I made epoxy leaf print of plants from around my home by using 10 minute epoxy on acrylic or glass slides.
Brassica oleracea (Alboglabra group, AKA Kailan) X600
Note the high density of very small stomata on this leaf as compared to those on the other plants shown below. These stomata are closed because the it came from a vegetable that has been in the fridge for several days.
Portulaca (AKA Purslane. Exact species indeterminate) X600
These stomata appear enormous when compared to those from Kale. These came fresh from my garden so the stomata are in open position.
Petal print from Caesalpinia pulcherrima f. flava (AKA Peacock flower) X600
Even petals have stomata! These stomata are closed as the petal was picked just after sunrise.
"Needle" print from Casuarina Equisetifolia X400
Casuarina trees are a common sight along Singapore's beaches. The have needle-like leaves (modified branchlets called cladodes) which you can break and gingerly stick together again before passing it off to a friend to guess the point of breakage. Although the lateral leaf print does not reveal the transverse structure of ridges that run along the length of the needles, it is evident the stomata are very small with no discernable guard cells in this 400 magnification picture. Due to the deeply recessed ridges, my 60X objective could not be brought to focus on these pit-like stomata.
Microscope : Olympus CHB, 10X eyepiece, 60X and 40X objective (Condenser stopped down about 2/3 way)
Camera : LG Optimus black
Tuesday, December 6, 2011
Saturday, November 19, 2011
Polarized Light Microscopy - Vanillin
If you've eaten anything that was vanilla flavoured, then you know the smell of vanillin.
I purchased a bottle of what appears to be white crystals of synthetic vanillin from a baking supplies store. A small pinch of crystals were wedged under a cover slip and gently heated until they have melted. The solid-liquid melting transition is surprising sharp compared to sugar and yields beautiful fields of crystals.
The initial melt yielded circular crystal patterns due to crystal formation around random seeds
Upon gingerly reheating and partially remelting 3/4 of the vanillin on the slide, the melt reform by using previously formed crystal boundaries from unmelted crystals from the previous melt.
Microscpe : Olympus CHB x10(0.25) objective with x10 eyepiece
Camera : LG Optimus Black (1.75 stops underexposure with "Vivid" color option)
I purchased a bottle of what appears to be white crystals of synthetic vanillin from a baking supplies store. A small pinch of crystals were wedged under a cover slip and gently heated until they have melted. The solid-liquid melting transition is surprising sharp compared to sugar and yields beautiful fields of crystals.
The initial melt yielded circular crystal patterns due to crystal formation around random seeds
Unpolarized View of vanillin crystals |
Vanillin crystals through crossed polarizers |
Upon gingerly reheating and partially remelting 3/4 of the vanillin on the slide, the melt reform by using previously formed crystal boundaries from unmelted crystals from the previous melt.
Microscpe : Olympus CHB x10(0.25) objective with x10 eyepiece
Camera : LG Optimus Black (1.75 stops underexposure with "Vivid" color option)
Labels:
Microscopy
Tuesday, November 1, 2011
O-level English : There is no point in preserving the past. We should be looking to the future.
Sample Essay
http://mareingenii.t15.org/EngOlvl/There%20is%20no%20point%20in%20preserving%20the%20past%20We%20should%20be%20looking%20to%20the%20future.html
http://mareingenii.t15.org/EngOlvl/There%20is%20no%20point%20in%20preserving%20the%20past%20We%20should%20be%20looking%20to%20the%20future.html
Labels:
Essays,
General Paper
Polarized Light Microscopy
A student of mine tore apart his old digital dictionary that he was going to toss in the trash. We had a nice time discussing its construction and he gave me its LCD screen from which I tore off a polarizing film. I cut the film into discs and added them to the light path of my Olympus CHB microscope. One went under the eyepiece turret while the other under the condenser.
These are the results:
Citric Acid Crystals at 100 times magnification (Camera : LG Optimus Black)
A technical treatment of this is available here:
http://www.microscopyu.com/articles/polarized/polarizedintro.html
These are the results:
Citric Acid Crystals at 100 times magnification (Camera : LG Optimus Black)
Small Citric Acid Crystal at 400 times magnification
A technical treatment of this is available here:
http://www.microscopyu.com/articles/polarized/polarizedintro.html
Labels:
Microscopy
Monday, April 18, 2011
Math : Problem Sum
PSLE math : Primary 5 problem sum.
THis is a post in response to a question from one of my students.
THis is a post in response to a question from one of my students.
Labels:
Mathematics
Monday, March 21, 2011
Thursday, February 17, 2011
Japanese Sec 4 math question
Holy cow. I saw this sec 4 level question from a Japanese forum.
http://www.page.sannet.ne.jp/ikenoue/type2/area/area.html
Apparently its for some entrance exam.
I think the Japs are insane...
My solution provided. The solution on the webpage is different from mine because they
defined the radius of the circle as half r while I defined it as r, but basically the same strategy.
http://www.page.sannet.ne.jp/ikenoue/type2/area/area.html
Apparently its for some entrance exam.
I think the Japs are insane...
My solution provided. The solution on the webpage is different from mine because they
defined the radius of the circle as half r while I defined it as r, but basically the same strategy.
Labels:
Mathematics
Monday, February 7, 2011
Physics : Lissajous Figures
Ever since I first read of them in junior college, I have always found Lissajous figures mesmerizing and beautiful.
I found a simple way to create them without using two function generators (poor me; I could only afford one) by using the left and right audio channels of a laptop.
You can also create them in sand! This is a hands-on experiment I did at a science camp; needless to say, the kids loved messing around with it.
I found a simple way to create them without using two function generators (poor me; I could only afford one) by using the left and right audio channels of a laptop.
You can also create them in sand! This is a hands-on experiment I did at a science camp; needless to say, the kids loved messing around with it.
Labels:
Physics
Physics : Corner cube reflectors
This is a corner reflector used by surveyors to measure distances precisely by bouncing lasers off them. [Link to Wikipedia article]. Read up on how they work; their operation is relevant to total internal reflection and prisms in O&A-level physics.
This particular reflector was near a bar named "The Colonial" above Little India Station on the underground NEL line. They can also be found on almost all the pillars that support the elevated sections of old East-west and North-south MRT lines.
The coolest thing about these reflectors is that the Apollo astronauts left a panel of them on the moon. [Link to Wikipedia Article] I really think it is ridiculous that anyone should doubt that men have been to the moon, especially when observatories around the world bounce lasers off those reflectors to measure the distance to the moon. Don't try using your laser pointers; the power needed to reach the moon is in the neighbourhood of a hundred watts, and even then, only a few photons get reflected by the corner reflectors and make it back to earth!
This particular reflector was near a bar named "The Colonial" above Little India Station on the underground NEL line. They can also be found on almost all the pillars that support the elevated sections of old East-west and North-south MRT lines.
The coolest thing about these reflectors is that the Apollo astronauts left a panel of them on the moon. [Link to Wikipedia Article] I really think it is ridiculous that anyone should doubt that men have been to the moon, especially when observatories around the world bounce lasers off those reflectors to measure the distance to the moon. Don't try using your laser pointers; the power needed to reach the moon is in the neighbourhood of a hundred watts, and even then, only a few photons get reflected by the corner reflectors and make it back to earth!
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