Comments on: What Makes A Good Nucleophile? https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/ Tue, 16 Apr 2024 18:35:48 +0000 hourly 1 https://wordpress.org/?v=6.6.2 By: What Makes A Good Nucleophile? | Straight A Mindset https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-679068 Thu, 07 Dec 2023 22:33:09 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-679068 […] Electronegativity: Across The Periodic Table, Nucleophilicity Increases With Decreasing Electronegat… […]

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By: Rohan Khan https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-585248 Tue, 22 Sep 2020 09:23:36 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-585248 Dear Sir.
You are the best.
I love the way in which you explain these terms in correct order and sequence….starting from the very basic terms.
You have cleared, all my confusion.
Everyone can easily understand,as you have explained in very proper manner.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-571211 Thu, 21 Nov 2019 21:41:09 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-571211 In reply to Raj.

Cyanide ion is more nucleophilic, and the lone pair that is transferred is the carbon. Otherwise the result would have a positively charged nitrogen and a negatively charged carbon.

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By: Raj https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-571196 Thu, 21 Nov 2019 19:07:29 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-571196 This was life saving for me!
But, tell me which one has more nucleophilicity CN(-) or OH(-)…and which electron pair is actually transferred in CN(-)..that of carbon or nitrogen?

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-564438 Wed, 18 Sep 2019 20:55:46 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-564438 In reply to karthika.

I think you mean hydride source? The isopropyl C-H bond is weaker.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-564378 Wed, 18 Sep 2019 16:15:23 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-564378 In reply to Hosni Elwan.

Hydroxide ion – it is a stronger base.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-563980 Fri, 13 Sep 2019 17:08:53 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-563980 In reply to AAKASH.

Which will be a stronger base? Can you find a pKa table to give you the values for H2O and CH3OH? That will tell you which will be a stronger base, since the weaker the acid, the stronger the conjugate base.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-563962 Fri, 13 Sep 2019 16:25:56 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-563962 In reply to piku singh.

1. Charged species generally more nucleophilic than neutral species (“the conjugate base is always a stronger nucleophile”).
2. The more basic a species is, generally, the more nucleophilic it is. Lots of exceptions, but not within the series you mention here.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-563252 Thu, 05 Sep 2019 18:09:30 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-563252 In reply to arun.

If one follows the same logic that the higher one goes on the periodic table, the more it will hydrogen-bond, then (CH3)3P will be more nucleophilic than (CH3)3N in polar protic solvents, and (CH3)3N will be more nucleophilic in polar aprotic solvents.

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By: James Ashenhurst https://www.masterorganicchemistry.com/2012/06/18/what-makes-a-good-nucleophile/#comment-563249 Thu, 05 Sep 2019 18:04:01 +0000 https://www.masterorganicchemistry.com/?p=5257#comment-563249 In reply to Varun.

In polar protic solvents, the order of nucleophilicity will be I- > Br- > Cl- > F- . This reflects the extent of hydrogen bonding around each ion (I- least, F- most). In polar aprotic solvents, the order reverses: F- > Cl > Br- > I- , since hydrogen bonding is not a factor, and F- tends to be more basic, as well as forms stronger bonds.

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