After the twilights had been getting normal through the past three weeks, where hardly any volcanic aerosoles from Sarychev volcano had been measured, I was very astonished when I saw an intense purple light with crepuscular rays about half an hour before sunrise (sun elevation at -6°) in the morning of November 17. The crepuscular rays crossed the whole sky near the horizon, converging at the antisolar point (1 - 2 - 3).
Of course I immediately asked my colleagues from the Hohenpeissenberg observatory about the phenomenon. And I got a very surprising answer:
At that moment there were two different layers of dust from the Sahara desert above us, a lower one at an altitude of about 8.5 kms with dust from the western parts of the Sahara, and a higher one at about 11 kms, which contained dust from the eastern part of the Sahara. There were two different currents of air at higher levels which overlapped each other above the Alps.
It is new for me to learn that such twilights are also possible in desert dust, just as this dust up to now only caused a kind of certain dimness in the air. But at that moment there was no desert dust directly above us; I only looked into the layers of dust.
However, there was an extra bonus on the next morning. Unfortunately could only watch it from the valley:
Monday, November 23, 2009
Thursday, November 19, 2009
Twinned rainbow
Mark Worme observed this rainbow today at around 3.15 pm Atlantic Standard Time in central Barbados facing east. At first he only noticed the double rainbow, but then he realized the lower one was split.
During a heavy rainshower, a twinning of the upper part of a rainbow can sometimes be observed, which often lasts from a few seconds up to several minutes. As for a long time there were only few observations of this phenomenon available, only speculations could be made about its origin. Only in the past few years, this twinning could be registered more often by continuous observations, and due to some detailed descriptions, new theories could be advanced. As in all observations both bows are of equal brightness, light refraction on ice particles can be ruled out. Most probably is that raindrops of a non-spherical shape produce one of these bows or even both of them. Due to surface-tension, small rain droplets hardly change their shape when falling, but large drops can be flattened by the air resistance. The more flattened they become, the smaller is their refractive index. So the sunlight has to fall upon water drops of different size at the same time to make the twinning appear. As this twinning was up to now observed under big shower or thunder clouds which formed in hot air, it can be supposed that the small, not flattened raindrops evaporate at a short distance below the cloud basis. This would explain why the twinning can only be seen for a short time and exclusively in the upper part of the rainbow. It should be important to determine the radius of the rainbow when the twinning is observed, and to record the weather situation at the time the twinning appears as exactly as possible.
During a heavy rainshower, a twinning of the upper part of a rainbow can sometimes be observed, which often lasts from a few seconds up to several minutes. As for a long time there were only few observations of this phenomenon available, only speculations could be made about its origin. Only in the past few years, this twinning could be registered more often by continuous observations, and due to some detailed descriptions, new theories could be advanced. As in all observations both bows are of equal brightness, light refraction on ice particles can be ruled out. Most probably is that raindrops of a non-spherical shape produce one of these bows or even both of them. Due to surface-tension, small rain droplets hardly change their shape when falling, but large drops can be flattened by the air resistance. The more flattened they become, the smaller is their refractive index. So the sunlight has to fall upon water drops of different size at the same time to make the twinning appear. As this twinning was up to now observed under big shower or thunder clouds which formed in hot air, it can be supposed that the small, not flattened raindrops evaporate at a short distance below the cloud basis. This would explain why the twinning can only be seen for a short time and exclusively in the upper part of the rainbow. It should be important to determine the radius of the rainbow when the twinning is observed, and to record the weather situation at the time the twinning appears as exactly as possible.
Sunday, November 15, 2009
Shadows and lights of a flight
Many people find flights boring - but not all! If you are lucky to be seated by a window you can always find something interesting in the air beside or below the airplane. David Lukacs from Hungary took this picture on 2nd November 2009 on a flight from Rome to Budapest, about 15 minutes after the departure. A thin layer of haze was between the plane and the sea so the sun shining on the right side above the plane could cast radial shadows on the left below. The beams of shadow and light join at the antisolar point.
A bit later when the plane travelled above a cloud layer David also noticed a nice glory below them:
Even the shadow of the airplane appeared in the middle:
A bit later when the plane travelled above a cloud layer David also noticed a nice glory below them:
Even the shadow of the airplane appeared in the middle:
Thursday, September 17, 2009
Thunderstorm shadows
In the evening of June 29, 2009, several thunderstorms formed unexpectedly over northwestern Germany, from the Ruhr area northward to southern Lower Saxony. They brought rainfalls up to 30 liters per square meter.
As the sun was almost setting, the shadows of the storm clouds reached a length of several hundred kilometers. The satellite picture taken at 19.15 UTC = 21.15 CEST shows the shadows extending even up to Thuringia and northern Bavaria.
Unfortunately, there are no reports on crepuscular rays from the area southeast of the thunderstorms.
Author: Peter Krämer, Bochum, Germany
Satellite image with kind permission of DWD (German Weather Office)
As the sun was almost setting, the shadows of the storm clouds reached a length of several hundred kilometers. The satellite picture taken at 19.15 UTC = 21.15 CEST shows the shadows extending even up to Thuringia and northern Bavaria.
Unfortunately, there are no reports on crepuscular rays from the area southeast of the thunderstorms.
Author: Peter Krämer, Bochum, Germany
Satellite image with kind permission of DWD (German Weather Office)
Sunday, September 06, 2009
Interference Phenomena on Soap Bubble Surface
Inspired by my daughter who was playing with soap bubbles, I one day got the idea to take photographs of the surface of soap bubbles.
For this purpose I filled a big dark frying pan with water and put some dishwashing liquid in it. I mounted my little digicam on a clamp pod (figure 2) and aligned it roughly with the pan.
Then I blew some bubbles into the water using a drinking straw. Now I aligned the camera exactly with the vernier adjustment of the clamp pod and started photographing.
Already the first pictures turned out well, and a short while later I had made a considerable amount of pictures. I soon noticed a remarkably large variety in the positioning of the different colours on the soap bubbles. At first, the distribution of colours on the bubbles looked like a piece of abstract art, but later the colours arranged to parallel stripes, similar to a rainbow.
The reason for this play of colours:
The physical reason for these colours is the so called two-beam interference. This is remarkably well explained at http://www.itp.uni-hannover.de/~zawischa/ITP/zweistrahl.html (German) and http://www.itp.uni-hannover.de/~zawischa/ITP/twobeams.html(English).
The main statement in this explanation is that the colours depend directly from the optical length of way (and so from the thickness) inside the the soap layer. This is an explanation as well for the black “holes” at the highest point of the bubbles, as also for the colourful rings below these “holes”. The colourful flaws, which can be seen especially on “fresh” bubbles, are areas of different thickness of the soap layer, which are (still) positioned irregularly. Following the force of gravity, they slowly flow downwards causing the soap layer to be thinner at the top and thicker at the bottom of the bubbles. The constantly the thickness of the soap layer increases from the top to the bottom of the bubbles, the more regularly is the positioning of the colourful rings.
The Picture above show a detail on the surface of a soap bubble.
Figure 2: Camera mounted on a c-clamp. The distance between the camera lens and the soap surface is here about 4 cms.
Figure 3: Abstract play of colours on the surface of fresh soap bubbles.
Figure 4: The lesser the flaws in the soap layers are, the more regular is the increase of the thickness of the soap layer towards the bottom of the bubbles, and so is the play of colours. The spotted dark areas on top of the bubbles indicate that the bubbles are about to burst.
More pictures: 5 - 6 - 7
Author: Reinhard Nitze, Barsinghausen, Germany
For this purpose I filled a big dark frying pan with water and put some dishwashing liquid in it. I mounted my little digicam on a clamp pod (figure 2) and aligned it roughly with the pan.
Then I blew some bubbles into the water using a drinking straw. Now I aligned the camera exactly with the vernier adjustment of the clamp pod and started photographing.
Already the first pictures turned out well, and a short while later I had made a considerable amount of pictures. I soon noticed a remarkably large variety in the positioning of the different colours on the soap bubbles. At first, the distribution of colours on the bubbles looked like a piece of abstract art, but later the colours arranged to parallel stripes, similar to a rainbow.
The reason for this play of colours:
The physical reason for these colours is the so called two-beam interference. This is remarkably well explained at http://www.itp.uni-hannover.de/~zawischa/ITP/zweistrahl.html (German) and http://www.itp.uni-hannover.de/~zawischa/ITP/twobeams.html(English).
The main statement in this explanation is that the colours depend directly from the optical length of way (and so from the thickness) inside the the soap layer. This is an explanation as well for the black “holes” at the highest point of the bubbles, as also for the colourful rings below these “holes”. The colourful flaws, which can be seen especially on “fresh” bubbles, are areas of different thickness of the soap layer, which are (still) positioned irregularly. Following the force of gravity, they slowly flow downwards causing the soap layer to be thinner at the top and thicker at the bottom of the bubbles. The constantly the thickness of the soap layer increases from the top to the bottom of the bubbles, the more regularly is the positioning of the colourful rings.
The Picture above show a detail on the surface of a soap bubble.
Figure 2: Camera mounted on a c-clamp. The distance between the camera lens and the soap surface is here about 4 cms.
Figure 3: Abstract play of colours on the surface of fresh soap bubbles.
Figure 4: The lesser the flaws in the soap layers are, the more regular is the increase of the thickness of the soap layer towards the bottom of the bubbles, and so is the play of colours. The spotted dark areas on top of the bubbles indicate that the bubbles are about to burst.
More pictures: 5 - 6 - 7
Author: Reinhard Nitze, Barsinghausen, Germany
Wednesday, August 19, 2009
Intense colours of a lightrefraction on fireweed seeds
This year the season of my firweed-hunt began earlier than last year because in hope of a better lightrefraction on early seeds. It was about mid-july when I saw the first seeds falling and I was very surprised when i moved the seeds beetween the sun and my camera. The effect was extremely strong. I guess this came from the fresh seeds, they were not sticked together like last year and showed real bright colours. I shot about 20 pictures and afterwards I went alomost crazy when I saw these intense clours on my PC. The pictures (1-2-3-4-5-6-7-8) were taken with a Canon EOS 350D and a Tamron AF 70-300mm Makro lense near Langgoens in Germany.
Author: Rolf Kohl, Langgöns, Germany
Tuesday, August 11, 2009
Reflected light dewbow on water surface
I and my wife Eliisa Piikki got a hint about a light phenomenon on a lake nearby. Eliisa took some photos and there was a dewbow and a reflected light dewbow in those photos. They were formed on the waterdroplets that were settled down on the Chrysomyxa ledi needle rust (Small-spored spruce-Labrador-tea rust).
That rust can't be seen in Finland every year, but this year it is very common especially in the Eastern and in the Northern Finland. Because of the rust the young needles of some spruces are brown.
Author: Jari Piiki, Finland
That rust can't be seen in Finland every year, but this year it is very common especially in the Eastern and in the Northern Finland. Because of the rust the young needles of some spruces are brown.
Author: Jari Piiki, Finland
Friday, August 07, 2009
Reflection rainbow (Lahti, Finland)
On the evening 5th of August 2009, there was a reflection bow observed at city of Lahti. Marja Wallin saw and photographed a small fragment of reflection primary bow.
For the moment, the precise location of sun ray reflection is not yet analysed... To see her other rainbow photos for same evening, look at here.
Update (11th Aug 2009):
There is another gallery existing of the reflection rainbow, in same date and location, taken by Sami Luoma-Pukkila.
image (c) Marja Wallin
For the moment, the precise location of sun ray reflection is not yet analysed... To see her other rainbow photos for same evening, look at here.
Update (11th Aug 2009):
There is another gallery existing of the reflection rainbow, in same date and location, taken by Sami Luoma-Pukkila.
image (c) Marja Wallin
Tuesday, July 21, 2009
Volcanic Twilights
On June 12, 2009, one of the most active volcanoes of the Kuril islands near Kamtschatka, which is situated near the northwestern end of the island of Matua, Sarychev Peak, erupted.
A NASA picture taken from the ISS gives an impressive sight of the eruption. Ashes have been ejected up to 20 kms into the atmosphere. Only a few hours after the eruption, the sulfur dioxide cloud of the volcano covered an area of 2.407 kms in width and 926 kms in length above the island. During the following weeks, the aerosoles spread over the whole northern hemisphere.
On July 4, Peter Krämer observed the caracteristic crepuscular rays (picture above). On July 13, Reinhard Nitze photographed the most spectacular volcanic twilight in Barsinghausen near Hanover (Fig. 3). In his picture, the high aerosol clouds can easily be recognized. These clouds still receive sunlight while normal cirrus clouds are already within the shadow of the earth.
During the past few days, there were also noctilucent clouds visible, which passed over to the reddish aerosol clouds in lower layers. There should be unusual twilights visible also during the following weeks.
A NASA picture taken from the ISS gives an impressive sight of the eruption. Ashes have been ejected up to 20 kms into the atmosphere. Only a few hours after the eruption, the sulfur dioxide cloud of the volcano covered an area of 2.407 kms in width and 926 kms in length above the island. During the following weeks, the aerosoles spread over the whole northern hemisphere.
On July 4, Peter Krämer observed the caracteristic crepuscular rays (picture above). On July 13, Reinhard Nitze photographed the most spectacular volcanic twilight in Barsinghausen near Hanover (Fig. 3). In his picture, the high aerosol clouds can easily be recognized. These clouds still receive sunlight while normal cirrus clouds are already within the shadow of the earth.
During the past few days, there were also noctilucent clouds visible, which passed over to the reddish aerosol clouds in lower layers. There should be unusual twilights visible also during the following weeks.
Saturday, July 04, 2009
COMPOUND EYE OF A HORSEFLY
July 11, 2008:
I was very astonished when I was working and suddenly a horsefly fell upon my workbench.
The animal was about 3.5 cms in length. It was a very hot day, and the “flying fellow” had obviously lost his way, landed up in the workshop and could not find the way out. Well, the animal was lying there without moving, and the sunlight caused nice diffraction colours in its big compound eyes.
Author: Michael Großmann, Kämpfelbach, Germany
I was very astonished when I was working and suddenly a horsefly fell upon my workbench.
The animal was about 3.5 cms in length. It was a very hot day, and the “flying fellow” had obviously lost his way, landed up in the workshop and could not find the way out. Well, the animal was lying there without moving, and the sunlight caused nice diffraction colours in its big compound eyes.
Author: Michael Großmann, Kämpfelbach, Germany
MONASTIR RED RAINBOW
On May 13, 2008, I was flying to Tunisia. Just before the plane landed in Monastir, I looked out of the window and saw a faint onset of a red rainbow. About one minute later, the rain became heavier, and the bow became more intensive, even below the horizon. Unfortunately, the plane landed about two minutes later, and I could not see if the red rainbow was visible from the ground.
Author: Michael Großmann, Kämpfelbach, Germany
Author: Michael Großmann, Kämpfelbach, Germany
BACKLIGHTED WATER VAPOUR
March 10, 2009:
There is not always fine weather outside for making pretty pictures. So I tried to take some photographs of backlighted hot water vapour. Surprisingly, some pretty irisation colours appeared, which kept constantly changing in the rising “fountains”. Even after a short time, as the water cools down, the colours become less intensive as they are when the water is very hot.
Author: Michael Großmann, Kämpfelbach, Germany
There is not always fine weather outside for making pretty pictures. So I tried to take some photographs of backlighted hot water vapour. Surprisingly, some pretty irisation colours appeared, which kept constantly changing in the rising “fountains”. Even after a short time, as the water cools down, the colours become less intensive as they are when the water is very hot.
Author: Michael Großmann, Kämpfelbach, Germany
Saturday, June 13, 2009
Bochum Twinned Rainbow
On June 9, 2009, another twinned rainbow appeared in the skies over Bochum, Germany. The phenomenon only lasted less than a minute, and I could watch the “twin ettect” move from left to right through the rainbow.
This picture has been processed to make the effect more obvious, but here is another picture showing how it really looked (1).
Just after the “twin effect” had disappeared, the rainbow reached a stunning brightness making supernumeraries visible as well as Alexander´s Band (2).
Text: Peter Krämer, Bochum, Germany
This picture has been processed to make the effect more obvious, but here is another picture showing how it really looked (1).
Just after the “twin effect” had disappeared, the rainbow reached a stunning brightness making supernumeraries visible as well as Alexander´s Band (2).
Text: Peter Krämer, Bochum, Germany
Tuesday, April 21, 2009
Pollen corona in Deventer, The Netherlands
On April 1st 2009, Peter Paul Hattinga Verschure observed beautiful pollen coronae from his garden in Deventer, The Netherlands. Every time the wind blew through the pine trees, a cloud of pollen was blown away from them. When these clouds of pollen passed exactly in front of the sun, a beautiful pollen corona appeared. So, in one second it was bright and had three rings, in the next moment it disappeared again.
Tuesday, February 24, 2009
Tertiary Glass-Sphere Bow
I have discovered a spectral reflection phenomenon inside a transparent plexiglass-sphere. The phenomenon, of which I am almost sure it is NOT the equivalent of the Primary or Secondary Rainbow, is in fact the equivalent of the Tertiary Rainbow, visible as a bright illuminating spectral colored ring all along the limb of the sphere. To see this ring, one should look "from behind" the sphere, toward the sun, with the sun "in front" of it (appearing exactly "in the centre" of the sphere).
The photo show the sphere with appearance of the red component of the spectrum. The distance of the observing eye (or camera's lens) to the sphere is VERY important, because the focal point of the ring is not a point, it's a spectral colored line (red at the far end, blue at the near end).
As far as I know, no one has ever observed or photographed the ring-like appearance of, what I call, the Tertiary Glass-sphere Bow (which has a focal point or "line", behind the globe!).
Author: Danny Caes, Ghent-Belgium
The photo show the sphere with appearance of the red component of the spectrum. The distance of the observing eye (or camera's lens) to the sphere is VERY important, because the focal point of the ring is not a point, it's a spectral colored line (red at the far end, blue at the near end).
As far as I know, no one has ever observed or photographed the ring-like appearance of, what I call, the Tertiary Glass-sphere Bow (which has a focal point or "line", behind the globe!).
Author: Danny Caes, Ghent-Belgium
Thursday, February 05, 2009
Fascinating moonrise during an atmospheric inversion
After a bleak low stratus day, I decided to escape from the fog in the evening of the 13th of January 2009. I drove to the nearby Witthoh (Hegaualb, western Lake Constance, Southern Germany). There I wanted to record the rise of the moon – at least I hoped for a clinched moonrise, because of a prevailing atmospheric inversion.
Along the 860-metre-high Witthoh there was still a temperature of -10 degree centigrade. Two kilometers further away and 100 m higher the temperature was just 0 degree centigrade. Consequently, a very remarkable temperature layer existed in this region.
On the pre-calculated time, the moon’s upper margin pushed over the horizon.
What happened afterwards exceeded my boldest dreams. A “bubbling” of the rising moon followed as I had never seen it before.
Three times, approximately half of the rising moon completely detached from the lower half with red lightning.
The moon “boiled” on the upper half and it let vanish red and green rays upwards.
Only after circa 15 minutes, the moon calmed down completely.
Here is one more link of the moonrise as animated GIF file:
Along the 860-metre-high Witthoh there was still a temperature of -10 degree centigrade. Two kilometers further away and 100 m higher the temperature was just 0 degree centigrade. Consequently, a very remarkable temperature layer existed in this region.
On the pre-calculated time, the moon’s upper margin pushed over the horizon.
What happened afterwards exceeded my boldest dreams. A “bubbling” of the rising moon followed as I had never seen it before.
Three times, approximately half of the rising moon completely detached from the lower half with red lightning.
The moon “boiled” on the upper half and it let vanish red and green rays upwards.
Only after circa 15 minutes, the moon calmed down completely.
Here is one more link of the moonrise as animated GIF file:
Friday, January 30, 2009
Kitchen optics
An everyday kitchen can provide ample opportunities for observing optical phenomena, and as Mónika Landy-Gyebnár and Ágnes Kiricsi are not only good housewives but keen observers of such beauties, they always keep their eyes open for a chance of photographing something interesting while doing their household duties.
When you decide to drink your coffee in the early morning sunlight that just reaches your kitchen window, you might be lucky to get its steam of equal droplet size, and opening your eyes with the first sip of coffee you notice the colours of the drifting steam. You must have another sip to be sure that you really see the scattered sunlight and the display of iridescent colours.
If you use a spoon to stir your coffee with, don't run to the dishwasher immediately, but be a bit negligent, and wait till the coffee dries on it.
You may discover spectral colours again: patterns of thin film interference. Could it be the coffee's volatile oils or bacteria signalling problems of mouth hygiene?
Bisquits are always good to crunch with the morning coffee. Most of them are packed in a small cellophane bag that we can easily drop aside at the table by the window. And here comes the sun again - as its rays fall on the empty sachet, birefringence produces the well-known spectral colours again.
Not only human beings need a refreshment in the morning - our plants are also thirsty. And not only cellophane sachets are prone to showing birefringence, but transparent plastic flowerpots, too.
We have to pack a sandwich for the workday, maybe a good slice of ham - oops, the ham is also showing the spectral colours! The tiny (a muscle cell is about 10-80 microns in diameter), regularly arranged cells of the meat behave like the water droplets of clouds.
When the office hours are over, we still have some activities at home: for example making dinner for the family. Let's treat them with some meat balls, fried delicious in hot rainbow-coloured oil. Yes, rainbow coloured, as the afternoon sun still shines in, and the transparent oil bottle is placed in front of the window. You don't necessarily need a usm filter (or a usm sieve :)) to see the caustic patterns.
But be careful! Never cover hot food with a foil, otherwise they might produce colours again. First spectral ones on the foil, which we are happy about, but later a sickly shade of green on the meat itself. In this second stage, don't hesitate to throw the food into the dustbin.
Towards the end of the day, the work of the housewife has not ended yet. She's still on duty in the kitchen, looking at the pile of dirty dishes that has been produced.While the hot water gathers in the sink, it also steams a bit. There's no evening without a good streetlamp corona - you only have to look outside for a moment! The hot vapour has precipitated on the cold glass of your kitchen window, so the long day's last phenomenon wishes you good night with a colourful display.
Let's hope that reading so much about these household duties won't cause you nightmares of mugs carelessly washed up, and that one evening a brave man sits in front of the computer, and writes an article about the optical phenomena observed during his weekend-long tinkering in the workshop.
When you decide to drink your coffee in the early morning sunlight that just reaches your kitchen window, you might be lucky to get its steam of equal droplet size, and opening your eyes with the first sip of coffee you notice the colours of the drifting steam. You must have another sip to be sure that you really see the scattered sunlight and the display of iridescent colours.
If you use a spoon to stir your coffee with, don't run to the dishwasher immediately, but be a bit negligent, and wait till the coffee dries on it.
You may discover spectral colours again: patterns of thin film interference. Could it be the coffee's volatile oils or bacteria signalling problems of mouth hygiene?
Bisquits are always good to crunch with the morning coffee. Most of them are packed in a small cellophane bag that we can easily drop aside at the table by the window. And here comes the sun again - as its rays fall on the empty sachet, birefringence produces the well-known spectral colours again.
Not only human beings need a refreshment in the morning - our plants are also thirsty. And not only cellophane sachets are prone to showing birefringence, but transparent plastic flowerpots, too.
We have to pack a sandwich for the workday, maybe a good slice of ham - oops, the ham is also showing the spectral colours! The tiny (a muscle cell is about 10-80 microns in diameter), regularly arranged cells of the meat behave like the water droplets of clouds.
When the office hours are over, we still have some activities at home: for example making dinner for the family. Let's treat them with some meat balls, fried delicious in hot rainbow-coloured oil. Yes, rainbow coloured, as the afternoon sun still shines in, and the transparent oil bottle is placed in front of the window. You don't necessarily need a usm filter (or a usm sieve :)) to see the caustic patterns.
But be careful! Never cover hot food with a foil, otherwise they might produce colours again. First spectral ones on the foil, which we are happy about, but later a sickly shade of green on the meat itself. In this second stage, don't hesitate to throw the food into the dustbin.
Towards the end of the day, the work of the housewife has not ended yet. She's still on duty in the kitchen, looking at the pile of dirty dishes that has been produced.While the hot water gathers in the sink, it also steams a bit. There's no evening without a good streetlamp corona - you only have to look outside for a moment! The hot vapour has precipitated on the cold glass of your kitchen window, so the long day's last phenomenon wishes you good night with a colourful display.
Let's hope that reading so much about these household duties won't cause you nightmares of mugs carelessly washed up, and that one evening a brave man sits in front of the computer, and writes an article about the optical phenomena observed during his weekend-long tinkering in the workshop.
Sunday, January 25, 2009
Shadows on ice crystals
During the cold spell in the middle of January, some of us in Hungary started "experimenting" with snow crystals. As surface halos had been observed for several consecutive days (see the images of the odd radius surface halos by Ákos Ujj: 1 - 2 ), our basic idea was to find out whether we would see the trace of the 22 degree halo if we simply threw up the snow crystals covering the ground. Interestingly, the answer was yes. It was really exciting to observe that 22° from the sun, the crystals were glittering in spectral colours, and they faintly drew the form of the halo. Unfortunately, I was not so lucky with photographing the effect. All I could capture was the streetlamp casting its shadow on the crystals thrown and kicked in the air by Alexandra Farkas.
Saturday, January 17, 2009
Perigee Moon
This photo was taken by Claudia Hinz at the evening of Jan. 11th, 19.35 CET from Mt. Wendelstein (1838m), Southern Germany. The full Moon in this night was extra bright. Dr. Elmar Schmidt of the SRH University of Applied Sciences in Heidelberg, Germany, used an absolutely-calibrated photometer to precisely measure the moonlight and found it more than 50% brighter than that of a typical full Moon.
1. The Moon was at perigee, the side of the Moon's elliptical orbit closest to Earth.
2. The Earth-Moon system was near perihelion, the side of Earth's elliptical orbit closest to the sun. Extra sunlight increased the reflected luminosity of the Moon.
3. The Sun-Earth-Moon trio were almost perfectly aligned. This triggered a strong opposition effect an intense brightening of the lunar surface caused by the temporary elimination of normal shadows.
4. The weather conditions were optimal for photometry due to the clean and dry arctic air (its relative humidity being less than 10% at the moment of the photo). This resulted in only clear air scattering of moonlight with no extraneous glare as evident in the completely blue night sky. The brightness of the mountain landscape was additionally increased because of the reflection from the snow.
Elmar Schmidt details the relative contributions of each factor in his full report.
Text: Elmar Schmidt & Claudia Hinz
Effects in cloud bows caused by perspective
In the morning of December 12, 2008, I coud observe a cloud bow on a stratocumulus layer, which was kind of perspectively cracked. Due to the ruggedness of the cloud surface it seemed as if there was a deep horizontal notch on the left side of the cloud bow.
But also this moonlight cloud bow, taken on September 9, 2008, seems to have vertical indentations and also an elliptical shape caused by the horizontal projection upon an uneven surface.
But also this moonlight cloud bow, taken on September 9, 2008, seems to have vertical indentations and also an elliptical shape caused by the horizontal projection upon an uneven surface.