How are Energy and Matter the Same? - Universe Today
As Einstein showed us, light and matter and just aspects of the same thing. So in a way, energy, matter, space and time are all aspects of the same thing. . Frozen light is the inverse analogy in the relationship and equally. Matter and energy are core concepts throughout science curricula in high .. Of the 10 textbooks we surveyed, 8 defined energy, and all of them and two (one biology, one chemistry) described energy in relation to the. It is fair to say that many people are unfamiliar with the separation of the categories: Which is, distinguishing CAUSE (matter) and EFFECT.
Solid matter can store energy and remain stationary and stable with regard to axial position if it is rotating. Matter is literally an energy force field or structured energy. The idea of thinking in terms of structured energy is difficult since we tend to perceive energy or force as nothing but a cause and can only be measured by its effect on matter. Due to the difficulty imagining energy as a massless effect; I tend to imagine air, water or objects with mass such as a straw or balloon.
Since every part of the this dimension is filled with energy, we exist in an ocean of energy.
Science would have us believe that space is void. But space is only void of concentrations of structured energy that we know as matter. From the standpoint of energy, or magnetic and gravitational force space is full. The planets, stars, black holes, and quasars all follow rules of motion. Forces act on forces and forces acting on stars and planets can hardly be considered void or nothingness. In fact everything affects everything to some extent. Since energy is a difficult concept let us suppose that the universe is filled with water.
For example, imagine a small eddy in water.
Quarked! . How are matter and energy related?
The eddy currents have a hollow center and could not resist the flow of air through it but from any side it would have properties of mass. With regard to energy, only a single Axis of rotational structure would have length and width. So we can say that an energy eddy with a single axis y of rotation acceleration would only have two dimensional resistance to a lineal energy or force.
If a photon were an energy eddy with a single axis of rotation, it would have properties of matter and energy. It would have a single axis of rotation; therefore having direction and frequency or wave form.
How are Energy and Matter the Same?
It would be effected by magnetism and gravity. It could be created by electrons tumbling and interacting in a concentrated magnetic field. The photon would vary with the diameter of the rotation. The cause and effect of the fields that create it would determine its diameter or frequency. If one imagines the rotating field or energy eddy on a plane the rotation would cause motion.
It would have direction and frequency. Think of a tire rolling down a hill. It has both physical and wave properties.
Is light a wave or matter? The answer is yes.
Because a photon is the most basic component of structured energy. During creation of this time space dimension it would be the first thing created. I know they say that a photon has no mass, but they used to say that about electrons also. Photon mass is let us say a property that allows it to be affected by gravity and magnetism. Dual Axis of rotation would have three dimensions length, width and height.
- THE RELATIONSHIP OF MATTER AND ENERGY AND THE APPLICATION TO THE FIRST CAUSE
- What is the relationship between matter and energy?
- What is the relationship between Matter and Energy?
If the object spins fast enough it would take on the properties of a solid spherical object. A two dimensional accelerating object is a model for the electron. The smallest stable mass. A rotational couple is formed when two directions of rotation are joined. We have both mass and stable wave form. The field or structure is fixed. It is the smallest fixed particle of mass. I know that somebody will say what about the quark. But the quark is not a fixed and independent structure.
Each polar region has a concentrated field that effect the electron microscope in a way that indicates structure. Proton How may directions can an object be rotated or accelerated at the same time? Imagine this sphere rotating X and Y axis now spin it on the Z axis or third dimensional axis.
If an element is in motion, a difference is generated between the initial energy value resting energy and the energy value it possesses while the body is in motion. Also, given Einstein's relativistic theory, a variation in the mass of the body is also generated: The mass of the body at rest, is also called intrinsic or invariant mass, since it does not change its value, even under extreme conditions.
Matter is the material substance that constitutes the whole of the observable universe, and together with energy, both elements constitute the basis of all physical phenomena. The relationship between matter and energy expressed in Einstein's theory of relativity, laid the foundations of modern physics in the early twentieth century. References De la Villa, D. Matter and energy relationship. The Einstein equation Rather, we detail common themes concerning student conceptions of energy and matter that emerged from our broad reading of the literature.
Some interview questions were adopted from a study designed to expose biology students' alternative conceptions about energy and matter Hartley et al. We recorded and transcribed the interviews, and then each author independently read the transcripts to look for themes common among the faculty-member answers, with particular attention paid to commonalities and differences in the discourse used by the faculty members of various disciplines.
We then discussed the themes that emerged from our readings of the transcripts, reconciled our interpretations, and returned to the transcripts to ensure that all of the data were consistent with these themes. Although this limited set of interviews cannot represent all physical-science faculty members, it did uncover several differences in how science faculty members teach about energy and matter at the introductory level. Our findings are divided into three sections: Definitions and presentations of energy and matter in introductory physics, chemistry, and biology textbooks The textbooks' treatments of matter differed markedly from those of energy.
Of the 10 textbooks we surveyed, 8 defined energy, and all of them included energy in the index.