Measuring Variables in Biology (DP IB Biology)
Revision Note
Measuring Variables in Biology
When measuring a variable in an experiment, it is important to use the most appropriate instrument and measuring technique to achieve the most accurate value for that measurement to an appropriate level of precise
Measuring mass
Mass is measured using a digital balance which normally gives readings to two decimal places
Balances must be tared (set to zero) before use, this indicates that the container or balance is empty before taking the measurement
The standard unit of mass is kilograms (kg) but in chemistry, grams (g) are most often used
1 kilogram = 1000 grams
Measuring volume of liquids
The most common units of measurement for volumes are cm3, dm3 or ml (millilitres) or l (litres)
The volume of a liquid can be determined using several types of apparatus, depending on the level of accuracy needed
For approximate volumes where high accuracy is not an important factor, measuring (or graduated) cylinders are used
These are graduated (have a scale so can be used to measure) and are available typically in a range of sizes from 10 cm3 to 1 litre (1 dm3)
Volumetric pipettes are the most accurate way of measuring a fixed volume of liquid, usually 10 cm3 or 25 cm3
They have a scratch mark on the neck which is matched to the bottom of the meniscus to make the measurement
Burettes are the most accurate way of measuring a variable volume of liquid between 0 cm3 and 50 cm3 (e.g. in a titration)
The tricky thing with burettes is to remember to read the scale from top to bottom as 0.00 cm3 is at the top of the column
Whichever apparatus you use, you may see markings in ml (millilitre) which is the same as a cm3
Burettes, measuring cylinders, pipette fillers and volumetric pipettes can be used to measure the volume of liquids
Measuring the volume of gases
The volume of a gas sometimes needs to be measured and is done by collecting it in a graduated measuring apparatus
A gas syringe is usually the apparatus used
A graduated measuring cylinder or burette inverted in water may also be used, provided the gas is not water-soluble
If the gas happens to be heavier than air and is coloured, the cylinder can be used upright
Gas syringes can be used to measure the volume of gas produced in a reaction
Measuring time
Time can be measured using a stopwatch or stop-clock which are usually accurate to one or two decimal places
The units of time normally used are seconds or minutes although other units may be used for extremely slow reactions (e.g. rusting)
1 minute = 60 seconds
An important factor when measuring time intervals is human reaction time
This can have a significant impact on measurements when the measurements involved are very short (less than a second)
Measuring temperature
Temperature is measured with a thermometer or digital probe
Laboratory thermometers usually have a precision of a half or one degree
Digital temperature probes are available which are more precise than traditional thermometers and can often read to 0.1 oC
Traditional thermometers rely upon the uniform expansion and contraction of a liquid substance with temperature; digital temperature probes can be just as, if not, more accurate than traditional thermometers
The units of temperature are degrees Celsius (ºC)
Measuring length
Rulers can be used to measure small distances of a few centimetres (cm).
They are able to measure to the nearest millimetre (mm)
The standard unit of length is metres (m)
Larger distances can be measured using a tape measure
Many distances in chemistry are on a much smaller scale, for example, a typical atomic radius is around 1 x 10-10 m, so cannot be measured in this way
When measuring length it is important to take note of the units that are being measured
1 cm is 10 mm
100 cm is 1 m
A ruler can measure distances to the nearest mm
Making counts
This often involves taking counts of cells, by counting the cells in a known volume of a culture, the concentration can be assessed
Direct counting methods of cells include microscopic counts using a hemocytometer or a counting chamber
A hemocytometer works by creating a volumetric grid divided into differently sized cubes for accurately counting the number of particles in a cube and calculating the concentration of the entire sample
Counting the number of cells in a culture can also be carried by a method known as a streak plate, this involves plating a known volume of the cell culture onto a petri dish with a growth medium
Direct counting methods do not require highly specialised equipment sp are easy to perform but they can be quite time consuming
Much of ecology involves counting organisms
Counting here can be difficult as many of organisms involved ma move, or are inconspicuous
Accurate counts are rare and so population sampling is carried out
Most counts are associated with errors due to the sizes of the populations or mistakes being made in detecting individuals or direct errors in counting such as large groups miscounted or individuals misidentified
Drawing annotated diagrams from observation
To record the observations seen under the microscope (or from photomicrographs taken) a labelled biological drawing is often made
Biological drawings are line pictures that show specific features that have been observed when the specimen was viewed
There are a number of rules/conventions that are followed when making a biological drawing
You can read in more detail the about drawing annotated diagrams from observations here
Making appropriate qualitative observations
Classifying organisms is an example of making qualitative observations
In qualitative classification, data can be classified based on attributes such as sex, colour of fur, number of limbs
The attribute being observed cannot be measured so it is classed as qualitative data
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