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If time is the forth dimension.

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How many other dimensions are there and what are they called

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  1. i would say time was the fourth dimension.


  2. There can be an infinite amount of other dimensions, we just can't perceive them all. We have 3 spatial dimensions and the 4th component, time. I prefer not to call it a dimension, because it can sound misleading. Time is just something that's tied to the 3 spatial dimensions, but it's not a real 4th dimension.

    In a 4-dimensional space, time would be the 5th "dimension"; in a 5-dimensional space, time would be the 6th "dimension", etc.

    As for what all those dimensions are called, scientist use letters of the alphabet, such as x, y and z. The 4th spatial dimension is usually marked by letter w (I think the trend here is to go backwards from the last letter of the alphabet).

    x is the horisontal dimension, y is the vertical dimension, z is depth

    w is the 4th dimension, so I suspect the 5th dimension would be v, the 6th would be u, and so on.

  3. Time is often referred to as the "fourth dimension". It is one way to measure physical change. It is perceived differently from the three spatial dimensions in that there is only one of it, that movement in time occurs at the fixed rate of one second per second, and that we cannot move freely in time but subjectively move in one direction.

    Theories such as string theory and M-theory predict that physical space in general has in fact 10 and 11 dimensions, respectively. The extra dimensions are space-like. We perceive only three spatial dimensions, and no physical experiments have confirmed the reality of additional dimensions. A possible explanation that has been suggested is that space is as it were "curled up" in the extra dimensions on a very small, subatomic scale, possibly at the quark/string level of scale or below.


  4. Depends on what theory, or version of a theory, you're talking about.

    Newtonian mechanics has three spacial dimensions (x,y,z) with time (t) as a separate entity: relativity has four dimensions (x,y,z,t) with time being rolled in with space to form spacetime: flat space string theories have 26-dimensions in the bosonic case (from the Polyakov equation), while superstring and M-theories currently use 10 or 11 spacial dimensions for flat solutions. In pure mathematics vector (and other spaces) can have an infinite number of dimensions!

    It all varies depending on what entity you are trying to describe as well as where and when it happens.

  5. In terms of direct observation, we believe that our universe has four dimensions. Three of the dimensions are those of spatial directions such as (say) x, y, and z. Furthermore, within Einstein's Theory of General Relativity, time is the fourth dimension - so that space and time become space-time. This fourth dimension is then incorporated into calculations of the 'metric' or measure of a small element 'ds' of (here flat or Minkowski) space, in an equation of the type: -

    ds² = dx² + dy² + dz² - c²dt²

    Thus, in relativistic calculations time becomes a fourth dimension!

    However, many modern theories of space and time such as string theory require space and time to have more dimensions. Wikipedia comments,'...An intriguing feature of string theory is that it involves the prediction of extra dimensions. The number of dimensions is not fixed by any consistency criterion, but flat spacetime solutions do exist in the so-called "critical dimension." Cosmological solutions exist in a wider variety of dimensionalities, and these different dimensions—more precisely different values of the "effective central charge," a count of degrees of freedom which reduces to dimensionality in weakly curved regimes—are related by dynamical transitions.

    Nothing in Maxwell's theory of electromagnetism or Einstein's theory of relativity makes this kind of prediction; these theories require physicists to insert the number of dimensions "by hand," and this number is fixed and independent of potential energy. String theory allows one to relate the number of dimensions to scalar potential energy. Technically, this happens because a gauge anomaly exists for every separate number of predicted dimensions, and the gauge anomaly can be counteracted by including nontrivial potential energy into equations to solve motion. Furthermore, the absence of potential energy in the "critical dimension" explains why flat spacetime solutions are possible.

    This can be better understood by noting that a photon included in a consistent theory (technically, a particle carrying a force related to an unbroken gauge symmetry) must be massless. The mass of the photon which is predicted by string theory depends on the energy of the string mode which represents the photon. This energy includes a contribution from the Casimir effect, namely from quantum fluctuations in the string. The size of this contribution depends on the number of dimensions since for a larger number of dimensions, there are more possible fluctuations in the string position. Therefore, the photon in flat spacetime will be massless—and the theory consistent—only for a particular number of dimensions.

    When the calculation is done, the critical dimensionality is not four as one may expect (three axes of space and one of time). Flat space string theories are 26-dimensional in the bosonic case, while superstring and M-theories turn out to involve 10 or 11 dimensions for flat solutions. In bosonic string theories, the 26 dimensions come from the Polyakov equation. Starting from any dimension greater than four, it is necessary to consider how these are reduced to four dimensional space-time.

    Two different ways have been proposed to resolve this apparent contradiction. The first is to compactify the extra dimensions; i.e., the 6 or 7 extra dimensions are so small as to be undetectable by present day experiments.

    To retain a high degree of supersymmetry, these compactification spaces must be very special, as reflected in their holonomy. A 6-dimensional manifold must have SU(3) structure, a particular case (torsionless) of this being SU(3) holonomy, making it a Calabi-Yau space, and a 7-dimensional manifold must have G2 structure, with G2 holonomy again being a specific, simple, case. Such spaces have been studied in attempts to relate string theory to the 4-dimensional Standard Model, in part due to the computational simplicity afforded by the assumption of supersymmetry. More recently, progress has been made constructing more realistic compactifications without the degree of symmetry of Calabi-Yau or G2 manifolds.

    A standard analogy for this is to consider multidimensional space as a garden hose. If the hose is viewed from a sufficient distance, it appears to have only one dimension, its length. Indeed, think of a ball just small enough to enter the hose. Throwing such a ball inside the hose, the ball would move more or less in one dimension; in any experiment we make by throwing such balls in the hose, the only important movement will be one-dimensional, that is, along the hose. However, as one approaches the hose, one discovers that it contains a second dimension, its circumference. Thus, an ant crawling inside it would move in two dimensions (and a fly flying in it would move in three dimensions). This "extra dimension" is only visible within a relatively close range to the hose, or if one "throws in" small enough objects. Similarly, the extra compact dimensions are only "visible" at extremely small distances, or by experimenting with particles with extremely small wavelengths (of the order of the compact dimension's radius), which in quantum mechanics means very high energies.'


  6. There are three conventional spatial dimensions: length (or depth), width, and height, often expressed as x, y and z. If time is considered as the "fourth dimension", the additional fourth spatial dimension would be referred to as the fifth dimension.

  7. Other dimensions are space dimensions. They are x,y,z


  8. Yes it is.

    The first three are the x,y and z cartesian planes.

    The next 7 have no names as far as I'm aware but are curled up so tightly that our brains cannot comprehend them  

  9. In a relationship RSTUVWXYZ there are nine dimensions.  Time is the fourth dimension in a standard space-time coordinate system.  The other three could be called length, height and depth (X,Y and Z).  No other dimensions are needed to solve problems in this particular reference system.  

  10. space is fith dimension

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