume suddenly with tremendous rapidity I think
it is possible to make a more gradual explosion fracing graphs at patents suggest fracing occurs at like 1/2 an hour to an hour it could be that a regular bunch of high pressure gradual explosions could spped fracing area progession rapidly while [
permitying the fracing equipment to be nonharmed as it is just a hydraulic momentary hyperpressure an order of magnitude greater than that which could be accomplished with fracing fluid pumps at engineering value efficiencies ( it might be possible to
make a fracing pump with an order of magnituide higher pressure yet wouldnt be cheap enough to make or use) so the combination of gradual explosion based hyperpressure with ordinary fracing pump technology is the thing that fracs more rapidly as well as
deeply while being cheap

viewing diagrams of oil recovery wells sometimes they place high pressure fluids or gases near the area to repressuize a well now visualize two wells comparatively near each other ( ) ( ) each with their own pressure with one overpressure, one
underpressure measurement. I think that sometimes merely connecting the two wells could create a pressuization at the sufficiency range from just connecting the two wells as obvious as this idea is it is automating it with software (the sotware is the
thing) at an area with dozens of wells that makes it particularly valuable as the software could describe the optimal pressurization sharing path to keep the largest amount of petroleum producing area at the overpressure that actually produces oil as to
what connects two ( ) ( ) differently pressuized well areas I thought this could be a fracinglike technology at just a ( )-( ) near area although even surface connectors might work

torsional oil well pressurization visualize three or more stacked planar cookie sheets with cookie dough between them, then grab opposite corners ,[]' of the stack then twist what happens to the cookie dough it squishes towards two areas just off center
Now think of geostratified areas near an oil well what happens if you do gradual explosions or well pressurizations, do they also torsionally concentrate oil possibly so, what matters though is that the geometry of the system is software predictable
telling you how much gradual explosive or pumped pressure to use to pool resources of a predicted viscosity

I do not know if doppler seismology is used at pertoleum geology or not. basically mineral layers have different bandpass area to different acoustic frequencies a doppler (basically just pitch shifting) acoustic beam would pass through the permitted
bandpass of all the layered mineral types which gives greater distance as well well as resolution of mapping. rather than measuring moving oil, I use the word doppler to mean a pitch shifting acoustic beam from a moving transducer which is apparently new
to wikipedia

Niche variation stochastics prediction doftware this is a petroleum geology hydrocarbon prediction software thing I think that at areas that produce say oil, there is a cveratin amount of natural variation ofd preferred terrain (er, stratigraphic mineral
diversity) say 7 kinds of dolomite, so you search a big databse to find any area that also has 7 different kinds of dolomite, then you compare that with areas that have only three kinds of dolomite, or 14. the idea here is sort of that when biomaterials
originally accumulated they did so with environmental variation, kind of like treeline zones near brush or something, only these are algal goop communities. one species communities might have very different petroleum as a result compared with 7 species
communities, thus finding a place with 7 kinfds of dolomite might actually be saying, this area had a variety of biomass accumulation zones, some of them productive. yet an area with 14 kinds of dolomite might say "this area had numerous biomass zones,
yet it is possible they were so diverse as to create only minimal concentrated volumes of product" whereas the 1 dolomite zone might say "if this is the right kind of dolomite, you've got a lot of hydrocarbons, yet the wrong kind of dolomite means no oil
(saudi arabia compared with white cluiffs of dover) so the software could look at the big geology database then find likely new comparatively conservative high likelihood of finding oil areas with 3 to 5 kinds of dolomite. then of course the petroleum
geologist would also have the software look to find nonpermeable base layers as well as hydocarbon accumulating strata ^ I mention this as it is a conceptual alternative to just looking to find ^ structures near coasts, as it actually looks to find
previous biotic communities of the diversity likely to give oil

visualize a mountain range like the cascades, (note this is different than suggesting there is oil at the cascades) then connect all the mountain peaks with one graph, it looks like a lot of triangles, then connect all the valley bases with each other,
looks like a lot of triangles. Now using those two graphs you could likely predict which way water would flow, right? with where it came from up high, as well as possible flow paths. Now ignore the entire mountains n valleys part, then look at is as a
deep stratigraphy grapher which shows where thing come from as well as would prefer to go. now use the valleys n mountains part again, only this time guess where paleozoic mountains n valleys actually were, suggesting how their biomass would concentrate.
then compare the stratigraphic map of actual known resources with the paleozoic mountin n valley resource model do the two correlate anywhere, if they do you found the math to find more oil at similar places with the software





Those rotating mass oil pumps appear to be improvable, there must be a variety of preferred pump velocities or pressures yet the pump mass appears the same, possibly a slider arm to give different length, or a side area to place mass would permit
customization to each well.
viewing the well data of a horizontal well there are minute to minute descriptions of a variety of data as well as location data at about 10 foot areas, I think that using a laser or xenon pulse light chromatogram or spectroscopic characterization of the
drillhead fluid would give minute to minute updates of the fraction of hydrocarbons permitting minute to minute steering of the drillhead towards the richer area of the well. The well graphs strongly emphasize that a graph spacing area [][][] can make a
double or triple petroleum flow difference, possibly steering nearer the richer hydrocarbons minute to minute creates a well that is 3 to 7 pct more productive
thinking of the thumper of the movie dune, I think that midwell at horizontal wells,
|
| .... . . . . . ... .....
|==========(thumper)======== a vertical thumper could cause flexing of the sedimentary material possibly causing petroleum to pool around certain areas ( .... .. .) thus moving it towards the well
noting that if each of the one per million most thoughtful Chinese thought of one new petroleum geology idea each year those 1400 new petroleum geology ideas would greatly benefit China Wen If you are a sound deep thinker create a new petroleum geology
idea each year Jiabao I think the DHAClinton approach of naming politicians something beneficial to remind people of it could reach them. The pemeiere of China could augment their name to see if it worked.

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