Uncertainty In Measurement

In chemistry, most of the time, we come across both, theoretical as well as experimental calculations. There are many methods which can help in handling these numbers conveniently and with minimal uncertainty.

Uncertainty-In-Measurement

Scientific Notation:

Atoms and molecules have extremely low masses, but they are present in large numbers.

Chemists deal with the figures which are as large as 602,200,000,000,000,000,000,000, which is the number of molecules of 2g of hydrogen.

They also have to deal with numbers as small as 0.00000000000000000000000166g, the mass of a Hydrogen atom.

There are even other constants like the speed of light, and charges on particles which have numbers above these stated magnitudes. It is written as ‘SCI’ display mode in scientific calculators.

To help us in handling these numbers we use the following notation: m × 10n, which is, m times ten raised to the power of n. In this n is an exponent having positive and negative values and m is that number which varies from .000… and 9.999…

The scientific notation 578.677 can be written as 5.78677 × 102. In this, the decimal has to be moved left by two places and if it is moved three places left then the power of 10 will be 3.

In the same way, 0.000089 can also be written as 8.9 × 10-5. In this, the decimal is moved five places towards the right, (-5) is the exponent in the scientific notation.

This helps us to attain easier handling, better precision and accuracy while performing operations on numbers with high magnitudes.

Uncertainty in Measurement

Uncertainty in Multiplication and Division:

The same rules can be applied for multiplication and division as well.

For e.g: (3.9 × 106) × (2.1 × 105) = (3.9 × 2.1)(106+5)

= (3.9 × 2.1) × (1011)

= 11.31 × 1011

In the case of division,

\(\begin{array}{l}\frac{3.6~×~10^{-5}}{2.0~×~10^{-4}}\end{array} \)

\(\begin{array}{l}=(3.6~ ÷~2.0)(10^{-5-(-4)})\end{array} \)

= 1.8 ×10-1

Uncertainty in Addition and subtraction:

In these operations first of all we have to place these numbers in such a way that they have the same exponents.

Therefore, when we add 5.43 × 104 and 3.45 × 103, the powers are made equal and after that, the coefficients are added and subtracted.

For example: 5.43 × 104 + 0.345 × 105 = [5.43 + (0.345× 10)]× 104 = 8.88 × 104

In the case of subtraction,

5.43 × 104 – 0.345 × 105 = [5.43 – (0.345× 10)]× 104 = (5.43 – 3.45) × 104 = 1.98 × 104

To learn more on the topic, download BYJU’S – The Learning App.

Test Your Knowledge On Uncertainty In Measurement!

Comments

Leave a Comment Cancel reply

Your Mobile number and Email id will not be published.

*

*

  1. It’s really help me😊😊☺

close
close

Play

&

Win