Transcript Finland
Light and colors
How do we see light?
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The human eye is like a complicated telescope. We have lenses to focus light with pupils which dilate
and contract to control how much light gets through. We also have retinas which turn the light into an
electrical signal travelling through neurons to the brain. Retinas have special cells called photoreceptor
cells which come in two varieties, rods and cones. Rods are more sensitive to light and are used to see
at night, while cones help us distinguish colors. Most humans have three different kinds of cones (color
blind people only have two), each of which is sensitive to a different range of wavelengths. Each photon
has a chance to be absorbed by the molecules in the rods and cones. This light energy is used to
convert molecules in the cell to a higher energy state which sets off a cascade of flowing charges,
becoming a signal to the brain.
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We note that there is lots of light that we don't see.
Most humans can only see light that has a
wavelength approximately between 400 and 700
nanometers. Radiowaves, microwaves, infrared
radiation, ultraviolet radiation, x-rays, and gamma
rays all have wavelengths outside of this range.
How do we see colors?
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Roses are red and violets are blue, but we only
know that thanks to specialized cells in our eyes
called cones.
When light hits an object, e.g. a banana, the object
absorbs some of the light and reflects the rest of it.
Which wavelengths are reflected or absorbed
depends on the properties of the object. For a ripe
banana, wavelengths of about 570-580 nanometers
bounce back. These are the wavelengths of yellow
light.
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When you look at a banana, the wavelengths of reflected light determine
what color you see. The light waves reflect off the banana's peel and hit
the light sensitive retina at the back of your eye. That's where cones come
in. Cones are one type of photoreceptor, the tiny cells in the retina that
respond to light. Most of us have 6 to 7 million cones, and almost all of
them are concentrated on a 0.3 millimeter spot on the retina called the
fovea centralis.
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Fireworks
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Fireworks need a source of combustible
material for energy such as black
powder, a mixture of charcoal and
sulfur or smokeless powder such as
cellulose nitrate.
fireworks contain substances that give
off bright, colorful light when heated.
This phenomenon has been
the basis of flame tests in
chemistry laboratories.
The colored flame is a result of
electrons in sodium ions
absorbing energy and moving
up to higher energy levels and
then falling back to their
ground state, emitting specific
amounts of energy that
correspond to colors of light
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Chemical ingredients of fireworks are
chosen to produce specific colors.
Barium compounds produce green colors
when heated.
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Copper salts produce green and blue flames.
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Sodium salts are yellow in flame.
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Lithium compounds produce red colors.
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Magnesium metal produces brilliant white
light when burned.
Strontium compounds produce brilliant red
colors
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Fireworks consist of a source of energy
such as a mixture of a fuel and an
oxidizing agent that react to produce
high temperatures and some substance
that will emit brightly colored light.
Halo
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A halo is an optical phenomenon produced by ice
crystals creating colored or white arcs and spots in
the sky. Many are near the sun or moon but others
are elsewhere and even in the opposite part of the
sky. They can also form around artificial lights in
very cold weather when ice crystals called diamond
dust are floating in the nearby air.
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There are many types of ice halos. They are produced by the ice crystals in
cirrostratus clouds high (5–10 km) in the upper troposphere. The particular shape
and orientation of the crystals is responsible for the type of halo observed. Light is
reflected and refracted by the ice crystals and may split up into colors because of
dispersion. The crystals behave like prisms and mirrors, refracting and reflecting
sunlight between their faces, sending shafts of light in particular directions.
22° halo
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A 22° halo is a halo, one type of optical phenomenon, forming a circle 22° around
the sun, or occasionally the moon. It forms as sunlight is refracted in millions of
randomly oriented hexagonal ice crystals suspended in the atmosphere. The halo
is large; the radius is roughly the size of an outstretched hand at arms length.
AURORA
WHAT ARE THEY?
The lights are seen above the magnetic
poles of the northern and southern
hemispheres
They are known as Aurora borealis in the
north and Aurora australis in the south
Auroral displays appear in many colours
although pale green and pink are the most
common
Shades of red, yellow, green, blue, and
violet have been reported
HOW IT HAPPENS?
Aurora is actually the result of collisions between gaseous
particles in the Earth's atmosphere with charged particles
released from the sun's atmosphere
Blown towards the earth by the solar wind, the charged particles
are largely deflected by the earth's magnetic field (the earth's
magnetic field is weaker at either pole) → therefore some
particles enter the earth's atmosphere and collide with gas
particles → These collisions emit light that we perceive as the
dancing lights of the north and the south
AURORA BOREALIS
In northern hemisphere the effect is known as the aurora
borealis or the northern lights
Auroras seen near the magnetic pole may be high
overhead, but from farther away they illuminate the
northern horizon as a greenish glow or sometimes a faint
red as if the sun were rising from an
unusual direction
The aurora borealis most
often occurs near
the norther hemisphere
AURORA AUSTRALIS
Its southern counterpart, the aurora
australis or the southern lights has
features that are almost identical to
the aurora borealis and changes
simultaneously with changes in the
northern auroral zone
It is visible from high southern
latitudes in Antarctica, South
America, New Zealand, and
Australia
COLORS
The most common auroral color, a pale yellowishgreen is produced by oxygen molecules and very
rare, all-red auroras are produced by high-altitude
oxygen. Nitrogen produces blue or purplish-red
aurora.
AURORA IN FINLAND
The best way to see the
Northern lights in Finland is
to visit in Lapland
The sky should be clear and
cloudless so the lights can
be seen well
In the night sky they are
beautiful and very well seen
Rainbow
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An optical and meteorological phenomenon
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It appears, when the light refracts
on the front surface of the
waterdrop, reflects on the back
surface of the drop and refracts again on the front
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The waterdrop is disperctive, so the white light breaks into
the seven main colours which form the rainbow
The rainbow is seen, when you stand the back to the sun
and you point to the rain in front of you
42°
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Rainbow is always a full circle but you see often just
part of it
Double rainbow
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Sometimes light reflects another time on the
waterdrops before they reach the eye of the
spectator
A second, more matt, rainbow appears close to the
other and forms the colours in reverse order. It’s
called DOUBLE RAINBOW
http://www.youtube.com/watch?v=99E9fDgZZuE
Double rainbow
Monochrome rainbow
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A shower may happen at sunrise or sunset, where
the shorter wavelengths like blue and green have
been scattered and essentially removed from the
spectrum.
Further scattering may occur due to the rain and
the result can be the rare and dramatic. This
rainbow is called MONOCHROME RAINBOW
LIGHTNING
Lightning is a massive electrostatic
discharge between the electrically
charged regions within clouds or
between a cloud and the surface of a
planet
Lightning happens
when the negative
charges (electrons)
in the bottom of the
cloud are attracted
to the positive
charges (protons) in
the ground.
The accumulation of electric
charges has to be great
enough to overcome the
insulating properties of air.
When this happens, a stream
of negative charges pours
down towards a high point
where positive charges have
clustered due to the pull of
the thunderhead.
The connection is made and
the protons rush up to meet
the electrons. It is at that
point that we see lightning
and hear thunder. A bolt of
lightning heats the air along
its path causing it to expand
rapidly. Thunder is the sound
caused by rapidly expanding
air.