Human Energy?!

Guys did you ever get to know that Humans have magnetic and electric field on their body and if are eager enough to to learn about that, then join & enjoying reading.

These magnetic and electric field can solve many of our problems and maybe in future we can come up with so many innovative project ideas based on this so that i could help making in a better future!.

You know the Drill. Join.Read.Grow!

Human Electric Energy

Nerve impulses are electrical energy signals; and, they creates energy-fields around the body and electro-magnetic energy waves that can travel away from the body.

Nerve Impulses - Electricity in the Body

Human electricity energy is generated by chemical processes in nerve cells. Billions of nerve impulses travel throughout the human brain and nervous system. A nerve impulse is a wave of electrical activity that passes from one end of nerve cell to another. Each impulse is the same size it; it is the frequency, impulses per second, that carries information about the intensity of the nerve signal.
Neurons are the basic unit of the nervous system. Neurons are responsible for sending, receiving, and interpreting information from all parts of the body.

Nervous System - Human Electrical System

The nervous system is a network of cells called neurons which transmit information in the form of electrical signals. In the brain alone there are around 100 billion and there is a similar amount in the nervous system tissues throughout the rest of the body.

• Nerves for relaying information to and from the senses.
• Nerves for controlling the internal functions of the body.
• Nerves for muscle movement.
• Nerves for thinking.

Human Magnetism - Electro-magnetic Field

As electricity passes through a metal wire it causes an energy field or magnetic field. In a similar way, human electricity in the brain and nervous system creates human magnetic fields. There are billions of nerve impulses in the body and these are constantly creating complex human magnetic fields. The human heart is a source of electro-magnetism that, even at a few meters away, is detectable by modern scientific instruments.
BODY HEALING BY MAGNETIC FIELD ENERGY
The adult body is comprised of more than 70 trillion individual cells, and that’s not counting the millions of bacteria we carry in our gut. Each of those trillions of cells carries out several thousand metabolic processes every second. In order for that level of complexity to function smoothly, there must be a great deal of communication between and within these trillions of cells. Thankfully, our cells are programmed for this type of communication, and are able to make changes in a fraction of a second when necessary.Aging and disease are essentially results of a breakdown in cellular communication. The body does its best to rebalance itself and reestablish dwindling communication channels, but sometimes the process needs help. Therapeutic electromagnetic fields can provide this help by encouraging the body to restore basic cellular communication, allowing it to respond appropriately to its ever-changing environment It is important to acknowledge the intricate nature of cells and cellular communication, as it lays the foundation for understanding how and why PEMFs can so efficiently and safely help the body correct injury and imbalance. biomagnetics refers to the study of the body’s own magnetic fields. These fields are extremely weak and are only detectable with exquisitely sensitive equipment that blocks out all external magnetic fields, including the Earth’s magnetic fields. Once the connection is made between the magnetic aspects of the human body and the biophysical chemistry of the human body, it becomes easier to see the body as a dynamic, ever-changing bioelectric and biomagnetic organism, subject to all the physical laws of electromagnetism. The human body produces complex electrical activity in several different types of cells, including neurons, endocrine, and muscle cells – all called “excitable cells”. As all electricity does, this activity also creates a magnetic field. The biomagnetic fields of the body, though extremely tiny, have been measured with techniques including magnetoencephalography (MEG) and magnetocardiography (MCG). These techniques measure the magnetic fields produced by the electrical activity in the body. The findings through objective basic research of these endogenous fields serves to determine their magnitudes as well as leading to the development of new non-invasive means of measuring cellular function. This is clinically useful in order to help guide treatment of the brain and heart. The body’s electrical activity happens primarily in the cell membrane. The cell membrane is there both to protect the contents of the cell and to act as a sort of gatekeeper – opening and closing channels (like doorways) through which ions can flow. These channels are sometimes referred to as “pumps.”The cell membrane itself has a voltage called a “potential” (or membrane potential, or transmembrane potential). Membrane potential refers to the difference in electrical charge between the inside and outside of the cell. The channels in the membrane are opened or closed based on the polarity of the membrane. When the channels are closed, a cell membrane is at its “resting potential” and when it is open it is at its “action potential.”Action potential (channel opening) requires electrical activity. During this process, the electrical potential of the membrane rapidly rises, allowing the channels to open up. As the channels open, ions flow into the cell, causing a further rise in the membrane potential, prompting even more channels to open up. This process produces an electric current (and therefore magnetic field) across the cell membrane, and the cycle continues. Once all channels are open, the membrane potential is so great that the polarity of the membrane reverses, and then the channels begin to close. As the entry channels close, exit channels are activated. Once the process is complete, all channels close and the membrane returns to its resting potential.Only certain ions flow in and out of a cell this way. Most commonly these are sodium, calcium, and potassium. The primary type of action potential is often referred to as the “sodium-potassium pump”, during which sodium flows into the cell via an entry channel and potassium flows out of a cell via an exit channel.Action potentials play different roles depending on cell type, but are generally responsible for cellular communication or to activate a cellular process. Muscle cells, for example, use action potentials as the first step to achieving muscle contraction.If a cell is injured or otherwise not well, this activity slows or stops. The energy required by action potentials is relatively small but can be insurmountable for a sick cell. Applying an external, therapeutic magnetic field to the body supports this function by providing the cell with the energy it is incapable of producing itself.

Magnetic Induction- Energy Transfer

The image on the right shows an input electric current producing a magnetic field around one wire; this field passes through another wire and creates an output electric current. In physical science, this is called magnetic induction. Similarly, to magnetic induction in metal wires, the human electromagnetic field can be felt, or can influence, other people who are standing by. From your experience, do some people create a feeling within you when you are close by?

• When close to some people, you may feel as if your body and mind becomes more energized, more hopeful and optimistic.
• When close to other people, you may feel as if your energy drains away, a depressing or lazy feeling.

Electricity Waves - Energy Travel over a Long Distance

Electric force can transform into different types of energy waves, such as heat, radiation, radio and micro waves; and these energy waves can travel a long distance. A changing magnetic field will induce a changing electric field and vice-versa, the two are linked. These changing fields form electromagnetic waves. Electromagnetic waves can travel not only through air and solid materials, but also through space. The human nervous system can create electric energy waves that can be measured with scientific instruments. The human body produces infra-red radiation that, with night vision equipment, can be seen from miles away.

Can humans sense magnetic fields?

The current consensus is that humans cannot sense magnetic fields. Birds can do it, as can bats, turtles, ants, mole rats, sharks, rays, and more. Recently, Czech scientists have suggested that foxes, cows and deer also have the same ability. But look at all the recent reviews in this field, and you’ll see very little mention of our own species. A decade ago, a German group showed that our vision is slightly more sensitive in some directions than in others, but the results have not caught on.It wasn’t always like this. In the 1980s, Robin Baker from the University of Manchester carried out a series of experiments which seemed to show that humans could sense magnetic fields. He took busloads of blindfolded volunteers on winding journeys for several kilometres before asking them to point their way back home. They did so more often than expected, and if they wore magnets on their heads, their accuracy dropped.The results were published in Science and you can read Baker’s own description of his study in this 1980 issue of New Scientist. He even wrote a book about it. At the time, Baker said, “Whatever the repercussions, we have no alternative but to take seriously the possibility that Man has a magnetic sense of direction.”Unfortunately, the main repercussion was a fierce series of rebuttals. Over the next decade, several groups around the world failed to repeat Baker’s results, even though Baker himself had no problems in doing so. He argued that their failure could have been due to local magnetic anomalies or brief changes in the strength of the magnetic field due to solar activity.An American duo – Gould and Able – charitably suggested that Baker’s British students “either had cues available to them which were absent in our experiments, or are dramatically better than Americans in using whatever cues may be involved.” Max Westby and Karen Partridge, who failed to replicate Baker’s results in Sheffield, were less kind. “Perhaps it depends on which side of the Pennine Hills the experiments are conducted?” they asked. “It is obviously extremely difficult to counter all conceivable explanations for a negative result but we are forced to wonder about the ecological importance of a magnetic sense, the existence of which is so difficult to demonstrate.”In the end, Baker relented and he moved on to the science of sperm. When I talked to him about the new study, he confesses that he hasn’t kept up with the field. “I’d spent nearly a decade, tested thousands of people under all sorts of conditions, and had absolutely no doubt. Then people did a few tests here and there and claimed the experiments didn’t replicate,” he says. “Even after I’d collected everybody else’s results and published that taken together, they did in fact constitute successful replication, nobody wanted to know. There was an element of ‘Sod them, then’.”Reppert thinks that Baker’s story was an unfortunate one, especially since he stopped just when others were starting to discover light-based magnetic sensors. “I think Baker’s work was very good work but a lot of people had trouble reproducing aspects of it,” says Report. “It’s just very hard to do these sorts of behavioral experiments in humans.

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