Scalar light is divine energy that is transferred from our solar system's Sun and the cosmos's stars and therefore pervades the limitless universe. Scalar light is a carrier wave that transmits the universe's instructions. The total amount of energy in the cosmos...is said to be constant, which means it cannot be created or destroyed; instead, it changes form.
In other words, everything in the universe is made of the same stuff-matter composed of atoms that are only different in their mass and number. All matter interacts with all other matter through gravity, but it also interacts with energy, especially light. The presence of electromagnetic radiation-including X-rays, ultraviolet, visible, and infrared-shows that energy is everywhere around us. Energy is never lost; it is only changed from one form to another. For example, when sunlight strikes an object, some of its energy is transformed into heat and light without any loss of energy. This shows that light is energy, and not particles like photons.
The physics behind all this was first explained by Albert Einstein in his famous equation E=mc2. It says that the energy E of an object of mass m is equal to the product of its speed v and its charge q (in units of electric potential). Because light has energy and is made up of particles called photons, this means that it should carry an electric charge!
The basic energy of the cosmos is scalar energy. It is energy that originates from the "Zero-Point Energy Field," which Albert Einstein named to define the field of energy that underpins everything in the cosmos, or the "Matrix," which Max Planck coined. The term "zero-point energy" refers to energy that has no frequency. All matter and energy have a frequency - some higher than others - that defines how many times it vibrates per second. Zero-point energy doesn't have a frequency because it's vibration is constantly changing direction, just like sound waves at zero pitch.
All forms of energy are said to be either wave-like or particle-like in nature. Wave-like energy travels in bands or waves. Particle-like energy exists in single units and cannot be divided. Light, for example, is a form of wave-like energy. It has frequencies that can reach us from distant places due to its ability to travel through space.
Energy cannot be created or destroyed, but it can be transformed from one form to another. For example, when light hits an object, some of this energy is absorbed by the object and converted into heat. Some of the light is reflected back into space. This is known as "reflective loss." All reflective surfaces lose some of their energy because they can only absorb certain frequencies of light. Any remaining light of a given frequency will be reflected back towards its source.
Scalar energy is made up of energy circles that radiate outwards in a balanced network. It generates a living field of energy systems. Nikola Tesla intended to employ scalar energy as a wave carrier in telecommunications, such as radio. He called this form of energy "cosmic electricity."
In physics, scalar energy is the name given to the irrotational component of an electric field. In other words, it is the part of the electric field that does not change direction when viewed from any point within its range. Thus, all parts of a charged particle's orbit will experience equal and opposite forces, and no net force will be experienced by any point within the particle's orbit. The term applies only to electromagnetic fields, which are represented by vectors; rotational components of these fields are vectorial too. Vectorial and scalar energies cannot co-exist in the same region because they represent opposing forces that would cancel each other out.
In classical mechanics, scalar potential energy is the portion of the total energy of a physical system that is stored in the position coordinates of all its particles. Quantum mechanically, however, there is no such thing as a coordinate system or location where a particle can be said to have a definite position without contradiction with other properties of that particle.
Scalar waves are longitudinal waves, which are made up of two identical electromagnetic waves of the same frequency that are orthogonal to each other. When two frequencies from different directions come into contact, they cancel each other out. Scalars do not propagate along their length; instead, they vibrate in place.
A scalar wave can be either compression or tension waves. In compression waves, the particles of an object move away from each other; in tension waves, they move towards each other. For example, consider a drumhead. When you beat it with a stick, it makes noise because its molecules move back and forth, creating compression waves. If you play a note on the drumhead's surface, those molecules stay put while another group overcomes the force of gravity and moves down toward the stick's tip. This motion creates a tension wave, which is why there is sound even though you aren't moving the drumstick around.
You can think of a scalar wave as a single vibration. As it travels through space, it spreads out due to things like air resistance and diffraction. But it never goes anywhere, so it doesn't matter where you are when you hear this wave - it will always reach you at the same time. This is why physicists say that light is a scalar particle - it can travel great distances without losing intensity (color) or direction (polarization).
Light is neither a scalar nor a vector quantity. Light is a natural occurrence. However, among the many attributes of light, we have its speed and velocity. Speed is a scalar number indicated by the letter c, whereas velocity is a vector quantity with intensity (c = 300 000 km/s) and direction. Although light is not measurable as a vector or scalar quantity, it can be described as such.
According to this hypothesis, the scalar wave travels at (7/4.7 =) 1.5 times the speed of light! This value is very close to that predicted by Einstein's theory for a medium with no mass or energy.
Scalar waves are not visible to human eyes, so they could exist without affecting our daily lives in any way. However, it has been suggested that they may have been detected by looking for changes over time in the polarization of light from distant stars. If such detection methods can be made sensitive enough, this might be a way to look for evidence of exotic matter.
The reason why we don't see scalar waves is because they interact with ordinary matter too much. The only kind of matter that wouldn't interact with them are neutral particles - but there aren't many of those in existence! A neutrino, for example, would pass right through scalar waves without even noticing they were there.
It's also possible that some large objects such as planets or stars emit or reflect scalar waves, but we just haven't seen them because they're bouncing off all the matter around us. It's an interesting idea that needs further investigation.