During 2011 ch4 gas was 7 times cheaper than liquid hydrocarbons per amount of produced energy Thus there is a strong value to creating liquid hydrocarbons from ch4 Many approaches use catalysts This is a new kind of ch4 to liquid hydrocarbon catalyst

Many catalytic materials work most efficiently at particular temperatures as well as pressures, researchers have compared the US diamond anvil technology with the former Russian superbaric hydraulic technology. The Russians made a gigantic hydraulic
machine to research the effect of high pressure on chemistry, the US researchers just used a microsample between two diamond plates to achieve higher pressures while keeping a viewable reaction. Now use semiconductor fabrication technology to create a
million or billion variably sized microchambers on silicon silicon nitride or diamond coated silicon nitride at a flat disk or semiconductor style wafer Then create a second disk or wafer with the complementary impressing shapes of varied sizes. When
sandwiched together with ch4 these million or billion diamond pressure chambers will first describe the optimal pressure regime to do catalysis while various chemical vapor deposited possible catalysts are measured as to their effectiveness at a million
or billion chemical variations. This technology rapidifies catalyst research tens of thousands or hundreds of thousands times more rapidly than 2oth century approaches. Further the diamond disks may be used to catalyze ch4 to liquid hydrocarbons at
production a vibrating system where billions of microtechnology near nanotechnology micropressure reactors like > ] with the right coating of catalyst could actually be used to make the liquid hydrocarbons at the well, which greatly improves energy
portability. A vibrating scroll compression technology similar to two metal vinyl LPs could continually microcompress the ch4 at the catalyst at bulk to produce hydrocarbon liquids

Nanomesh proppants
Proppants are little blobs, sometimes natural silica, that keep microfractures permeable to hydrocarbons propped silicon carbide or nitride proppants are patented thus may have economic value silicon carbide nanomesh is latticelike ultralight silicon
carbide that is about 5 times lighter than aerogel. I think that little eiffelblob proppants would have vastly less mass thus travel further while the fracing water travels through the newly created permeability spaces. The published advantage of the
silicon carbide proppant is that as the geology relaxes with gravity it stays strong enough to keep the micropermeabilities passable longer compared with ordinary silica silicon carbide or nitride nanomesh would be similarly hyperstrong yet travel
further with water. There is also a newer opportunity to clump nanomesh proppants on each other or on ordinary silica. Nanomesh silicon carbide or nitride proppants are engineerable to float, thus one proppant could tend to accumulate as a base,
another as a support, keeping the microchannels open wider longer more effectively. This may also create opportunities to blend two thirds silica proppant with one third nanomesh to create highly value optimizes propped fracing

Quantum linked s d pi orbitals effect quantum inked atoms s d pi orbitals thus causing an electron effect different than outermost electron mobility effects
Its published that twin slit quantum physics experiments work on 114 amu molecules (10 ish boron carbon nitrogen atoms) thus ch4 or even mere hydrogen can be treated as a quantum wave function

Quantum wave functions are linkable yet the specific state of the atom or molecules electron orbital configuration is part of its quantum identity to have two linked atoms or molecules they are more coherent if they share precisely the same orbital
configuration. Thus it imaginable that when quantum linking two benzene atoms the moment of linkage would be better more coherent more durable, more nformationally particular if they both are at either chair or boat version simultaneously. Now if we
link two hydrogen atoms or two ch4 molecules then radically change the electron orbital characteristics at s d p or pi orbital area, this quantum linkage may apply to the linked atom, it may have susceptibility of detectability if it has the same
configuration momentarily, the susceptibility of detection particulariuzes the electron orbital state, creating a modified atom at a distance. Note we didn’t actually do anything to the distant atom, we were just able to observe it when it
momentarily went out of synchronization with the other atom or molecule at the lab. This very different structuralization of the near nucleus electrons may well produce a very different observable effect the molecule is likely to disintegrate, or an
atom is likely to emit a very high energy photon events that may be detectable at greater distances than electricity or most em waves The petroleum geology idea then is to beam quantum linked atoms or molecules as waves then when they meet long
hydrocarbons they sychro freak out which causes detectability so its an actual way of mapping hydrocarbons directly rather than from acoustic reflection or near area EM when you think about sending a beam of deep electron linked atoms through space or
material as a result of a modified twin slit experiment it is kind of like a new kind of electricity as it effects nonoutermost electrons. Things that move only outermost electrons are the previous kind of electricity. Then there are also published
proton conduction technologies, these actually use proton movement at circuits or reactions.

Lets compare this to quantum radar which is apparently authentic
Quantum radar is a hypothetical remote-sensing method based on quantum entanglement.
One possible implementation of such technology has been developed and patented[1] by defense contractor Lockheed Martin.[2] It intends to create a radar system which provides a better resolution and higher detail than classical radar can provide.
The technology is hoped to work by using photon entanglement to allow several entangled photons to function as if a shorter wavelength was used to allow detection of small details while having an overall longer group wavelength that allows long distance
transmission.
Here a big company says you can beamcast what amounts to an array telescope of quantum linked objects to get a more detailed view the version I describe just says you can make an effort only to observe part of the electron orbital volume or positions of
a quantum beamed atom or molecule The similarities suggest that supertricity or um, mezzanine electrons mezzotronics qlme quantum linked mezzanine electronics may be functional

Its possible Nernst battery proppants could make a surfactant from ambient fluids carboxylating an alkane or using chlorine from electrolysis to give a lipophilic on one area hydrophilic at another area molecule
This is likely to already exist yet an acoustic beam travelling on a vehicle with a acoustic sensor stationary at a different location could systematically traverse an area raster scanning geofeatures at depth Its also possible to have both the sensor
as well as the beam mounted on separate travelling vehicles to gather higher quality data or possibly to supervisualize an area found to nifty at the time of measurement
Geologists use fluid tracers now It is possible that chemicals that delay activation to trace could be placed at one area, then portions of the chemical become active to reacting with situ environment thus reacting along the way to grapg the actual
chemical environment at a variety of places from one tracer fluid application --------------------(gloms reacts)—Measure
---------------(gloms reacts)--------Measure
-----(gloms reacts)------------------Measure
-(gloms reacts)----------------------Measure
As the tracer travels just some of it gloms then reacts, the detector or chemistry can tell which stage of reaction occurred where at the mineral resource

Some petroleum geology processes use warmth to convert or fluidize hydrocarbons it is possible that an IR reflective fluid at situ could concentrate warmth to more effectively modify situ keorgen as well as petrochemicals

Clumps of sedimentary material have silt grains chunks each of these is responsive to different drilling forces its kind of like the opposite of a fascht if a drill had side supports that tend to compress an area such that the chunks or grains have
greater force at their preferred area of division then drilling is more rapid, compare aligned crackers at parallel== or perpendicular (splat) these have different efficacies of material dividing at a particular pressure

Its possible some geostrata or minerals like dolomite have varying waters of hydration at the crystals That suggests that there is a specific warmth or chemical treatment to change the numbers of waters of hydration which changes the volume either
creating greater permeability of causing heightened pressure to move fluids Geostrata that pool hydrocarbons sometimes have a ^ shape that pools hydrocarbons one approach is to change the mass atop the ^ formation at the gulf coast as well as other offshore areas it may be possible to make a cassionthat completely removes a
massive overmass of water, thus causing hydrocarbons to appreciably move towards the depressurized cassion area regenerating wells
Canada as well as Russia has lots of tar sands as well as oil shale I think it may be possible to use frost heave to repeatedly scrape as well as divide water petroleum mousses to concentrate petroleum Among places with snowy winters frost heave can be
applied numerous times each 24 hours. Note that some of these places have resources where tyhere are patents suggesting thermal liquefaction or softening, It is possible the naturally occurring cool resource at some loacations could be used to gather
hydrocarbons
Noting that some hydrocarbon resources have fossil parts I think it may be possible to generate acoustic energy that is responant at the particular sixe n mass of the fossil parts, the emphasis is actually just creating slightly greater permeability as a
result of deep wiggling shapes
Kerogen may be radicalizable or reactivatable (like olefins as destaurated may be reactable) at particular defined surroundings, the creation of these reactants at situ, then at a different temperature as well as pressure furthers reactions that soften
or liquefy kerogen, the patents show very different kerogen reactivities at different temperatures, thus I think this may work. I think I have previously written about if you make 1 pct heptane, will that mobilize dodecane better than dividing dodecane
to two decanes? Similar thinking only with reactivity rather than molecule size
I do not know if tar sands with microliquefaction channels would give hydrocarbons more rapidly yet I think it might be possible to create a high viscosity yet high mass oil right on site that rather than floating, would tend to mingle with thicker
gooeier natural hydrocarbon fluids providing laminar flow separation channels as well as sepration planes throughout the heavy goop resource. These channels might then preferentially pass high warmth water to liquefy or soften throughout the resource
Its slightly similar to “fracing” tar with oil, to create widish laminar flow shaped channels that things can pass through










not petroleum geology yet it is possible the electro osmotic effect as described at mit paper 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 size 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 absorb em energy then are rather calm this 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

I just thought of a new petroleum geology technology the various acoustic DSP math approaches all like higher quality data creating a reference datapoint like the way satellite optics using laser standards to figure out actual atmospheric variation
apparently doiubles or triples resolution applied to georesources well gels have different acoustic responses than liquids, yet a gel can turn to a liquid at a predictable interval Thus if you place a gel thatr gradually turns liquid at a hydrocarbon
well sampling area the acoustic behavior of the gel can predictably change from "minerallike" to another acoustic reflectance standard, to oil to water as it "melts" noting that each of these provides a defined spatial area, as well as a defined (yet
changing) density the actual density motion resonance standard the ability of math DSP to know that at a particular time a reference acoustic responsiness like a particular desired mineral or mapped mineral is created. This gives much larger data
reference objectness than just one chunk of bismuth or the like, as it might possibly define a more precise map of where each type of mineral as the reference rotates what it is as the gel "melts" now i write gel yet this could actually be a metal oil
colloid with predictable specific gravity shifts

(nift) hydrocarbons from wells might have microparticulates, possibly also sulfur particles to be removed, thus dilute with liquified natural gas to strongly reduce the viscosity of the fluid permitting much more rapid particle movement towards base, or
having minimal friction through filters, then just change reduce pressure or return to well temperature to separate the cleaner freshened oil from the ch4. ch4 is likely already on site

turning methane to longer hydrocarbons
semipersist or link 3 of 4 Hydrogens at methane to a similar sized nonreactive chemical like a Si polymer that has halogens at some regular spacing, this causes just one hydrogen of each methane to be usually open to reaction with other moving molecules
like other methanes . One approach is to create a molecular passageway approach visualize two planar breadboards with methanes mostly socketed at them, then you stack them = so that the chaneel between them permits gas flow of possible reactants,
like more methane It is possible that a macrocrystal of this could be produced from si or boron (perhaps) gappy lattice crystalline system Anyway you should be able to acoustically or thermally micropressurize it like fizeau circles between two
optical plates (like b refringence spacing effect) to find the optimal spacing to create preferred reactivity
its even possible that if the things like breadboards were wobbled at the right frequency that could create a tosses back n forth right between two energy levels at an an activation energy diagram effect to cause surface energies to kind of oscillate
around a preferred transition activation energy even if the actual system was on either side of the graph of the process

Put superhappiness genes near chromosome centers as these change less than distal parts of a chromosome


well here are some petroleum engineering ideas

noting than rotating a sedimentary mineral or a piece of layered mica causes it to delaminate if you rotate it, (like if you turn a sedimentary mineral rather than edges coming off it separates nto layers) it may be possible to create circular polarized
fracing effects so either fluid or proppants such that they cause rotation of layered material that causes delamination. some sediments have mica, which although there might be rather tiny amounts might have higher porosity if delaminated. rotating
proppants could be a "fancy nozzle" effect


Im kind of wondering ifreverse osmosis has a place at hydrocarbon engineering. Notably reverse osmosis is much energy cheaper than distillation when purifying water, so just possibly some areas of petroleum engineering could benefit from membrane
separation of hydrocarbon blends possibly a little like "condensates" as they are called or the quite different yet plausibly seperable LNG from things like heptane after liquefaction. I think an actual petroleum engineer with raised eyebrow, might say
that the entire reason they do catalytic reformation at high temperatures is to actually produce the differently valued hydrocarbon products, that they cool them down to distill, rather than use energy
(heat to distill)! That honestly its just process energy from the essential cataltic reforming phase. or that column trays act much like a sortation media thats why I wonder about this idea. hmmmmmmmmmmm yet it might work. like what if there were a
low temperature ch4 to longer hydrocarbon process? would a membrane effect make more sense than evaporative distillation

the situ production of electricity from oil shale is a possibility. (eww) mostly because after a period of situ warming from native hydrocarbons, after those kerogens convert then are pumped out as gas or fluid, theres a lot of warm minerals, quite
possibly near a bunch of cool groundwater, which suggests something like cogen, cogeneration which would effect the economics of the entire plant to make the product cheaper, or cover equipment $

wacky reflector supermapping. I once read at a science magazine that the usual parabolic dish when gevien irregular side projections created a slightly modified waveform, possibly even when using the standard central antenna, that made distinguishing
waveform frequencies more possible with DSP, thus creating an earthwork with an irregular projection could be effective at doing better acoustic geomapping at depth


well these might be petroleum geology ideas, some of them are pretty ...optimistic...

using nitrogen containing explosives to frac at the perimeter of a fracing area creates more channelizaion, wider channels as well as the possibility of purposed granules creating nitric acod hno3 from air nitrogen as well as h2so4 from area sulfur
resources may be cheap nitrated carbohydrates like nitroglycerine or nitrostarches or possibly nitrosugars may be frac perimeter ncreasing explosives now the thing is that pumping nitroglycerine underground faces dilution as well as vibration hazards (
nifty) thus i suggest a process to actually form the nitrogen explosives deep at the frac area or perimeter the high molarity hno3 with glycerine reaction to make nitroglycerine is fairly rapid, making a version that takes hours or weeks to react would
permit pumping the reagents to the frac perimeter where they would then combine react then await detonation also pumpinh hno3 to a frac field suggests dilution concerns, thus I think a kind of gel, mousse or sort of liposomalesque mixture of hn03 with
glycerine can be pumped to the frac perimeter also benefitting this approach would be a color changing material so that the goop that gradually turns to nitroglycerine or other nitrogen explosive shows what phase of risk it is at, fluorescent green
just means you see where it is, perhaps a streak on some pipe, so clean it up, fluorescent yellow, prioritize that cleaning, fluorescent red, use spray cleaner from a distance. noting that high energy density oil shale is described as 4000 kilocalories
per something (it may have been lb, possibly kg) creating a nitroexplosive as cheaply as possible makes sense from an energy efficiency perspective. thus the cheapest possible source of nitric acid is really something to think about as regards to a
hydrocarbon reserve equivalent to over 200 years of US current amount, these even cheaper gas separation would be of benefit

thinking about the movement of hydrocarbons whether fluid or gas the permeability of the material affects that, so with percolation theory mathwise it may be possible to look at simple dimensional enhancements. what little i know of percolation theory
sounds sort of 1.n or fractal dimensional mathematically upping that to two dimensions (nifty) creates technology opportunities like this idea have granulaes at a percolationgradient be considered as 2d shapes like Ms pac man if you rotate three or
more of these to face each other (< >) you create a wider flow channel, so what are the stochastic math models of rotating 2d shapes at a percolation gradient to create a superabundance of microchannels to strongly increase fluid flow researching
those mat models gives a description of optimal granuals to permit fluid flow then applying these preferred chunk or granual shapes to what explosives or frac process create causes much higher permeability ncreasing resources as well as rate of value
creation one approach to moving granuals to orient towards channelization is acoustics geothe was the first to notice that particles on a vibrating surface autosorted to regular sometimes rather attractive patterns, thus an explosion that makes ms
pac man granuales then a really loud acoustic that jiggles them towards channelization (< >)to create greater fluid flow is a petroleum geology technology (v)

I previously wrote about how if you grinf up chunks to big n littele , then remix them 0o0.0 then compress, the blend will cause bending then chunk fractionation more rapidly thus creating little chunks with less energy which can the be used at things
like fluidized bed resource utrilization )fuels) or if metals, concentration a differently 1.n or 2 d fractal dimensional approach to this could be even more efficient if you had a bunch of mineral chunks, then were to use a mechanism or possibly light
beam to create a channel the chunk would then have a stochastically likelly nook that another mineral chunk would nestle with, then when compressed to make pieces the resulting microchunks would have a more customizable size distribution ncreasing
efficiency so mathwise what is the most efficient one groove on chunk stochastic rock crushing mix also technologically it is possible that water jt or light beam channelization might be of sufficient energy efficiency to permit this solar light
beam channelization may e possible at some locatiopns that is where a plurality of less ntense beams are each fluttered or turned offnon at the right frequency with a mild rotatator then refocused to create a vibrating light pulse like the pulsed lasers
use to do laser channeling (its not just on, it a modulated beam, so creating a modulated solar bean could come from multi solar beam combination)


(nifty) making oil shale be at tinier chunks to do fluidized bed or different process is of value It is possible that there are large areas of oil shale I have not heard of at near shore ocean areas these could be made to teenier chunks with wave action
float meachines. I read that during 1990s AD grinding minerals was like 2 or 3 pct efficient, so using as fewcalories to grind oil shale is of process benefit. direct wave energy mechanical grinding could make microsized oil shale particles much
cheaper Also it is possible that there are chemoactive processes that use large amount of situ reagents at a different situ oil shale process ocean transport is much cheaper than land transport if large amounts of some cheap reagent (process chemical)
is to be supplied to a hydrocarbon resource, also ocean water may provide some meaningful chemical reagent like MgCl (grignard) or possibly bromine that could be used to make olefins c=c, which have greater industrial value, at a situ process

im wondering if there are alternating width frac hydraulic systems with a sump basically lets say a person uses high pressure high volume fracing at one region, then next to it uses less pressure to create fracs with less diameter or width, then another
region with higher pressurewith greater surface area n width, yet "connecting" these is a drilled valvable path with a reservoir, a sump The engineer then does hydraulic force multiplication on the different frac regions to more strongly widen them (
flow rate) or ncrease frac surface area (available resource)

I have been making an occasional effort to think of a gas additive that makes people live longer, current octane modifying chemicals if they were longevity chemicals would be better.
It is less bizarre than it sounds
Ferrocene is already an approved octane modifier at some countries
so just change that to polyphenol ferrocene
similarly Metal core alkanes have been used as octane regulators. Tin is FDA approved as a food additive, one person at imminst.org thinks tin chloride could improve brain regeneration, so tetraethyl tin could be a gas additive that might test out as
slightly physiologically beneficial. Tin as a part of catalyticconverters to reduce nitrogen oxides is patented, so there is a possibility that an alkane tin could actually reduce pollution slightly as an additive
Simliarly nanoparticles of lanthanides like CeO actually cause nerve regeneration, although Ce is kinda spendy as a gas additive
all metals of course have the potential to affect
Recently the Baati study suggests fullerenes may be beneficial (doubling rodent lifespan). There is an EPA study that says during 1972 about a gram of carbon particulate 1 um or smaller diameter per 100 miles was produced (a fairly tiny amount), also
breathing differs from eating.
So I urge peple here that like chemistry to consider creating a longevity wellness gas additive, wikipedia says over a trillion liters of gas are used worldwide per year, so 1-3 pct of that is 10 to 30 billion liters of Octane modifying additive (of some
types) http://www.carkipedia.com/fuel_systems/gasoline_additives.php a year. 30 billion liters a year is a lot of a xenochemical to absorb, so it makes sense it actually be beneficial to physiological well being
Things to consider are, well, what does it turn into after its used? I utterly doubt that ferrocene polyphenols would persist, then again catalytic converters make an effort to create the smallest molecules from partially modified fuel, so are there any
tiny molecules that are actually beneficial?
If you think large changes could be beneficial, then the catalytic converter can be changed to something that actually makes a larger molecule if it is truly beneficial, like say


(nift) One sort of different approach to giving a frac field a hydraulic ratio multiplier would be to create something that can expand or shrink like a tube shaped like |--- ===| remotely (I wonder what I mean here, perhaps noting that dried
hygroscopic materials will absorb water sufficiently to lift a car or break concrete (plants) I was thinking of a frac proppant with a hygroscopic center that would swell gradually from moisture thus actuall ncreasing diameter with duration rather than
compressing or embedding


(nift)with layered oil shales like the volcanic layered green river formation that has 200 or 300 years of us oil consumption at one place im wondering if the coefficient of bending is noticeably different at the metamorphic layered areas between the
sedimentary layers if so this would provide a sweet spot a kind of torsion number so that if the were rotated the buckling would automatically more efficiently microparticlize the shale also as weird as this sounds the volcanic material may be
partially porous, particularly at certain distances from the prehistoric volcano, where they are if some regions have porous layers between shale layers then oil from the completed process could be pumped back through the porous volcanic layers, then,
get this, solidified, so than an explosion causes a kind of "winshield glass effect" where having a force direction layer (a rubber flat) between two things causes a particular kind of particle size creation, the polymerized oil could be perhaps be
predictably refluidized with situ warmth that was applied to the granulated windsahield effect situ oil shale






I think BINAP reaction could change hydrocarbon polymer length yet the source of the BINAP reagent looks like napthalene with phosphorus, which actually is very cheap as a kind of partial combustion of hydrocarbons makes multicyclic aromatic hydrocarbons,
it works much better with coal, as coal tar is naturally full of near BINAP molecules so I thought that just perhaps adding phosphorus, which although not spectacularly cheap is at leask bulk commodity fertilizer cheap, to partial combusted
hydrocarbons of high molecular mass, could make a kind og BINAPish sludge to cause reactions

Its possible I was thinking that situ oil shale or tar sands processes that use situ warmin or combustion could use a hydrogenation sludge (cheap polycyclic phosphorus containg binap like catalyst) pumped nto their chemospaces. Its possible a tendency
to hydrogenate would actually create more optimal length alkanes from giving hydrogens to the distal parts of divided hydrocarbons -ch2ch2ch2c- or using english, situ cracking with more hydrogen to occupy molecule makes higher yield of little valuable
fluid cheap fertilizer partial combustocataslush makes this happen, possibly.

situ coal to liquid hydrocarbons seems like more of binapslush process


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