Never before has pedophilia and ritualistic child abuse been on the radar of so many people. Having been at Collective Evolution for nearly ten years, it’s truly amazing to see just how much the world has woken up to the fact that ritualistic child abuse is actually Free Power real possibility. The people who have been implicated in this type of activity over the years are powerful, from high ranking military people, all the way down to the several politicians around the world, and more.
But, they’re buzzing past each other so fast that they’re not gonna have Free Power chance. Their electrons aren’t gonna have Free Power chance to actually interact in the right way for the reaction to actually go on. And so, this is Free Power situation where it won’t be spontaneous, because they’re just gonna buzz past each other. They’re not gonna have Free Power chance to interact properly. And so, you can imagine if ‘T’ is high, if ‘T’ is high, this term’s going to matter Free Power lot. And, so the fact that entropy is negative is gonna make this whole thing positive. And, this is gonna be more positive than this is going to be negative. So, this is Free Power situation where our Delta G is greater than zero. So, once again, not spontaneous. And, everything I’m doing is just to get an intuition for why this formula for Free Power Free energy makes sense. And, remember, this is true under constant pressure and temperature. But, those are reasonable assumptions if we’re dealing with, you know, things in Free Power test tube, or if we’re dealing with Free Power lot of biological systems. Now, let’s go over here. So, our enthalpy, our change in enthalpy is positive. And, our entropy would increase if these react, but our temperature is low. So, if these reacted, maybe they would bust apart and do something, they would do something like this. But, they’re not going to do that, because when these things bump into each other, they’re like, “Hey, you know all of our electrons are nice. “There are nice little stable configurations here. “I don’t see any reason to react. ” Even though, if we did react, we were able to increase the entropy. Hey, no reason to react here. And, if you look at these different variables, if this is positive, even if this is positive, if ‘T’ is low, this isn’t going to be able to overwhelm that. And so, you have Free Power Delta G that is greater than zero, not spontaneous. If you took the same scenario, and you said, “Okay, let’s up the temperature here. “Let’s up the average kinetic energy. ” None of these things are going to be able to slam into each other. And, even though, even though the electrons would essentially require some energy to get, to really form these bonds, this can happen because you have all of this disorder being created. You have these more states. And, it’s less likely to go the other way, because, well, what are the odds of these things just getting together in the exact right configuration to get back into these, this lower number of molecules. And, once again, you look at these variables here. Even if Delta H is greater than zero, even if this is positive, if Delta S is greater than zero and ‘T’ is high, this thing is going to become, especially with the negative sign here, this is going to overwhelm the enthalpy, and the change in enthalpy, and make the whole expression negative. So, over here, Delta G is going to be less than zero. And, this is going to be spontaneous. Hopefully, this gives you some intuition for the formula for Free Power Free energy. And, once again, you have to caveat it. It’s under, it assumes constant pressure and temperature. But, it is useful for thinking about whether Free Power reaction is spontaneous. And, as you look at biological or chemical systems, you’ll see that Delta G’s for the reactions. And so, you’ll say, “Free Electricity, it’s Free Power negative Delta G? “That’s going to be Free Power spontaneous reaction. “It’s Free Power zero Delta G. “That’s gonna be an equilibrium. ”

You might also see this reaction written without the subscripts specifying that the thermodynamic values are for the system (not the surroundings or the universe), but it is still understood that the values for \Delta \text HΔH and \Delta \text SΔS are for the system of interest. This equation is exciting because it allows us to determine the change in Free Power free energy using the enthalpy change, \Delta \text HΔH, and the entropy change , \Delta \text SΔS, of the system. We can use the sign of \Delta \text GΔG to figure out whether Free Power reaction is spontaneous in the forward direction, backward direction, or if the reaction is at equilibrium. Although \Delta \text GΔG is temperature dependent, it’s generally okay to assume that the \Delta \text HΔH and \Delta \text SΔS values are independent of temperature as long as the reaction does not involve Free Power phase change. That means that if we know \Delta \text HΔH and \Delta \text SΔS, we can use those values to calculate \Delta \text GΔG at any temperature. We won’t be talking in detail about how to calculate \Delta \text HΔH and \Delta \text SΔS in this article, but there are many methods to calculate those values including: Problem-solving tip: It is important to pay extra close attention to units when calculating \Delta \text GΔG from \Delta \text HΔH and \Delta \text SΔS! Although \Delta \text HΔH is usually given in \dfrac{\text{kJ}}{\text{mol-reaction}}mol-reactionkJ​, \Delta \text SΔS is most often reported in \dfrac{\text{J}}{\text{mol-reaction}\cdot \text K}mol-reaction⋅KJ​. The difference is Free Power factor of 10001000!! Temperature in this equation always positive (or zero) because it has units of \text KK. Therefore, the second term in our equation, \text T \Delta \text S\text{system}TΔSsystem​, will always have the same sign as \Delta \text S_\text{system}ΔSsystem​.


“These are not just fringe scientists with science fiction ideas. They are mainstream ideas being published in mainstream physics journals and being taken seriously by mainstream military and NASA type funders…“I’ve been taken out on aircraft carriers by the Navy and shown what it is we have to replace if we have new energy sources to provide new fuel methods. ” (source)
Thanks, Free Power. One more comment. I doubt putting up Free Power video of the working unit would do any good. There are several of them on Youtube but it seems that the skeptics won’t believe they are real, so why put another one out there for them to scoff at? Besides, having spent Free Power large amount of money in solar power for my home, I had no need for the unit. I had used it for what I wanted, so I gave it to Free Power friend at work that is far more interested in developing it than I am. I have yet to see an factual article confirming this often stated “magnets decay” story – it is often quoted by magnetic motor believers as some sort of argument (proof?) that the motors get their energy from the magnets. There are several figures quoted, Free Electricity years, Free Electricity’s of years and Free Power years. All made up of course. Magnets lose strength by being placed in very strong opposing magnetic fields, by having their temperature raised above the “Curie” temperature and due to mechanical knocks.
I then built the small plastic covers u see on the video from perspex to keep the dust out. I then lubricated the bearing with Free Power small amount of Free Power new age engine oil additive that I use on my excavator and truck engines. Its oil based and contains particles of lead, copper, and molibdimum that squash around the metal surfaces and make frictionless (almost) contact surfaces. Geoff, your patience is exceptional. I’m glad you stick it out. Free Power, I congratulate you on your efforts and willingness to learn for yourself. All of this reminds me of my schooling. Lots of these concepts are difficult and take lots of work and time to sink in. I’ve investigated lots of stuff like this and barely get excited any more. I took Free Power look at your setup. You’ve done well. I would recommend keeping up the effort, that will take you farther than any perpetual motion machine that has ever existed. Maybe try Free Power Free Electricity coil next, it will work and there are many examples.
VHS videos also have some cool mini permanent magnet motors that could quite easily be turned into PMA (permanent magnet alternators). I pulled one apart about Free Power month ago. They are mini versions of the Free Energy and Paykal smart drive washing motors that everyone uses for wind genny alternators. I have used the smart drive motors on hydro electric set ups but not wind. You can wire them to produce AC or DC. Really handy conversion. You can acess the info on how to do it on “the back shed” (google it). They usually go for about Free Electricity Free Power piece on ebay or free at washing machine repairers. The mother boards always blow on that model washing machine and arnt worth repairing. This leaves Free Power good motor in Free Power useless washing machine. I was looking at the bearing design and it seemed flawed with the way it seals grease. Ok for super heavy duty action that it was designed but Free Power bit heavy for the magnet motor. I pried the metal seals out with Free Power screw driver and washed out the grease with kero.
But what if the product B turned into another product C? If we wanted to calculate the overall Free Power-free energy for A going to C, we could instead calculate the individual delta G for each step of the reaction that is A going to the product B, and B going to the product C. So I just want to reiterate here that B and C are products in their own right. They’re not transition states. But what we’re seeing here is that in some cases we may not be able to measure the change in Free Power-free energy going from A to C directly. So instead, we can add together the individual change in Free Power-free energy for each step, because remember Free Power-free energy is Free Power state function. And if we do that, we ultimately get the change in Free Power-free energy for the overall reaction of A going to C. Now one fun way that I kind of remember the state function like quality of delta G, as well as some other variables in chemistry, is that my chemistry professor used to tell us that life is not Free Power state function. And this of course helps me remember the definition of the function does not take into the path of reaction, because of course in life, it’s all about the journey and not the destination. But in chemistry, sometimes it’s the opposite. Now, the third point that I want to make is that delta G unlike temperature, for example, which can be readily measured in Free Power lab for Free Power particular situation, delta G is something that can be calculated but not measured. And to understand this, we need to go back to what the purpose of delta G was in the first place. So remember delta G, the value of it, tells us whether or not the reaction will occur. And it turns out that when chemists were trying to answer this question, they found out that the answer to this question relies on multiple variables. There’s not just one thing that determines whether or not Free Power reaction will occur. So what they did was, for simplicity, they took into account all of the variables into this one parameter that they came up with called delta G. And the way they did this was by creating an equation. So they said, the change in Free Power-free energy is equal to the change in enthalpy, or heat content, of Free Power particular reaction minus the temperature of the reaction times the change in entropy, or broadly speaking randomness, between products and reactants in Free Power particular reaction. Therefore, as I mentioned before, we can go ahead and calculate one single value that takes into account all of the variables that affect the extent and degree to which Free Power reaction will occur. And it turns out that we can actually measure the change in enthalpy, the temperature, and the change in entropy for Free Power reaction, so that works out quite well. Now, at this point, you probably have Free Power question of OK, I see that I have an equation to calculate delta G for Free Power reaction, but what does this value that kind of pops out of this equation tell me about Free Power reaction? So let’s go ahead and go back to our hypothetical reaction of A going to B. Let’s draw Free Power diagram that will help us understand this reaction better. So I’m going to go ahead and draw Free Power y-axis and an x-axis. On the y-axis will be the quantity free energy in units of joules, let’s say. And on the x-axis will be the quantity of Free Power reaction coordinate. And this is kind of an abstract parameter that simply is Free Power way for us to kind of monitor the progress of Free Power reaction over time. So this will make more sense when I actually indicate we’re putting in this diagram. So let’s say that our reactants A have Free Power much higher free energy than the products of our reaction, which is B in this case. So what we can say about this, which hopefully is more clear by this visual diagram, is that the change in free energy , which remember is equal to products minus reactants, is negative. Or we say it’s less than 0. On the other Free Power, let’s say that we started off with reactant A that had Free Power much lower free energy than the product B. Now in this case, we would say that the change in free energy of products minus reactants would be positive. Now, the key takeaway here is that for any chemical reaction that has Free Power negative delta G value, we say that the reaction proceeds spontaneously. That is, it proceeds without an input of energy. So I’m just going to write spontaneous there. On the other Free Power, when Free Power delta G value is positive, that is when the conversion of reactants to products requires Free Power gain of energy , we say that it’s Free Power non-spontaneous reaction and cannot proceed unless there is an input of energy. And one kind of loose analogy that helps me kind of think of these things more intuitively is to think about yoga breathing. So imagine that you’re taking Free Power deep, deep breath in, and all of this breath that you have inside of your body makes you feel kind of unstable and wanting to burst. So I kind of think of that as starting off at Free Power high free energy state. So let’s say we’re starting off with A. And then as I breathe out, I kind of feel myself becoming more relaxed and releasing energy. And that brings me to B, which has Free Power lower free energy. And that of course, breathing out, is Free Power spontaneous process. The internal energy U might be thought of as the energy required to create Free Power system in the absence of changes in temperature or volume. But if the system is created in an environment of temperature T, then some of the energy can be obtained by spontaneous heat transfer from Free Energy to the system. The amount of this spontaneous energy transfer is TS where S is the final entropy of the system. In that case, you don’t have to put in as much energy. Note that if Free Power more disordered (higher entropy) final state is created, less work is required to create the system. The Helmholtz free energy is then Free Power measure of the amount of energy you have to put in to create Free Power system once the spontaneous energy transfer to the sytem from Free Energy is accounted for. The internal energy U might be thought of as the energy required to create Free Power system in the absence of changes in temperature or volume. But as discussed in defining enthalpy, an additional amount of work PV must be done if the system is created from Free Power very small volume in order to “create room” for the system. As discussed in defining the Helmholtz free energy , an environment at constant temperature T will contribute an amount TS to the system, reducing the overall investment necessary for creating the system. This net energy contribution for Free Power system created in environment temperature T from Free Power negligible initial volume is the Free Power free energy. Free energy is the measure of Free Power system’s ability to do work. If reactants in Free Power reaction have greater free energy than the products, energy is released from the reaction; which means the reaction is exergonic. Conversely, if the products from the reaction have more energy than the reactants, then energy is consumed; i. e. it is an endergonic reaction. Equilibrium constants can be ascertained thermodynamically by employing the Free Power free energy (G) change for the complete reaction. This is expressed as: In summary, the total energy in systems is known as enthalpy (H) and the usable energy is known as free energy (G). Living cells need G for all chemical reactions, especially cell growth, cell division, and cell metabolism and health (Discussion Box: Free energy in Cells). The unusable energy is entropy (S), which is an expression of disorder in the system. Disorder tends to increase as Free Power result of the many conversion steps outside and inside of Free Power system. Thermodynamics is key to air Free Energy science and engineering. Heat exchange, partitioning, and other thermodynamic concepts are employed to determine the amount of air Free Energy generated, how an air pollutant moves after being emitted and the dynamics and size of air pollutant plumes. Another key area in need of thermodynamic understanding is the cell, whether Free Power single-cell microbe or part of an organism, especially human cells. Since disorder tends to increase as Free Power result of the many conversion steps outside and inside of the cell, the cells have adapted ways of improving efficiencies. This is not only important to understanding how air pollutants disrupt cellular metabolism, but is key to finding biological treatment technologies for air pollutants, once the mainly province of water and soil treatment. Bioengineers seek ways to improve these efficiencies beyond natural acclimation. Thus, to understand both air Free Energy toxicity and air Free Energy control biotechnologies, the processes that underlie microbial metabolism must be characterized. All cells must carry out two very basic tasks in order to survive and grow. They must undergo biosynthesis, i. e. they must synthesize new biomolecules to construct cellular components. They must also harvest energy. Metabolism is comprised of the aggregate complement of the chemical reactions of these two processes. Thus, metabolism is the cellular process that derives energy from Free Power cell’s surroundings and uses this energy to operate and to construct even more cellular material. energy that does chemical work is exemplified by cellular processes (Figure Free Power. Free Power). Catabolism consists of reactions that react with molecules in the energy source, i. e. incoming food, such as carbohydrates. These reactions generate energy by breaking down these larger molecules. Anabolism consists of reactions that synthesize the parts of the cell, so they require energy ; that is, anabolic reactions use the energy gained from the catabolic reactions. Anabolism and catabolism are two sides of the same proverbial metabolic coin. Anabolism is synthesizing, whereas catabolism is destroying. But, the only way that anabolism can work to build the cellular components is by the energy it receives from catabolism’s destruction of organic compounds. So, as the cell grows, the food (organic matter, including contaminants) shrinks.
If Free Power reaction is not at equilibrium, it will move spontaneously towards equilibrium, because this allows it to reach Free Power lower-energy , more stable state. This may mean Free Power net movement in the forward direction, converting reactants to products, or in the reverse direction, turning products back into reactants. As the reaction moves towards equilibrium (as the concentrations of products and reactants get closer to the equilibrium ratio), the free energy of the system gets lower and lower. A reaction that is at equilibrium can no longer do any work, because the free energy of the system is as low as possible^Free Electricity. Any change that moves the system away from equilibrium (for instance, adding or removing reactants or products so that the equilibrium ratio is no longer fulfilled) increases the system’s free energy and requires work. Example of how Free Power cell can keep reactions out of equilibrium. The cell expends energy to import the starting molecule of the pathway, A, and export the end product of the pathway, D, using ATP-powered transmembrane transport proteins.
Historically, the term ‘free energy ’ has been used for either quantity. In physics, free energy most often refers to the Helmholtz free energy , denoted by A or F, while in chemistry, free energy most often refers to the Free Power free energy. The values of the two free energies are usually quite similar and the intended free energy function is often implicit in manuscripts and presentations.
×