Hydrogen Variety 2 10 And 8anu

fig. 17

Deuterium. During observations on the electrolysis of water a very few examples of two Hydrogen atoms united in a temporary alliance were seen. These two atoms were of varieties 1 and 2 and placed themselves at right angles to each other as in Fig. 18. This group of two Hydrogen atoms would have double the weight of ordinary Hydrogen, as is required for Deuterium.

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The discovery of this very light gas of atomic weight 2 (H=I), was announced in The TheosophisU December 1932. The external shape of die atom is spherical and it consists of 36 Anu. Twelve of these are divided into four groups of H3, one of which is placed at each of the four corners of a tetrahedron. Interlaced with this tetrahedron is a second containing four groups of six Anu. Fig. 15. Here we meet two forms which occur very often. First the group of six Anu arranged in the shape of a ' cigar' or elongated hexagon or prism. This we distinguish as Ad6. This form revolves with extreme rapidity around its longitudinal axis, and looks like a pencil sharpened at both ends. It appears to be strongly coherent, for, as will be seen later, its six Anu remain attached to each other on the E3 level, and even when divided into triplets on the E2 level these revolve around each other.

In Adyarium four of these prisms are placed at the comers of a tetrahedron, thus forming the larger group which also occurs very often and which is distinguished as Ad 24.

It will be seen that the two groups of four bodies each form tetrahedrons, that is to say, their respective positions in space, as they individually revolve within the sphere-wall of the element, are those marked out by the eight corners of two interlaced tetrahedrons.

Adyarium is rare in the atmosphere at the earth's surface, but it exists in greater quantity in the stratosphere. Like Hydrogen, it is being slowly lost to our atmosphere by radiation during the earth's journey round the Sun. But the rays of light from the Sun are combining sub-elements all the time, and the lost elements are being replaced by the new creations.

As this element was first observed by clairvoyant magnification at Adyar, we have called it Adyarium.

Total = 36 Anu 36

Number weight = 2.00.

atomic no. ib OCCULTUM

Occultum was first observed in 1895 and, finding that it was so light and so simple in its composition, it was thought that it might be Helium, of which it was not possible at that time to obtain a sample. When, however. Helium itself came under observation in 1907, it proved to be quite different from the object previously observed, so the gas observed in 1895 was called Occultum, until orthodox science should find it.

This element consists of 54 Anu and contains groups from Hydrogen and Adyarium. It is ovoid in shape. Fig. 15.

We here meet the tetrahedron, Ad 24, as in Adyarium. Above the tetrahedron is a balloon-shaped figure. Oc9, apparently drawn into shape by the attraction of the tetrahedron. The body below the tetrahedron looks like a coil of rope, and contains fifteen Anu, Ocl5. They are arranged on a slanting disc in a flat ring and the force goes in at the top of one Anu, and out of the bottom of it into the top of the next, and so on. making a closed circuit. The two little spheres, each containing a triplet, are like fill-up paragraphs to a compositor—they seem to be kept standing and popped in where wanted.

The constituents of Occultum reappear in Gold and other elements.

Tetrahedron Balloon Triplets Ring

Total = 54 Anu 54

Number weight = 3.00

HYDROGEN

E2

E3

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/ voy V&/)

DISINTEGRATION OF HYDROGEN VARIETY 1

THE HYDROGEN GROUP HELIUM

Helium is different in configuration from the other inert gases. It is made up of the whole of Hydrogen and a good deal from Adyarium. It is ovoid in shape and not in the form of a six-pointed star as are the other inert gases, and it is therefore included in this preliminary group. Fig. 15 shows that the four elements in this group are closely related.

The two triangles of Hydrogen appear in Helium and two Ad 24 tetrahedrons. The tetrahedrons revolve round an egg-shaped central body consisting of two H3 spheres, and the triangles spin on their own axes while performing a similar revolution Helium is completely balanced, that is to say, it is seemingly self-sufficient; a positive tetrahedron of 4 Ad6 groups is counterbalanced by a similar tetrahedron which is negative. A positive half of Hydrogen is satisfied with a negative half and in the centre of all the two groups of 3 Ami, being positive and negative, satisfy each other.

The whole has an attractive airy appearance, as of a fairy element.

Centre = 6 Anu

2 Triangles =18

Total = 72 Anu

Number weight =rs = 4.00

THE DISINTEGRATION OF THE HYDROGEN GROUP

HYDROGEN

On the E4 level the six bodies contained in the gaseous atom instantaneously re-arrange themselves within two spheres; the two linear triplets unite with one triangular triplet, holding to each other relative positions which, if connected by three straight lines, would form a triangle with a triplet at each angle ; the remaining three triangular triplets similarly arrange themselves in the second sphere. These form the E4 compounds of Hydrogen.

In the dissociation of these to the E3 level, each sphere breaks up into two, the two linear triplets joining each other and setting free their triangular comrade. Two of the triangular triplets similarly remain together, casting out the third, so that Hydrogen yields four E3 compounds.

On the E2 level, the connexion between the double triplets is broken, and they become four independent groups, two remaining linear, but rearranging their internal relations; the two remaining groups are triplets.

The final dissociation sets all the Anu free. Figs. 16 and 19.

ADYARIUM OCCULTUM HELIUM

E2

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oo

E3

1

i

E4

\ • V / • \ • ' —1 • y

• \ • 1

Ad24

Ad 12

Oc15 + 2 H3

OC9

fig. 20. disintegration of adyarium. occultum and helium fig. 20. disintegration of adyarium. occultum and helium

DISINTEGRATION OF ADYARIUM

On the E4 level Adyarium sets free the two tetrahedrons Ad24 and Adl2.

On the E3 level the Ad24 gives 4 sextets, 4 Ad6, two positive and two negative ; while the Adl2 gives 4 triplets.

On the E2 level each Ad6 gives two triplets, making 8 triplets in all.

The triplets from the Adl2 each give a duad and a unit, thus liberating four duads and four units.

DISINTEGRATION OF OCCULTUM

The tetrahedron, Ad24, acts as in Adyarium on the E4 level and separates as a whole, with its 4Ad6, flattening itself out within its hole. Two of the Ad6 are positive and two negative.

On further dissociation to the E3 level, the Ad6 go off independently, showing two types. These again divide into triplets on the E2 level.

The ring, Ocl5, becomes a ring within a sphere and the two triads 2H3, which are loose in the gaseous atom, come within this ring. On the E3 level the ring casts out the two triads, which become independent triplets, and the ring breaks into two, a close ring of seven Anu and a double cross of eight.

These subdivide again to form E2 compounds, the ring yielding a quintet and a pair, and the double cross separating into its two parts.

The two triplets each cast out an Anu on dissociation to E2 and form two pairs and two units.

The balloon, Oc9. On the E4 level the balloon becomes a sphere. On the E3 level it is much divided, the cohesion of its parts being slight. It forms two triplets, a pair and a unit. On the E2 level these set free, on further dissociation, no less than five separate Anu and two duads.

DISINTEGRATION OF HELIUM

Helium, being composed of the constituents of Hy-Jrogen, Adyarium and Occultum, breaks up as do these elements.

On the E4 level we find two spheres each containing three triplets as in Hydrogen and two tetrahedrons, Ad24. In addition there is a globe containing two small spheres, 2 H3.

On the E3 level the Hydrogen triplets break up as ir Fig. 19 and the two Ad24 as shown in Fig. 20. The globe containing the two H3 liberates the two triplets on the E3 level.

On the E2 level the disintegration proceeds as shown in Figs. 19 and 20.

CHAPTER III

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