Do
Microscopes Work?
Photograph taken outside
Rutgers University, Newark, New Jersey, October 2015.
It seems likely that most, if not all, diagnosed diseases are
fictions used to control and reduce populations. First, when one looks into a microscope one
is focusing on something within the microscope, not what is on the slide. Second, the size a cancer or viral cell is
said to be means it would be unable to do harm, no matter how many there
are. Third, there is no explanation of
how the instructions or information within DNA would alter living matter. Diseases kill because of policies to suppress
appetite and otherwise cause harm, including by causing fear.
A microscope acts similarly to a kaleidoscope, in the sense that
we are viewing something within the microscope, not what is on the slide. We
are unlikely to be seeing the object on the slide because of where the slide is
placed, even if the magnifications said to be needed were capable of being
achieved, there were sufficient light, and our eye was close enough to the
small objective lenses.
First, the magnifications said to be needed to view cells are
unlikely to be achievable: additional lenses add rather than multiply
magnification, while the focal adjustment and objective lenses are rotated
rather than extended or contracted. If
the magnification were possible to achieve, we would, in any case, only see a
speck on the microscope slide at any one time so that, with a traditional
microscope (ie, where the slide has to be manipulated by hand), parts of the
material on the slide would be missed. Second,
the objective lenses are very small, and our eyes are too far from them to make
visibility of the material on the slide possible. Third, and especially given the size of the
lenses, the lighting is insufficient to make viewing of the slide
possible. No beam of light is shone from
the microscope onto the slide. In other
words, it is the microscope, not the material on the slide beneath the small
lenses, which is illuminated. Also, the
angle at which the mirror is placed to capture light when the microscope is lit
by the mirror is not such as to maximise light entering the microscope, nor to
capture an image of the entire slide, as can be seen from the fact that the
cylinder becomes dark if an opaque object on the slide is moved only slightly. In fact, the cylinder, or lens tube, has to
be dimly lit in order to see the actual object we are viewing, which disappears
if there is too much light from the mirror (as when one looks into a camera in
bright sunlight), again making it unlikely we would be able to view an object
outside it. Fourth, if the
magnifications said to be needed to view a cell were achievable, the slide
would need to be placed far from the microscope for the image not to blur – as is
the case with a telescope, which works according to the same principles of
light and lenses. This is implied by the
reference on zoom lenses to its reach, ie, the distance at which objects can be
seen clearly.
From observation using my own microscope, a vividly coloured small
object (a butterfly scale) on the microscope slide does sometimes appear to be
visible when the microscope is lit from the mirror but appears only to wash
over the complex (in the sense of containing different parts) image on the
screen, and then one is more likely to be seeing an impression of the stain
than the object itself. The fact that the slide is placed where it is rather
than inside the microscope in fact indicates that the aim is not to see what is
on the slide at all, although if we were able to see that far we would expect,
if the microscope were lit by the mirror (ie, the mirror were not facing
downwards), to see our own eyes reflected back. That we are not observing what is on the
slide can be seen from the fact that, on the whole (ie, apart from the presence
or absence of a ‘wash’), the image does not change whether or not the slide is
present. If the slide is lit from
within, so that we are not viewing a projected image, then even if there were
enough light to see what was outside the microscope it might, in fact, appear
smaller, as when objects placed beyond a glass of water appear reduced in size (and
are not those directly in front of the glass) whereas, for instance, a fork
placed inside it appears larger.
What we are most likely to be seeing is an object within the microscope,
which, from observation, appears to be the lens of a small animal, probably
bird, eye. First, at the higher end of
the microscope we may see the translucent image of the lenses of our own eye
projected in front of us. The magnification
is similar to that achieved by the eye alone squinting into sunlight and is
achieved as a result of the reduction in focal length when looking into the
microscope. Second, if I look up into
the objective lenses of my own microscope I can see, in two of them, what looks
like a concave orange ‘rim’, resembling the iris of a small animal, such as a pigeon,
which shifts slightly if I tilt the microscope. The image on the screen also shifts
slightly if I tilt the microscope. The
similarity between the image of the lens of my own eye and the image on the
screen indicates that I am likely to be viewing on the screen the object with
the orange rim since this resembles a small eye, with a small part of the
stained material on the slide on the microscope stage appearing, at most, as a
wash over the clearer and more detailed object.
Since the lenses are used to adjust focus, magnification of the image is
by our eye and the result of projection onto a screen or glass higher up the
microscope. In fact, the magnified cylinder
looks, on inspection, likely to be only that of the focal adjustment itself –
ie, the image of the lenses contained within the tube are projected onto a
glass or screen near the top of the microscope. In sum, we are at most seeing only a blurred impression
of part of the material on the glass slide and the clear and detailed object
one sees is likely to be of the lens of a small bird’s eye contained, and
projected, within the microscope.
Second, something as small as a cancer or viral or Ebola cell
would not be able to travel or survive in the fluids and fluctuations of the
human body or, even if it were able to, cause harm, no matter how many cells there
are (as being stung by a large number of small wasps will not hurt in the same
way as being stung by one large wasp and may have a protective effect, in the
same way as a first injury to the body may lessen the impact of the second). In fact, something invisible to the eye at
the appropriate range seems intuitively to be unlikely to have shape or mass by
however many it is multiplied and so not to exist.
Third, there is no satisfactory philosophical or scientific
explanation of how the information, or instructions, contained within DNA, said
to be present in every cell of the human body, can interact with and change living
matter (which, other than the brain, is not said to be conscious and therefore
able to ‘read’ the instructions), in other words, by what mechanism, or
mechanical link, and using what force, or, if it can, in a way that is
different to or greater than those changes caused by environmental factors such
as nutrition or physical injury or ageing.
Diagnosed diseases kill because of factors such as fear and
fatalism, inadequate nutrition (eg, food that is too salty), gas emissions
(which suppress appetite as well as weakening the body), alcohol and tobacco,
and extremes of temperature. Clausewitz
said war was a continuation of policy by other means, but science fiction, eg,
disease, is likely also to be a policy of war, intended to dominate nature
(knowledge of whose intelligence has also been suppressed), promote secularism,
and control and reduce populations. For
example, it seems unlikely that the earth would rotate at 66,600 miles per hour
around the sun or, even if it did (in some sort of cocoon), at the same time
rotate at 1,000 miles per hour on its axis.
If the atmosphere moved at the same speed, birds would have to fly
against a 1,000 mile per hour wind or, if the atmosphere did not move, they
would find themselves 0.28 miles along the road a second after they had
ascended into the air.
© Louise
Orrock, February 2016
No comments:
Post a Comment