All human beings are all tapped into the energies of Eternal Universal Life Force Energy whether or not they are fully aware of this fact. This is also known as the Universal Mind. There are times when we purposefully think out a solution to a problem. We ponder and ponder, then a thought comes to us as if out of nowhere. Sometimes we get the answers from our own brilliance and education. Other times we might be meditating or praying on a matter or a person, then get a wave of an idea that might help.
There are also times when thoughts come to us uninvited. They just suddenly appear. This happens, for the most part, when we are partly daydreaming or otherwise engaged in a project like taking a walk along a woodland path or some other activity that is not mentally taxing. All of a sudden, a revelation that we have not thought of before occurs to us.
At these moments, we become aware of the energies of thoughts that appear to have a life of their own. That is because they do. There is more to this concept than you may realize. Not only can we tap into thoughts which are seemingly beyond us, everyone also has a secret power. We have the ability to change things and their outcomes by simply observing them.
Holistic health therapists are trained in these unseen energies. You and I are part of a much bigger whole. In the energy classes I teach, I teach about the aura of each person, as well as the Earth. The radiation of Eternal Universal Life Force Energy within all life interacts and pulses with the consciousness of the more expansive THOUGHT energy.
Science has also noted these metaphysical anomalies. It occurs in physics, quantum mechanics, particle physics, electronics, thermodynamics, and quantum mechanics. They have even given a name for this, the observer effect. By the very act of observing something, we change its outcome.
Wikipedia is helpful at simplifying the reasons this happens:
“In physics, the observer effect is the disturbance of an observed system by the act of observation.[1][2] This is often the result of instruments that, by necessity, alter the state of what they measure in some manner. A common example is checking the pressure in an automobile tire; this is difficult to do without letting out some of the air, thus changing the pressure. Similarly, seeing non-luminous objects requires light hitting the object, and causing it to reflect that light. While the effects of observation are often negligible, the object still experiences a change. This effect can be found in many domains of physics, but can usually be reduced to insignificance by using different instruments or observation techniques.
“A notable example of the observer effect occurs in quantum mechanics, as demonstrated by the double-slit experiment. Physicists have found that observation of quantum phenomena can change the measured results of this experiment. Despite the “observer effect” in the double-slit experiment being caused by the presence of an electronic detector, the experiment’s results have been misinterpreted by some to suggest that a conscious mind can directly affect reality.[3] The need for the “observer” to be conscious is not supported by scientific research, and has been pointed out as a misconception rooted in a poor understanding of the quantum wave function ψ and the quantum measurement process.[4][5][6]
“Particle physics[edit]
“An electron is detected upon interaction with a photon; this interaction will inevitably alter the velocity and momentum of that electron. It is possible for other, less direct means of measurement to affect the electron. It is also necessary to distinguish clearly between the measured value of a quantity and the value resulting from the measurement process. In particular, a measurement of momentum is non-repeatable in short intervals of time. A formula (one-dimensional for simplicity) relating involved quantities, due to Niels Bohr (1928) is given by{\displaystyle |v’_{x}-v_{x}|\Delta p_{x}\approx \hbar /\Delta t,}
- Δpx is uncertainty in measured value of momentum,
- Δt is duration of measurement,
- vx is velocity of particle before measurement,
- v′x is velocity of particle after measurement,
- ħ is the reduced Planck constant.
The measured momentum of the electron is then related to vx, whereas its momentum after the measurement is related to v′x. This is a best-case scenario.[7]
“Electronics[edit]
“In electronics, ammeters and voltmeters are usually wired in series or parallel to the circuit, and so by their very presence affect the current or the voltage they are measuring by way of presenting an additional real or complex load to the circuit, thus changing the transfer function and behavior of the circuit itself. Even a more passive device such as a current clamp, which measures the wire current without coming into physical contact with the wire, affects the current through the circuit being measured because the inductance is mutual.
“Thermodynamics[edit]
“In thermodynamics, a standard mercury-in-glass thermometer must absorb or give up some thermal energy to record a temperature, and therefore changes the temperature of the body which it is measuring.
“Quantum mechanics[edit]
“Main article: Observer (quantum mechanics)
“The theoretical foundation of the concept of measurement in quantum mechanics is a contentious issue deeply connected to the many interpretations of quantum mechanics. A key focus point is that of wave function collapse, for which several popular interpretations assert that measurement causes a discontinuous change into an eigenstate of the operator associated with the quantity that was measured, a change which is not time-reversible.
“More explicitly, the superposition principle (ψ = Σnanψn) of quantum physics dictates that for a wave function ψ, a measurement will result in a state of the quantum system of one of the m possible eigenvalues fn , n = 1, 2, …, m, of the operator ∧F which in the space of the eigenfunctions ψn , n = 1, 2, …, m.”
Namaste