Element 115, the key
to understanding how the ultra-secret "Black World" has created aircraft
capable of manipulating gravity and space/time, has been identified, and
the recent discovery of element 118, which decayed into
element 114, further helps identify the possibilities.
The most important attribute
of this heavier, stable element is that the gravity A wave is so
abundant that it actually extends past the perimeter of the atom.
These
heavier, stable elements literally have their own gravity A field around
them, in addition to the gravity B field that is native to all
matter.
The Key To
Gravity-Control Systems
No naturally occurring atoms on earth have enough protons and
neutrons for the cumulative gravity A wave to extend past the
perimeter of the atom so you can access it.
Now even though the distance
that the gravity A wave extends past the perimeter of the atom is
infinitesimal, it is accessible and it has amplitude, wave length, and
frequency, just like any other wave in the electromagnetic spectrum.
Once you can access the gravity A wave, you can amplify it just like we
amplify other electromagnetic waves.
And in like manner, the gravity A wave is amplified and then
focused on the desired destination to cause the space/time distortion
required for practical space travel.
This amplified gravity A wave is so powerful that the only naturally
occurring source of gravity that could cause space/time to distort this
much would be a black hole.
We're amplifying a wave that barely extends past the perimeter of an
atom until it's large enough to distort vast amounts of space/time.
Transmutation
We synthesize heavier, unstable elements by using more stable elements
as targets in a particle accelerator. We then bombard the target element
with various atomic and sub-atomic particles.
By doing this, we actually
force neutrons into the nucleus of the atom and in some cases merge two
dissimilar nuclei together. At this point, transmutation occurs, making
the target element a different, heavier element.
As an example, in the early 80's, the lab for heavy ion research in
Darmshtot, Germany synthesized some element 109 by bombarding
Bismuth 203 with Iron 59. And to show you how difficult it is to do
this, they had to bombard the target element for a week to synthesize 1
atom of element 109.
And on that subject, this same lab has projected
that in the future they should be able to bombard Curium 248 with with
Calcium 48 to yield element 116 which will then decay through a series
of nuclides which are unknown to them, but are well known to the
scientists at S4 located within the complex of the Groom Lake "Area
51" installation.
The length of time which an element exists before it decays determines
its stability. Atoms of some elements decay faster than atoms of other
elements, so the faster an element decays, the more unstable that
element is considered to be.
When an atom decays, it releases or
radiates sub-atomic particles and energy, which is the radiation that a
Geiger counter detects.
Alien Craft
The reactor found in the alien craft at S4, as widely mentioned
by physicist Robert Lazar is primarily based on a superheavy
element with an atomic number of 115.
Element 115 will be
designated as "Ununpentium" according to IUPAC guidelines. Its
periodic designation and electron configuration appear in the diagram at
the top of the page.
GENERAL PROPERTIES
Name:
Ununpentium
Symbol:
Uup
Atomic Number:
115
Atomic Weight:
UNKNOWN
Density @ 293K:
31.5g/cm³
Atomic Volume:
13.45cm³/mol
Group:
Superheavy Elements
Discovered:
1989
STATES
State:
Solid
Melting Point:
1740°C
Boiling Point:
3530°C
Heat of Fusion:
UNKNOWN kJ/mol
Heat of Vaporisation:
UNKNOWN kJ/mol
ENERGIES
1st Ionization Energy:
531 kJ/mol
Electronegativity:
UNKNOWN
2nd Ionization Energy:
1756 kJ/mol
Electron Affinity:
UNKNOWN kJ/mol
3rd Ionization Energy:
2653 kJ/mol
Specific Heat:
UNKNOWN J/gK
Heat Atomization:
kJ/mol atoms
APPEARANCE AND
CHARACTERISTICS
Structure:
FCC Face-centered cubic
Color:
Reddish-orange
Uses:
Reactor Fuel
Toxicity:
UNKNOWN
Hardness:
UNKNOWN mohs
Characteristics:
Stable
CONDUCTIVITY
Thermal Conductivity:
6.1 J/m-sec°
Electrical Conductivity:
7.09 1/mohm-cm
Polarizability:
20.5 A³
Sci/Tech
New superheavy elements created
BBC News Online Science
Editor Dr David Whitehouse
June 9, 1999
The collision of
lead and krypton leads to the new elements.
Two new "superheavy"
elements have been made by bombarding lead atoms with energy-packed
krypton atoms at the rate of two trillion per second.
After 11 days, the scientists working at the Lawrence Berkeley
National Laboratory, US, had produced just three atoms of element
118. These contained 118 protons and 175 neutrons each in their nucleii.
The new elements decayed almost instantly to element 116, which itself
was short-lived. But, for that brief moment, they were the only three
atoms of these elements ever to have existed on Earth.
Ken Gregorich, the nuclear chemist who led the discovery team,
said:
"Our unexpected success
in producing these superheavy elements opens up a whole world
of possibilities using similar reactions: new elements and
isotopes."
US Secretary of Energy,
Bill Richardson, commented:
"This stunning discovery
opens the door to further insights into the structure of the atomic
nucleus."
Unstable
combination
Atoms consist of a central nucleus surrounded by a cloud of electrons.
The nucleus consists of protons and neutrons.
But not all combinations of neutrons and protons are stable. In nature,
no element heavier than uranium, with 92 protons and 146 neutrons, can
normally be found.
Scientists can make heavier ones by colliding two large nuclei together
and hoping that they will form a new, heavier nucleus for a short time.
One of the most significant aspects of the new elements is that their
decay sequence is consistent with theories that predict an "island of
stability" for atoms containing approximately 114 protons and 184
neutrons.
"We jumped over a sea of
instability onto an island of stability that theories have been
predicting since the 1970s," said nuclear physicist Victor Ninov.
He is the first author of a
paper on the discovery submitted to Physical Review Letters journal.
Atomic structure
Synthetic elements are often short-lived, but provide scientists with
valuable insights into the structure of atomic nuclei. They also offer
opportunities to study the chemical properties of the elements heavier
than uranium.
I-Yang Lee, scientific director of the atom smasher at
Lawrence Berkeley National Laboratory, said,
"From the discovery of
these two new superheavy elements, it is now clear that the island
of stability can be reached.
"Additionally, similar reactions can be used to produce other
elements and isotopes, providing a rich new region for the study of
nuclear properties."
Fast work
Element 118
takes less than a thousandth of a second to decay by emitting an
alpha particle
This leaves behind
an isotope of element 116 which contains 116 protons and
173 neutrons
This daughter is
also radioactive, alpha-decaying to an isotope of element 114
The chain of
successive alpha decays continues until at least element 106
PhysicsWeb
Element 118
disappears two years
after it was discovered
1 August 2001
Researchers at the
Lawrence Berkeley National Laboratory in the US have retracted their
claim to have discovered element 118.
The retraction follows more
detailed analysis of the original data at Berkeley and the failure of
experiments at Berkeley, the RIKEN laboratory in Japan, and the GSI
laboratory in Germany to observe the element.
In 1999 a team of researchers from the Berkeley lab, the University of
California at Berkeley and Oregon State University claimed to have
detected three atoms of element 118 in collisions between high-energy
krypton ions and a lead target.
"The observation of a
chain of six high-energy alpha decays within about one second
unambiguously signalled the production and decay of element 118"
said team leader Ken Gregorich at the time.
Element 118 was then
the heaviest element to have been detected.
In a brief statement submitted to Physical Review Letters, which
published the paper reporting the original discovery, the Berkeley team
write:
"Prompted by the absence
of similar decay chains in subsequent experiments, we (along with
independent experts) re-analyzed the primary data files from our
1999 experiments. Based on these re-analyses, we conclude that the
three reported chains are not in the 1999 data. We retract our
published claim for the synthesis of element 118."
"Science is self-correcting," said Berkeley director Charles
Shank. "If you get the facts wrong, your experiment is not
reproducible. There are many lessons here, and the lab will extract
all the value it can from this event. The path forward is to learn
from the mistakes and to strengthen the resolve to find the answers
that nature still hides from us."
