dna.png

Chapter 2 - Models Of Bonding & Structure

atom-symbol.png

Atom Symbol

Chapter 1 - Models Of The Particulate Nature Of Matter

globe-with-meridians.png

 Globe with Meridians

Chapter 3 - Classification Of Matter

fire.png

Fire

Chapter 4 - What Drives Chemical Reactions?

rocket.png

Rocket

Chapter 5 - How Much, How Fast & How Far?

test-tube.png

Test Tube

Chapter 6 - What Are The Mechanisms Of Chemical Change?

Imagine you&#39;re in a race with your friend. Both of you start from the same spot. At the end of the race, you&#39;ve covered 8 meters while your friend, who was on a skateboard, zipped 10 meters. If we compare your distance to your skateboarding friend&#39;s, you covered 8/10 or 0.8 of the distance he did! In the world of chromatography, this is similar to the RF value.

RF = Distance travelled by the spot (let&#39;s call it b) / Distance travelled by the solvent (let&#39;s nickname it a).

RF = b/a

&nbsp;

Fun Fact: Since the spot is like the little sibling following its big brother, the solvent, it can&#39;t go farther than the solvent! That&#39;s why RF values are always between 0 (didn&#39;t move at all) and 1 (moved as far as the solvent did).

Just like how you might run slower in heavy rain or on a slope, the distance our little spot travels can change depending on:

<ul>
	<li>The Type of Solvent: It&#39;s like choosing between running in sneakers or flip-flops.</li>
	<li>Temperature: Imagine running on a hot summer day vs. a cool autumn evening.</li>
	<li>pH: This can affect the spot&#39;s mood. Think of running on a full stomach vs. an empty one.</li>
	<li>Type of Paper (in Paper Chromatography): Some papers are like running on grass, others feel like sand!</li>
</ul>

Remember those times you compared your handwriting to see if it matches with the mystery note writer? RF values are a bit like that! By comparing the RF values of unknown substances with the known ones (under the SAME conditions), we can identify them. Like a detective&#39;s secret tool!

Textbooks show chromatograms as clear, distinct spots. But when you try it, sometimes it&#39;s a beautiful blend of colors, like a sunrise! Want more distinct colors? Play around with different solvents. It&#39;s like using different Instagram filters on the same picture.

&nbsp;

Real-World Example: Imagine detectives trying to find out the ink used in a ransom note. They can use chromatography to separate the inks and then compare the RF values with known inks to identify the exact one used!

&nbsp;

In a nutshell: Chromatography is like a fun race where substances race at different speeds, and RF values are their unique &#39;fingerprints&#39; to identify them. 🏁🔍

Unlock Chromatography Success: Decipher RF Values!

ib-standard-level.webp

Standard Level

Chemistry SL

Chapter 2 - Models Of Bonding & Structure

Unlock Chromatography Success: Decipher RF Values!

Table of content

What's this 'retardation factor' or RF?🚗

The math behind RF📏

Factors affecting our racing spots🌡

Unlock the Full Content!

Chapter 2 - Models Of Bonding & Structure

Unlock Chromatography Success: Decipher RF Values!

Table of content

What's this 'retardation factor' or RF?🚗

The math behind RF📏

Factors affecting our racing spots🌡

Unlock the Full Content!