Who Needs Dark Matter? An Alternative Explanation for the Galactic Rotation Anomaly

The galactic rotation anomaly, whereby there is a flattening of the rotational velocity curve with radius, was the prime driver for development of the theory of ‘Dark Matter” by Jan Oort and Fred Zwicky in the 1930s, reinforced by Vera Rubin over 30 years later based on more observations of galactic rotation.

She concluded that the mass densities of galaxies were uniform well beyond the galactic bulge, requiring that some form of ‘invisible’ matter be present to account for the rotational anomaly on a purely gravitational basis.

Borrowing concepts from the Electric/Plasma Universe theories, I examine a possible explanation of at least part of this observed behavior for spiral galaxies by considering an idealized case where the combined magnetic fields from the galactic core and spiral arms  exhibit a trend toward the ‘flatness’ in these rotation curves as one proceeds outward radially from the galactic core to its edge.  In the process, I provide at least an introduction to some of these other alternative explanations for the galactic rotation anomaly.

Who Needs Dark Matter?  An Alternative Explanation for the Galactic Rotation Anomaly

 Raymond HV Gallucci, PhD, PE, 8956 Amelung St., Frederick, Maryland, 21704, e-mails: [email protected], [email protected]

Borrowing concepts from the Electric/Plasma Universe theories [1], I examine a possible explanation of at least part of the observed behavior for the galactic rotation anomaly for spiral galaxies by considering an idealized case where the combined magnetic fields from the galactic core (assumed to be a rotating charged sphere) and spiral arms (assumed to be a rotating charged disk exhibit a trend toward the ‘flatness’ in these rotation curves as one proceeds outward radially from the galactic core to its edge.  This hopefully is a plausible addition to the various alternate explanations for this anomaly that do not invoke the likely fiction of ‘dark matter,’ alleged to comprise roughly 85{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117} of the total matter in the universe (and, with the other likely fiction ‘dark energy,’ alleged to comprise roughly 95{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117} of the total mass-energy of the universe).  In the process, I provide at least an introduction to some of these other alternative explanations for the galactic rotation anomaly.

  1. Introduction

As discussed in “Dark matter” [2]:

“Dark matter was postulated by Jan Oort in 1932, … to account for the orbital velocities of stars in the Milky Way and by Fritz Zwicky in 1933 to account for evidence of ‘missing mass’ in the orbital velocities of galaxies in clusters.  Adequate evidence from galaxy rotation curves was discovered by Horace W. Babcock in 1939, but was not attributed to dark matter.  The first to postulate dark matter based upon robust evidence was Vera Rubin in the 1960s–1970s, using galaxy rotation curves. … Together with fellow staff-member Kent Ford, Rubin announced … that most stars in spiral galaxies orbit at roughly the same speed, which implied that the mass densities of the galaxies were uniform well beyond the regions containing most of the stars (the galactic bulge), a result independently found in 1978 … Eventually other astronomers began to corroborate her work and it soon became well-established that most galaxies were dominated by ‘dark matter’ … [B]y the 1980s most astrophysicists accepted its existence.”

FIGURE 1.  Rotational curves for a disk [3]

Since dark matter has not actually been observed or detected, but only inferred by circumstantial evidence, primarily due to the alleged anomaly in galactic rotation curves (see Figure 1), dissident physicists have offered other explanations for the relative flatness of the rotational velocity of galaxies with increasing radius.  That is, while the presumably densely packed galactic core (essentially a sphere of stars) rotates like a solid body (green, thick-dashed line in Figure 1), once into the disk region, galactic rotational speed flattens out, such that structures such as spiral arms continue to rotate as if ‘fixed’ like the spokes of a wheel (albeit ‘bent backward’ in a logarithmic spiral).

  1. Some Explanations without Dark Matter

Review of some of these ‘dissident’ websites uncovers alternate (to dark matter) explanations, both gravitationally- and electromagnetically-based, such as the following.

“This theory attributes the anomaly in galactic rotation to the effects of time dilation on Newtonian speeds when making observations from the Earth’s frame of reference … A spherical time rate field.  The spherical time rate field around any mass is similar to a gravity well … [F]or relatively short radii from the centre of any mass and even for those at solar system scales, we do not notice much physical effect from the time dilation diminishing with ‘r’ … We might then envisage that the relentless continuation of this time rate increase (time dilation decay), from the galactic centre outwards, will accumulate … and so become significant in terms of the red and blue shift of Newtonian rotation speeds … The only radial position that shows us a REAL, unshifted Newtonian rotation speed … is therefore at a radius similar to our own position in the Milky Way (for galaxies of similar mass and distribution) … So, we need to raise the calculated Newton curve so it crosses the observed curve at this position. We therefore deduce there is more mass at the centre, [and that] … all Newtonian speeds are redshifted and slowed down relative to our frame of reference, increasingly so, as you look closer toward the galactic centre.  The Newton curve inboard, therefore becomes increasingly lowered from the inverse square form as you move inwards and this brings the Newton curve down to match the observed.  Outboard, … all Newtonian speeds are blueshifted relative to our frame and so appear increasingly faster than Newton with increasing ‘r’ … Both these effects, inboard and outboard, result in a good ‘fit’ between time shifted Newtonian speeds and the observed curve of rotation speeds.” [4]

“Electric Universe theory asserts that there is a model of spiral galaxy formation that has long been demonstrated by laboratory experiment and ‘particle in cell’ (PIC) simulations on a supercomputer.  But, the particles are charged and respond to the laws of electromagnetism.  This seems … obvious … when … more than 99.9 percent of the visible universe is in the form of plasma … Plasma responds to electromagnetic forces that exceed the strength of gravity to the extent that gravity can usually be safely ignored.  This … suggests why gravitational models of galaxies must fail … [C]omputer simulations have been backed up by experiments in the highest energy density laboratory electrical discharges—the Z-pinch machine [that] … verify each stage in development of the PIC simulations … [T]he beautiful spiral structure of galaxies is a natural form of plasma instability in a universe energized by electrical power. [5]

Continuing with the Electric Universe arguments, “[o]ne of the reasons for the assumption of large amounts of Cryogenic (or Cold) Dark Matter (CDM) in the Gravity Model is to explain the observed rotation of galaxies … However, there is another way stars could be made to orbit a galaxy in this fashion.  Michael Faraday found … that a metal disk rotating in a magnetic field aligned with the axis of the disk would cause an electric current to flow radially in the disk … Galaxies are known … to possess magnetic fields aligned with their axes of rotation, and they also have conducting plasma among their stars.  Assuming that currents exist in the plane of the galaxy similar to the equatorial current sheet known to exist in the Solar System, then the conditions appear to be similar to that in a Unipolar Inductor or Faraday Motor …  [I]t is at least possible that it is these electrical effects that are causing the anomalous rotation that we see, not some huge quantity of invisible Dark Matter.” [6]

One of the more unique explanations asserts that “the mutual [gravitational] perturbations among the component stars in a Spiral Arm can be shown to have far greater effects than previously noted.  The inverse-square nature of gravitation causes the effect to be very strong at the relatively short distances within a Spiral Arm … One interesting consequence of this research is the realization that the Sun and all other stars slowly weave back and forth across the Spiral Arm! … The analysis … [suggests that]: {1} A general tapering shape of an Arm is necessary to produce the effect described here. This suggests a reason for the common existence of spiral arms in galaxies. {2} A tapered Arm shape is a necessary resultant consequence of the meta-stable situation described here. These two statements suggest a mechanism for the genesis and persistence of spiral arms in many galaxies. {3} [T]he Sun and everything else in each Arm apparently laterally oscillate across the width of the Arm … [W]ithin the Spiral Arms, a substantial previously undescribed conventional gravitational net force vector [coupled with] … [t]he tapering shape of a Spiral Arm … results in a meta-stable situation that establishes the stability and persistence of the Spiral Arm, including the circumstance where the Arm revolves in the observed non-Keplerian way … [A]s long as the Arm tapers as it extends outward, there is significant force active on each constituent star to pull it along and also toward the axis of the Arm … This therefore explains the lasting integrity of the Arm structure, and also suggests a much less massive galaxy.  It may remove the need for dark matter, exotic particles, materials, or objects to account for a lot of unseen distributed mass in the Galaxy.  The question of Missing Mass as to explaining the rotation of the Galaxy is no longer necessary or appropriate.” [7]

As can be seen, both gravitational (first and last) and electromagnetic (second and third) alternative explanations to dark matter as being responsible for anomalous galactic rotation have been proffered.  While my hypothesis will align mainly with the electromagnetic explanation, I draw significantly from aspects of that developed by Johnson, albeit not its gravitational effects.  The interested reader is directed to Johnson’s website for the details of the simulations he performed to substantiate his hypothesis, too intricate and lengthy to be reproduced here.

  1. Another Possible Explanation

My analysis begins with mathematically constructing a representative spiral galaxy, whose spherical, central core has a radius Rs = 1 and whose three, logarithmically spiraling, equi-spaced arms extend out from the core through the disk to radius Rd = 5 (Figure 2).  (Logarithmic spirals, with an equation r = exp[aθ] in polar coordinates, reasonably approximate the arms of spiral galaxies, including our own Milky Way. [8])

Photographs indicate the number of spirals in galaxies which are reasonably symmetric range from the minimum of two to around five.  Three are postulated for my representative analysis.)  The arms are shown as uniformly tapering, from a maximum width where they meet the core (black circle) of π/3 down to zero such that, if unwound and straightened spokes, each would comprise a triangle of base π/3 and height 16.12 (based on logarithmic spirals with the equation r = exp[θ/{2π/ln 5}] for three equally-spaced spirals).

FIGURE 2.  Representative Three-Armed, Logarithmic Spiral Galaxy

3.1  Magnetic Effects

The equation for the component of the magnetic field B aligned with the axis of galactic rotation in the disk of the galaxy (ecliptic) outside a rotating charged sphere (the galactic core) at radius r is as follows [9]:

Bs(r) = μ0QsωRs2/12πr3                                                                                                                                                              [1]

where Qs = total charge on the sphere (galactic core) and ω = rotational speed of the sphere (galaxy).

For the disk, the B field always aligns with the axis of rotation and has the following magnitude for a disk of radius r within the plane of the disk itself (also assumed to be rotating at ω) [10]:

Bd(r) = μ0σωr/2                                                                                                                                                                          [2]

where σ = charge density = q(r)/(π[r2 – Rs2]) for Rs < r < Rd and q(r) = total charge on disk from Rs through r (at Rd, q[r] = Qd, the total charge of the disk).

Assume q(r) = k(r)Qs, where k(r) = fraction of charge in disk relative to Qs (for convenience, assume the disk charge Qs cannot exceed that of the sphere, i.e., 0 < k(r) < 1).  Within the plane of the disk itself,

B(r) = (μ0ω/2π)(k[r]Qsr/[r2 – Rs2])                                                                                                                                             [3]

Combining Equations [1] and [3] yields

B(r) = (μ0ωQs/2π)(Rs2/6r3 + k[r]r/[r2 – Rs2])                                                                                                                              [4]

With Qs = 1 and Rs = 1 (such that all further calculations will be scaled to the sphere’s charge and density), this simplifies to

B(r) = (μ0ω/2π)(1/6r3 + k[r]r/[r2 – 1])                                                                                                                                        [5]

where Rs < r < Rd, i.e., 1 < r < 5.

For subsequent analysis, define the following scaled value for the B field

B’(r) = B(r)/(μ0ω/2π) = 1/6r3 + k[r]r/[r2 – 1]                                                                                                                             [6]

It is evident that, as one proceeds outward radially along the disk, the contribution from the sphere drops off as r3 while that from the portion of the disk between the sphere and r only as 1/r, given the previous constraint on k(r).

When speaking of the ‘disk,’ I recognize that we really have three spiral arms lying within the galaxy’s ecliptic.  I will view this as if the charge (and mass, both of which I assume are directly proportional to each other) was uniformly distributed in the annulus between the sphere and radius r of the disk as one proceeds outward to Rd = 5.  Thus, k(r) will increase from 0 at the sphere (r = Rs = 1, where the disk begins) to its maximum value of Qd/Qs < 1 at Rd = 5.  How k(r) increases with r depends on the shape of the spiral arms.  Figure 2 shows them as tapering.  Another possibility is a uniform cross-section, i.e., no tapering (we will not consider the possibility of them widening as r increases as this is not evident from galactic photographs).  Figure 3 shows this variation for the two ‘extremes.’

FIGURE 3.  Variation in Disk Charge Fraction Based on Spiral Arm Tapering

3.1  Gravitational Effects

What about gravitational effects?  Assuming the mass of the sphere (galactic core) = Ms (also assumed directly proportional to Qs), the gravitational field G(r) solely from the sphere as a function of r is

G(r) = ΓMs/r2, Rd < r (using Γ as the symbol for the gravitational constant).                                                                           [7]

For the disk, based on similarity for the gravitational force inside a solid sphere of uniform density at radius r [11], assume that the gravitational force from the galactic disk at r arises solely from that portion of the disk < r.[1]  Since the mass of the disk < r is proportional to r2h, where ‘h’ is the thickness of the disk, and the gravity at r is proportional to 1/r2, when combined the dependence on r disappears, implying that the gravity throughout the disk (from the disk only) is constant.  With the mass of the disk = Md, the gravitational force from the disk will be a constant, ΓMs/Rd2. Therefore, we can modify Equation [7] as follows:

G(r) = Γ(Ms/r2 + Md/Rd2), where Rs < r < Rd, i.e., 1 < r < 5.                                                                                                     [8]

Analogous to setting Qs = 1, we now set Ms = 1 (such that all further calculations will be scaled to the sphere’s mass), thereby simplifying this to

G(r) = Γ(1/r2 + Md/Rd2)                                                                                                                                                             [9]

For subsequent analysis, define the following scaled value for the G field

G’(r) = G(r)/Γ = 1/r2 + Md/Rd2                                                                                                                                                 [10]

It is evident that, as one proceeds outward radially along the disk, the contribution drops off primarily as r2, since the first term, the gravitational force from the sphere, dominates the second, constant term, the gravitational force from the disk within r, until r approaches Rd, so long as Md < Ms.

  1. Results

What we have shown so far is that the expected variation as one proceeds radially outward from the sphere along the disk for the B’ field should be somewhat flatter (due to the 1/r variation becoming dominant over the 1/r3 variation) than that for the G’ field, with its primarily 1/r2 variation.  Note that we are not comparing the relationship between the absolute strengths of the two types of field, magnetic vs. gravitational (the former is known to be much stronger), but only their variation relative to their maximum values (at the sphere).  The results of the comparison are shown in Figure 4 for both the tapering and non-tapering spiral arms, and indicate the expected trend toward ‘flattening’ of the B’ field vs. the G’ field. (Just to be clear, Figure 4 does not represent any relative strengths among the three charge [Q] ratios for the B’ field, the three mass [M] ratios for the G’ field, or between the two sets [B’ and G’].  Each specific case has been scaled to its maximum value [at the sphere] such that all curves have a value of 1.0 at Rs. [or just infinitesimally farther out in the case of the B’ fields since their maximum does not occur until at least an infinitesimal bit of the disk is included].  While one can readily surmise that the B’ field increases with charge ratio, and the G’ field increases with mass ratio, their strengths relative to each other are not represented in the Figure.  The Figure solely illustrates the trend in each individual field’s strength as one proceeds radially outward from the sphere along the disk solely for the purpose of illustrating the degree of ‘flattening’ in each particular case.  This caveat holds for Figures 5 and 6 as well.)

Comparing this with Figure 1, and assuming rotational velocity is reasonably proportional to field strength, one sees behavior closer to that of the flat or galactic curves for the B’ field than for the G’ field, at least beyond a radius of ~2.  This is especially pronounced when the spiral arms are assumed not to taper.  The average between the taper and no taper behavior is displayed in Figure 5 for an easier view, further illustrating the trend.

  1. Conclusion

Hopefully I have at least made a plausible argument for one possible explanation for the galactic rotation anomaly, at least as one proceeds radially outward from the galactic core, for an idealized spiral galaxy to add to the lexicon of other such arguments that do not invoke the likely fiction of ‘dark matter’ (and its sibling ‘dark energy’).  Borrowing from the Electric/Plasma Universe theories, which assert that the much greater strength of the electromagnetism vs. gravity may explain much of the observed behavior of the universe, I attempt to show mathematically that magnetic forces could account for at least some of the supposedly anomalous ‘flattening’ observed in rotational speed of a galaxy as one proceeds radially outward.  It is by no means a rigorous treatment of the subject, but hopefully at least demonstrates that such an explanation merits further investigation.

  1. References
  1. http://www.electricuniverse.info,www.plasma-universe.com
  2. http://en.wikipedia.org/wiki/Dark_Matter
  3. http://upload.wikimedia.org/wikipedia/commons/d/dc/jpg
  4. http://www.thenakedscientists.com/forum/index.php?topic=39624.0 (Ken Hughes).
  5. http://www.holoscience.com/wp/electric-galaxies/ (Wallace Thornhill).
  6. https://www.thunderbolts.info/wp/2012/02/29/essential-guide-to-the-eu-chapter-10/ (David Talbott).
  7. http://mb-soft.com/public/galaxyzz.html (Carl Johnson).
  8. http://en.wikipedia.org/wiki/Logarithmic_spiral
  9. Vagner, et al., Electrodynamics of Magnetoactive Media, Springer Series in Solid State Sciences, ISSN 0171-1873; 135 (2004)
  10. http://physicspages.com/2013/04/17/magnetic-fields-of-spinning-disk-and-sphere/
  11. Wilhelm, “Gravitational Force on a Point-Mass M inside a Solid Sphere or Solid Shell, with Uniform Mass Distribution,” 2005 (http://www.heisingart.com/dvc/ch{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}2013{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20Gravitational{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20force{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20on{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20a{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20point{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20inside{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20a{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20spherical{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}20shell.pdf).
  12. http://en.wikipedia.org/wiki/Globular_cluster

FIGURE 4.  Comparison between B’ and G’ Field (Scaled) Variation with Radius

FIGURE 5.  Scaled Average between Taper and No Taper for B’ and G’ Fields

Appendix:  Possible Effect from a Globular Cluster Halo

As discussed in “Globular cluster” [12]:

“A globular cluster is a spherical collection of stars that orbits a galactic core as a satellite.  Globular clusters are very tightly bound by gravity, which gives them their spherical shapes and relatively high stellar densities toward their centers … Globular clusters are fairly common; there are about 150 to 158 currently known globular clusters in the Milky Way, with perhaps 10 to 20 more still undiscovered  Large galaxies can have more: … Some giant elliptical galaxies … have as many as 13,000 globular clusters … Globular clusters are generally composed of hundreds of thousands of low-metal, old stars, … similar to those in the bulge of a spiral galaxy but confined to a volume of only a few million cubic parsecs … Globular clusters can contain a high density of stars … Some globular clusters … are extraordinarily massive, with several million solar masses and multiple stellar populations.”

To gauge the possible contribution from any magnetic field generated by a halo of globular clusters surrounding my representative spiral galaxy, I assume there is such a halo at a distance of 5Rd/2 (i.e., r = 25/2), rotating with the galaxy at the same rotational speed ω as the disk so as to form a spherical shell of charge in which the galaxy resides.  (This very crude approximation is based loosely on the estimated radius of the Milky Way galaxy [~50,000-60,000 light-years] and the estimate that its halo of globular clusters is located at a radius of ~131,000 light years.)  From Vagner [9], the B field inside such a sphere within the ecliptic plane is

Bh = μ0Qhω/6πr                                                                                                                                                                        [11]

where Qh = charge on the spherical shell i.e., the total charge of the halo).

As before, we can define Bh’ = Bh/(μ0ω/2π) = Qh/3r                                                                                                                       [12]

Considering the same range on Qh as for Qd (i.e., from Qs/3 to Qs), and setting Qs = 1 and r = 5Rd/2 = 25/2, we obtain

Bh’ = 2f/75, where 1/3 < f < 1.                                                                                                                                                [13]

When this is added to the combined B field from the rotating sphere and disk, the total B field rises as much as ~8{154653b9ea5f83bbbf00f55de12e21cba2da5b4b158a426ee0e27ae0c1b44117}, as shown in Figure 6 (plotted against the scaled averages as in Figure 5 for convenience of viewing).

FIGURE 6.  Scaled Average B’ Fields between Taper and No Taper (with Halo of Globular Clusters)

[1]      As shown there, gravitational force rises linearly from zero at the center of the solid sphere to its maximum value at the sphere’s surface.  This follows readily from gravity arising only from the portion of the sphere < r, for which the enclosed mass is proportional to the cube of the radius, while the gravitational force at r is proportional to the inverse square of the radius.  Combined, these yield a linear dependence of gravity with r.

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Comments (6)

    • Avatar

      Ray Gallucci

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      While I am not a proponent of black holes or relativistic effects such as time dilation, if one accepts these concepts, your gravispheres theory certainly is one among several plausible ones to explain the galactic rotation anomaly without the fiction of dark matter. In a way, it bears resemblance to Ken Hughes’ theory of relativistic effects creating what we perceive here on Earth as the galactic rotation anomaly. If I follow, you postulate that the decrease in the gravitational constant with radius is responsible for the same perceived anomaly. Would your theory work with the Electric Universe concept of “black holes” really being very dense plasmoids?

      Reply

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    Ken Hughes

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    I see you have absorbed the contents of my YouTube video – https://youtu.be/jLe6llQSVks and used many of the terms ideas I have invented to describe my postulate almost verbatum. That is all well and good, and indeed you do explain the proposal clearly and accurately and I m grateful for that. However, I do expect for a another presenter of this idea to refer to its originator as a mark of professional courtesy and respect and would ask that you remedy this asap. I like your paper and the way it is presented and wish you well in your work,
    Thank you and regards,
    Ken Hughes

    Reply

  • Avatar

    Ray Gallucci

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    Ken – This is your reference as listed in the paper, including your name: “http://www.thenakedscientists.com/forum/index.php?topic=39624.0 (Ken Hughes).” Your material is shown in quotes, with the reference cited immediately afterward.. The references got misnumbered somehow when my original was converted into PSI format (they should begin with {1}, not [7]). Your work is indeed references as shown above (you are #4, misnumbered as #10, with your name included). The [4] is shown after the quotation, so I believe I have properly referenced you, as well as the others whom I quote. The other quoted references were also misnumbered (5, 6, 7 were misnumbered by PSI formatting as 11, 12, 13) – their names are listed there as well (Thornhill, Talbott, Johnson). Each is similar cited with a reference in { ] immediately after their quotations. PSI formatting also placed equation numbers beneath equations rather than to the far right as in the submitted manuscript, so that may have led to some confusion as well. You’ll find I reference you again in my next paper as well, using a similar citational method. I trust you find this acceptable.

    Reply

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    Ken Hughes

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    Hi Ray,
    Thank you for your response. Yes, indeed I was confused and looking closer I do find you have referenced me correctly. I thank you for that and apologise for any suggestion that you did not.
    Good luck, and thanks again.

    Ken

    Reply

    • Avatar

      RAYMOND GALLUCCI

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      Ken – Thanks for the note. I am glad the confusion was corrected, and I see John is now aware of the formatting problem and hopefully will be able to ensure it does not happen in the future. (PSI prefers submissions in Word rather than pdf, and Word has its own default automatic numbering style, which I sometimes have to override to prevent happening what apparently happened with the PSI article. Unfortunately, this default may have kicked back in when PSI re-formatted.) As I said, I have referenced you again in the very next article that should be published, again about the galactic rotation anomaly. I am happy you found this article and my referencing of your work, as it was a unique insight on your part that I thought merited recognition in my article.

      Ray

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