For more details, check this page on photosynthesis: http://click4biology.info/c4b/3/Chem3.8.htm
(I will eventually get around to writing more about photosynthesis on this website).

Other Important Points

Here are some extra notes about photosynthesis that could come in handy when discussing your results and writing your conclusion and evaluation sections.

• Plants carry out respiration (the opposite of photosynthesis!) the entire time to make energy, and so they constantly USE oxygen and MAKE carbon dioxide (which lowers the pH). At low photosynthesis rates (e.g. in the dark), they are respiring but not photosynthesizing. You will only start to see bubbles or pH changes when the rate of photosynthesis is higher than the rate of respiration.
• Having different number of leaves or mass of the plant cutting will affect your results. More leaves mean more photosynthesis! Also, they should all be healthy cuttings.
• Remember to take your measurements only after a few minutes of exposing your plant to light so that it will be photosynthesizing at a constant rate. Similarly, be careful not to expose all your plant cuttings to light while running an experiment on one of them!
• If you are using a pH probe, it needs to be properly calibrated before starting your experiments. If you are not able to do this, just remember that it might be a source of error…

Try to make a list of all the things you will need to run the experiment. Think about what you need to keep constant. You should also have a control experiment where photosynthesis won’t happen (no source of light or carbon dioxide, or a dead plant, for example).

Related posts:

1. Photosynthesis Lab
2. Photosynthesis Lab: What to Measure?
3. Photosynthesis Lab: Set Up

Now, how would you measure the rate of photosynthesis?

Again, let’s look at the equation for photosynthesis:

CO₂ + H₂O + light –> O₂ + glucose

There are 2 things we can quickly measure in this experiment (the dependent variables): amount of oxygen produced, or, amount of carbon dioxide used.

If the rate of photosynthesis increases, the rate of oxygen production goes up, and the rate of CO₂ consumption rises too! If the rate of photosynthesis goes down, then we can expect the opposite effect: oxygen production drops and carbon dioxide is not used as quickly.

But how can we measure oxygen or carbon dioxide levels?

It’s quite easy with Elodea!

Measuring Oxygen

In water, oxygen that is produced by the Elodea cutting is released as bubbles from its leaves. The rate of oxygen produced can be measured by either counting the number of bubbles released in a certain amount of time (bubbles/min), or by trapping the oxygen gas in an inverted syringe or tube and measuring the volume of oxygen produced in a certain amount of time (cm³/min).

It’s important that you give the plant a few minutes to photosynthesize before starting your measurements. This ensures that the plant is making oxygen at a constant rate. (You should also check this visually, before starting to count the bubbles). To have more accurate results, take the measurement at least 3 times. You could also vary the amount of time used to count the bubbles (10 seconds, 30 seconds, 1 minute). Then calculate the number of bubbles per minute or per second.

Measuring Carbon Dioxide

To measure carbon dioxide levels, we can measure the pH of the water. This is because when carbon dioxide dissolves in water, it forms carbonic acid and lowers the water pH. Therefore, in the opposite situation — i.e. when carbon dioxide is used — the pH goes up.

CO₂ + H₂O –> H₂CO₃ <–> H⁺ + HCO^3-

pH probe by Sergei Golyshev (http://www.flickr.com/photos/29225114@N08/)

As the changes in pH are probably quite small, it would be necessary to use a pH meter (or pH probe) with a digital readout. pH paper may not be sensitive enough to detect the changes. Measure the pH once before starting the experiment. Then, start taking pH measurements after the plant is consistently producing oxygen bubbles. Take a few measurements at 5 minute intervals (for example, you can run the experiment for 15 minutes and that would give you 3 readings).

Remember to rinse the pH probe with distilled water before transferring it to your test tube. You should also make sure that the test tube water is well-mixed before taking your measurement, by stirring with a glass rod, or inverting the tube a few times (make sure you use a rubber stopper so you don’t spill it all!).

Another important note: make sure you use really clean test tubes, plants and stoppers! Any contaminants could affect your pH reading. Rinse everything with tap water before you start your experiment!

Related posts:

1. Photosynthesis Lab: What to Expect
2. Photosynthesis Lab: Set Up
3. Photosynthesis Lab

Photo of Elodea plant by Kristian Peters (http://www.flickr.com/photos/fabelfroh/)

A commonly-used plant for such experiments is the Elodea, an aquatic (underwater) plant also referred to as pondweed. You can buy this at aquarium stores.

The set up depends on which question you would like to study.

In general, the plant is placed in a test tube filled with diluted sodium bicarbonate solution (1%). Sodium bicarbonate (baking soda) gives the plant a source of carbon dioxide so that they photosynthesize more quickly.

You need to provide the plant with a fixed light source (a light bulb, for example). You could place a large beaker (around 2 liters) filled with water between the light source and the test tube so that the light heats up only the beaker water and not the plant!

For your experiment, you should change only ONE variable, never more than that (if you can help it!).

Light Intensity

Take the case of investigating the effects of light intensity on photosynthesis rates. To change this, you can either use different wattage light bulbs, add screens between the light bulb and the plant, or change the distance of the light bulb from the plant. If you want to be really accurate, get a light meter and measure the light intensities that the plant is receiving with the different settings.

from The Biology Web (http://faculty.clintoncc.suny.edu/faculty/michael.gregory/)

Carbon Dioxide

To change carbon dioxide levels, just change the concentration of sodium bicarbonate in the solution (e.g. 0.5%, 1%, 1.5%, 2%).

Temperature

To change the temperature, you could warm the plant/test tube gently using a water bath method, i.e. place the test tube containing the plant in another large beaker which is filled with cool or warm water of known temperature. Place a thermometer in the test tube so that you know when the set temperature has been reached, and to make sure that it doesn’t change too much during the experiment.

Related posts:

1. Photosynthesis Lab
2. Photosynthesis Lab: What to Measure?
3. Photosynthesis Lab: What to Expect

Remember that the simple equation for photosynthesis is:

CO₂ + H₂O + light –> O₂ + glucose

Photo of Elodea plant by Kristian Peters (http://www.flickr.com/photos/fabelfroh/)

There are many questions you can ask about photosynthesis, such as:

• Does light intensity affect the rate of photosynthesis?
• Does temperature affect the rate?
• What about levels of carbon dioxide made available to the plant?

For your experiment, you can change what you provide the plant with (the independent variable) and see how this affects their ability to photosynthesize.

Read more about setting up your experiment, what variables you can measure, and what you should expect and look out for.

Hope the explanations here will help you write and plan your next lab report!

Feel free to send me more comments, suggestions and feedback!

Related posts:

1. Photosynthesis Lab: Set Up
2. Photosynthesis Lab: What to Expect
3. Photosynthesis Lab: What to Measure?

Gas collected is able to relight a glowing splint (light a wooden splint, blow it out and then insert it quickly into the gas chamber)

Test for carbon dioxide :

1. Bubbling carbon dioxide through lime water (calcium hydroxide) makes it cloudy due to solid precipitates of calcium carbonate.
   Ca(OH)₂ (aq) + CO₂ (g) –> CaCO₃ (s) + H₂O (aq)
2. Putting a lit splint into the gas collection chamber will put out the fire, as CO2 does not support combustion.
3. Dissolved carbon dioxide lowers the pH of a solution. Carbon dioxide reacts with water to form carbonic acid.
   CO₂ (g) + H₂O (aq) <==> H₂CO₃ (aq)

Test for nitrogen :

Nitrogen is extremely neutral and there does not change the color of moist litmus or indicator paper, neither does it have color or smell. It is also non-combustible and will put out a lit splint.

Test for hydrogen:

Burns with a ‘pop’ sound – which is actually a small explosion as hydrogen is extremely flammable!

Test for chlorine gas :

1. It is green-yellow in color, and smells pungent.
2. It turns moist litmus/universal indicator paper red, then white.
3. Since it is not combustible, it puts out a lit splint just like carbon dioxide.

To absorb carbon dioxide :

Place a strong alkaline/base in solid form (pellets, flakes) such as sodium hydroxide (NaOH), potassium hydroxide (KOH) or lithium hydroxide (LiOH) to absorb carbon dioxide.

Related posts:

1. Photosynthesis Lab: What to Measure?
2. Photosynthesis Lab: Set Up
3. Photosynthesis Lab