Imperial College London

Henry Rzepa

A few posts back, I explored the "[benzidine
rearrangement](http://www.ch.imperial.ac.uk/rzepa/blog/?p=8961){target="_blank"}"
of diphenyl hydrazine. This reaction requires diprotonation to proceed
readily, but [we then
discovered](http://www.ch.imperial.ac.uk/rzepa/blog/?p=9135){target="_blank"}
that replacing one NH by an O as in N,O-diphenyl hydroxylamine required
only monoprotonation to undergo an equivalent facile rearrangement. So
replacing both NHs by O to form diphenyl peroxide (Ph-O-O-Ph) completes
this homologous series. I had
[speculated](http://www.ch.imperial.ac.uk/rzepa/blog/?p=9135){target="_blank"}
that PhNHOPh might exist if all traces of catalytic acid were removed,
but could the same be done to PhOOPh? Not if it continues the trend and
requires no prior protonation at all!

![PhOOPh](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/04/PhOOPh.svg){.aligncenter
.size-full .wp-image-10253 decoding="async"}

Here is the results of a ωB97XD/6-311G(d,p)/SCRF=water calculation. Now
I should explain that the conventional explanation for the non-existence
of PhOOPh is that the O-O bond homolyses very readily to form phenoxy
radicals\[cite\]10.1002/jcc.540140402\[/cite\]. But of course other
peroxides such as t-Bu-O-O-t-Bu do exist (although they are rather
fragile) and so the phenyl analogue is clearly special.

|                                                                                                                                                                   |                                                                                                                                                                     |
|-------------------------------------------------------------------------------------------------------------------------------------------------------------------|---------------------------------------------------------------------------------------------------------------------------------------------------------------------|
| ![PhOOPh](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/04/PhOOPh.gif){.aligncenter .size-full .wp-image-10256 decoding="async" width="220"}    | ![PhOOPha1](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/04/PhOOPha1.gif){.aligncenter .size-full .wp-image-10255 decoding="async" width="220"}  |
|  ![PhOOPh2](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/04/PhOOPh2.svg){.aligncenter .size-full .wp-image-10259 decoding="async" width="220"} | ![PhOOPha1](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/04/PhOOPha1.svg){.aligncenter .size-full .wp-image-10258 decoding="async" width="220"}  |

You will notice from the IRC profiles shown above that even without any
prior protonation, the barrier to O-O cleavage is really very small (\~
4 kcal/mol). But the method I have used to calculate this is a closed
shell DFT procedure. This does not allow the formation of the (open
shell) biradical that two phenoxy radicals would represent. The barrier
is low even without the formation of phenoxy radicals! Of course, as
with the two previous examples, the actual initial product formed is
the π-complex as first suggested by Michael Dewar. The wavefunction of
such a species requires special treatment, since it is [best
described](http://www.ch.imperial.ac.uk/rzepa/blog/?p=9271){target="_blank"}
as a linear combination of two closed-shell configurations, what is
called a multi-configuration or multi-reference wavefunction.^‡^ So the
single-configuration closed shell calculation that the above IRC
represents must be an upper bound to a proper description of the energy
transition state. In other words, if the description is improved, the
barrier can only get even lower! 

Notice in the above that the π-complex formed in the first stage (of
two) is actually lower in energy than the diphenyl peroxide itself, and
that the barrier for this π-complex to then collapse to form the C-C
bond between the two 4-positions is also tiny. This π-complex in other
words is very transient indeed, probably not surviving for even one
molecular vibration. To all intents and purposes, this really is a
concerted \[5,5\] sigmatropic shift, as shown in the schematic at the
top of this post. But the bottom line is that the homolysis argument
need not be the only one (although it  is not necessarily incorrect).
One can just as readily explain why PhOOPh does not exist by invoking
facile formation of Dewar-like π-complex instead.

------------------------------------------------------------------------

^‡^ Another deceptively simple little molecule that requires such a
treatment is C~2~, the topic of much recent
debate\![cite\]10.1002/anie.201208206\[/cite\],
\[cite\]10.1063/1.4802585\[/cite\]

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rel="author"}
:::


A few posts back, I explored the “benzidine rearrangement” of diphenyl hydrazine. This reaction requires diprotonation to proceed readily, but we then discovered that replacing one NH by an O as in N,O-diphenyl hydroxylamine required only monoprotonation to undergo an equivalent facile rearrangement. So replacing both NHs by O to form diphenyl peroxide (Ph-O-O-Ph) completes this homologous series.

Why diphenyl peroxide does not exist.

The transient π-complex formed during the "\[5,5\]" sigmatropic
rearrangement of protonated N,O-diphenyl hydroxylamine can be (formally)
represented as below, namely the interaction of a six-π-electron
aromatic ring (the phenoxide anion **2**) with a four-π-electron phenyl
dication-anion pair **1**. Can one analyse this interaction in terms of
aromaticity?

![pi-complex1](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-complex1.svg){.aligncenter
.size-full .wp-image-9220 decoding="async" width="420"}

I [showed
previously](http://www.ch.imperial.ac.uk/rzepa/blog/?p=9186){target="_blank"}
that the interaction between these two components involves the
stabilising overlap (donation) of a filled orbital on **2** with an
empty (acceptor) orbital on the dication-anion pair **1**. So what does
the interaction of a six-electron (and hence 4n+2 Hückel aromatic) donor
ring with a four-electron (and hence formally a Hückel anti-aromatic)
acceptor ring lead to? To find out, I carried out a QTAIM analysis of
the ring- and bond-critical points in the topology of the computed
electron density of complex, and then evaluated the NICS
(nucleus-independent-chemical shift) NMR probe at these points. First,
the QTAIM analysis. Green=bond critical points, red=ring and blue=cage.

![pi-QTAIM](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-QTAIM.jpg){.aligncenter
.wp-image-9222 loading="lazy" decoding="async" width="360" height="250"}

The [NMR
analysis](http://hdl.handle.net/10.6084/m9.figshare.107066){target="_blank"}
(ωB97XD/6-311G(d,p)/SCRF=water) is shown below. This is for a closed
shell wavefunction, which does not include contributions from any open
shell biradical singlet.

::: {#attachment_9224 .wp-caption .aligncenter style="width: 369px"}
![Click for
3D.](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-NMR1.jpg){.wp-image-9224
loading="lazy" decoding="async"
aria-describedby="caption-attachment-9224"
onclick="jmolInitialize('../Jmol/');jmolSetAppletColor('white');jmolApplet([450,450],'load wp-content/uploads/2013/01/pi-NMR.mol2;set fontscaling TRUE; font label 18;select atomno=35;label %A 1=-0.9;select atomno=29;label %A 2=-5.9;select atomno=33;label %A 3=-14.0;select atomno=31;label %A 4=-17.1;select atomno=32;label %A 5=-12.1;select atomno=34;label %A 6=-13.2;select atomno=30;label %A 7=-15.7;');"
width="359" height="313"}

Click for 3D.
:::

1.  This is the ring centroid of the phenoxide anion **2**, and would
    normally be expected to show a highly diatropic NICS value
    indicative of ring aromaticity. The value computed for the complex
    is -0.9 ppm, which is not aromatic!
2.  This is the ring centroid of the (nominally) antiaromatic **1**, and
    has a value of -5.9 (mildly aromatic; benzene itself on this scale
    is about -10 ppm). Neither ring is behaving as might be indicated
    they should prior to their forming the π-complex.
3.  The remaining points all lie in plane between the two rings; they
    are unique to the π-complex itself. Point \# 3 has a NICS of -14.0
    ppm; it is \~located at the centroid of the C=O and C=N bonds.
4.  This point has NICS -17.1 ppm, being the most highly diatropic of
    the seven computed.
5.  This, -12.1, and
6.  the next -13.2 are ring points lying between the 3,3′ carbons of
    either ring.
7.  This point is the (defining) centroid of the whole complex and has
    NICS -15.7 ppm.

This reveals that neither individual ring of the complex sustains a a
diatropic ring current, but that the region between the two rings, one
that defines the π-complex itself, is very highly diatropic. The most
simple way of looking at it is that the two rings coming together has
created an aromatic complex (I remind again that this is in the
closed-shell picture of this system, allowing partial biradical
character may influence this). To illustrate this holistic aspect, I
show below the most stable of the π-MOs (this MO in fact resembles to
remarkable degree the lowest π-MO of
[ferrocene](http://hdl.handle.net/10042/to-8269){target="_blank"}  which
can be used to illustrate the [18-electron filled
shells](http://www.ch.imperial.ac.uk/rzepa/blog/?p=3908){target="_blank"}
of the iron at the centre).  in fact this is one of seven π-MOs that can
be
[identified](http://hdl.handle.net/10.6084/m9.figshare.106811){target="_blank"},
making the system a **14** (certainly 10)-π-electron aromatic (the extra
electrons come from the oxygen of **2** and the C=N region of **1**).

::: {#attachment_9234 .wp-caption .aligncenter style="width: 290px"}
![Click for
3D.](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-MO.jpg){.wp-image-9234
loading="lazy" decoding="async"
aria-describedby="caption-attachment-9234"
onclick="jmolInitialize('../Jmol/');jmolSetAppletColor('white');jmolApplet([450,450],'load wp-content/uploads/2013/01/benzidine-pi_mo39.cub.xyz;isosurface wp-content/uploads/2013/01/benzidine-pi_mo39.cub.jvxl translucent;');"
width="280" height="193"}

Click for 3D.
:::

It is most amusing (which is how Michael Dewar might have stated it)
that such an unpretentious molecule as PhNHOPh could reveal such
surprises. It is also noteworthy that Dewar championed the concept of
using aromaticity to determine selection rules for pericyclic reactions,
and so he would perhaps have appreciated that the π-complex he suggested
for the benzidine pericyclic rearrangement might have its own unique
aromatic character.

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rel="author"}
:::


The transient π-complex formed during the “[5,5]” sigmatropic rearrangement of protonated N,O-diphenyl hydroxylamine can be (formally) represented as below, namely the interaction of a six-π-electron aromatic ring (the phenoxide anion
<strong>
 2
</strong>
) with a four-π-electron phenyl dication-anion pair
<strong>
 1
</strong>
. Can one analyse this interaction in terms of aromaticity?

Aromaticity in the benzidine-like π-complex formed from PhNHOPh.

Michael Dewar\[cite\]10.1016/S0040-4039(01)82765-9\[/cite\] famously
implicated a so-called π-complex in the benzidine rearrangement, back in
the days when quantum mechanical calculations could not yet provide a
quantitatively accurate reality check. Because this π-complex actually
remains a relatively unusual species to encounter in day-to-day
chemistry, I thought I would try to show in a simple way how it forms.

![pi-complex](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-complex.svg){.aligncenter
.size-full .wp-image-9188 decoding="async" width="400"}

I am actually illustrating it with the benzidine rearrangement of
monoprotonated PhNHOPh, which I dealt with in the [previous
post](http://www.ch.imperial.ac.uk/rzepa/blog/?p=9135){target="_blank"
rel="noopener"}, if only because the energy of this π-complex relative
to monoprotonated PhNHOPh is amazingly low (in other words, it is not
one of these high energy molecules which only exist in the virtual world
of computational modelling). The mechanism can be conceptually broken
down to considering how the N-O bond can be cleaved in one of three
ways. Route A is the homolytic route to give a 4-biradical (in one of
the possible resonance forms), which of course can couple to form a
4,4′-biphenyl. Route B is a heterolytic route in which the two electrons
from the N-O σ-bond are retained by **1**, whilst for route C this
electron pair is retained by **4**.

These two fragments can then interact in several ways to form
the π-complex.  Here I will illustrate just the two closed shell options
(B/C), whilst recognising that there may also be contribution from the
open shell biradical (in water as solvent, the two ionic configurations
are clearly going to be stabilised by solvation and so may contribute
relatively more than the non-polar radical-pair ).

1.  Route B (green), overlapping the HOMO of **1** with the LUMO of
    **2** to create a new π-MO** **to be occupied by the two electrons
    extracted from the N-O σ-bond (a similar promotion of a σ- to a
    π-pair was [noted in this
    post](http://www.ch.imperial.ac.uk/rzepa/blog/?p=7258){target="_blank"
    rel="noopener"}).
2.  Route C (red), overlapping the HOMO of **4** with the LUMO of **3**
    to achieve the same result.

<table class="aligncenter" data-border="1" data-align="center">
<colgroup>
<col style="width: 50%" />
<col style="width: 50%" />
</colgroup>
<tbody>
<tr class="header">
<th colspan="2">Route B</th>
</tr>
&#10;<tr class="odd">
<td><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 220px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/N-LUMO.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/N+LUMO-.20174_mo34.cub.xyz;isosurface color red green wp-content/uploads/2013/01/N+LUMO-.20174_mo34.cub.jvxl translucent;&#39;);"
width="210" alt="HOMO for 5,5 benzidine rearrangement. Click for 3D." />
<p>LUMO of 2. Click for 3D.</p>
</div></td>
<td rowspan="2"><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 240px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-complex.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/NH2O-pi_mo58.cub.xyz;isosurface color red green wp-content/uploads/2013/01/NH2O-pi_mo58.cub.jvxl translucent;&#39;);"
width="230" alt="HOMO for 5,5 benzidine rearrangement. Click for 3D." />
<p>HOMO for π-complex. Click for 3D.</p>
</div></td>
</tr>
<tr class="even">
<td><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 220px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/O-HOMO.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/O-HOMO-.22278_mo25.cub.xyz;isosurface color red green wp-content/uploads/2013/01/O-HOMO-.22278_mo25.cub.jvxl translucent;&#39;);"
width="210" alt="HOMO for π-complex. Click for 3D." />
<p>HOMO of 1. Click for 3D.</p>
</div></td>
</tr>
<tr class="odd">
<td colspan="2">Route C</td>
</tr>
<tr class="even">
<td><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 220px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/O-LUMO.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/O+LUMO-.16695_mo25.cub.xyz;isosurface color red green wp-content/uploads/2013/01/O+LUMO-.16695_mo25.cub.jvxl translucent;&#39;);"
width="210" alt="HOMO for 5,5 benzidine rearrangement. Click for 3D." />
<p>LUMO of 3. Click for 3D.</p>
</div></td>
<td rowspan="2"><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 240px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/pi-complex1.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/NH2O-pi_mo58.cub.xyz;isosurface color red green wp-content/uploads/2013/01/NH2O-pi_mo58.cub.jvxl translucent;&#39;);"
width="230" alt="HOMO for 5,5 benzidine rearrangement. Click for 3D." />
<p>HOMO for π-complex. Click for 3D.</p>
</div></td>
</tr>
<tr class="odd">
<td><div id="attachment_8986" class="wp-caption aligncenter"
style="width: 220px">
<img
src="http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/N-HOMO.jpg"
class="wp-image-8986" decoding="async"
aria-describedby="caption-attachment-8986"
onclick="jmolInitialize(&#39;../Jmol/&#39;);jmolSetAppletColor(&#39;white&#39;);jmolApplet([450,450],&#39;load wp-content/uploads/2013/01/N-HOMO-.25844_mo34.cub.xyz;isosurface color red green wp-content/uploads/2013/01/O-HOMO-.22278_mo25.cub.jvxl translucent;&#39;);"
width="210" alt="HOMO for π-complex. Click for 3D." />
<p>HOMO of 4. Click for 3D.</p>
</div></td>
</tr>
</tbody>
</table>

The relative weight of these two combinations is largely determined by
the difference in energies between the two HOMO/LUMO pairs and their
overlap. ΔE is different for the two combinations, being 0.021 Hartree
(route B) and 0.091 (route C), with lower being better.

The overlap of the HOMO/LUMO (in either orbital combination) is almost
perfect for the face-to-face π-stacking of the complex. Note that
this π-π-stacked arrangement in effect returns some electrons to the N-O
region, in what is now called σ-π conjugation, and which used to be
called hyperconjugation (it also resembles the [conjugation of a Si-C
bond with a phenyl
ring](http://www.ch.imperial.ac.uk/rzepa/blog/?p=4967){target="_blank"
rel="noopener"} in the Wheland intermediate).

------------------------------------------------------------------------

#### Acknowledgments

This post has been cross-posted in PDF format at
[Authorea](https://doi.org/10.15200/winn.142478.85242){rel="noopener"
target="_blank"}.

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rel="author"}
:::


Michael Dewar[cite]10.1016/S0040-4039(01)82765-9[/cite] famously implicated a so-called π-complex in the benzidine rearrangement, back in the days when quantum mechanical calculations could not yet provide a quantitatively accurate reality check. Because this π-complex actually remains a relatively unusual species to encounter in day-to-day chemistry, I thought I would try to show in a simple way how it forms.

The π-complex in the benzidine rearrangement: a molecular orbital analysis.

Kinetic isotope effects have become something of a lost art when it
comes to exploring reaction mechanisms. But in their heyday they were
absolutely critical for establishing the mechanism of the benzidine
rearrangement\[cite\]10.1021/ja00373a028\[/cite\]. This classic
mechanism proceeds *via* *bis*protonation of diphenyl hydrazine, but
what happens next was the crux. Does this species rearrange directly to
the C-C coupled intermediate (a concerted \[5,5\] sigmatropic reaction)
or does it instead form a π-complex, as famously first suggested by
Michael Dewar\[cite\]10.1016/S0040-4039(01)82765-9\[/cite\] \[via
TS(NN\] and only then in a second step \[via TS(CC)\] form the C-C bond?
Here I explore the isotope effects measured and calculated for this
exact system.

![benzidine-KIE](http://www.ch.imperial.ac.uk/rzepa/blog/wp-content/uploads/2013/01/benzidine-KIE.svg){.aligncenter
.size-full .wp-image-9107 decoding="async" width="420"}

It boils down to the following. It was supposed that if the mechanism
was a concerted \[5,5\] sigmatropic shift, then both the N-N and the C-C
bonds would be breaking/forming at the transition state and both N and C
isotope effects would be expected. However, if a π-complex were formed,
then either TS(NN) OR TS(CC) would be the rate determining step, and so
either a NN OR a CC isotope effect should manifest, but not BOTH. The
experiment carried out by Henry Shine and colleagues was thus expected
to be the definitive one.\[cite\]10.1021/ja00065a018\[/cite\] The
results (in aqueous ethanol, at 273K) revealed the following:
k(^2^H/^1^H) = 0.962, k(^14^C/^12^C)^‡^ = 1.013, k(^13^C/^13^C) = 1.013,
k(^15^N/^14^N) = 1.041. This might have appeared to prove conclusively
that the reaction was concerted, involving both the C-C and N-N bonds;
in other words a \[5,5\] sigmatropic rearrangement.

The quantum mechanical (closed shell) surface reveals only two separate
transition states, TS(NN) and TS(CC), and so at first sight seems to
contradict the experimental isotope inference. But the experimental
values are very unlikely to be wrong. So how can one reconcile these two
methods? Well, the answer is not to give up, but to calculate the
isotope effects for BOTH transition states, and see if either of them
matches the experimental result. Here are these calculations:

|      |              |                |                |                |
|------|--------------|----------------|----------------|----------------|
| TS   | k(^2^H/^1^H) | k(^14^C/^12^C) | k(^13^C/^13^C) | k(^15^N/^14^N) |
| CC   |  0.946       |  1.050         |  1.050         |  1.032         |
| NN   |  1.002       |  1.008         |  1.007         |  1.075         |
| Expt |  0.962       |  1.013         |  1.013         |  1.041         |

The match between experiment and theory for TS(CC) is reasonable (given
the approximations in both the theory and the difficulty of the
experiments and ensuring isotopic purities) but not so for TS(NN). But
TS(CC) is a "stepwise-concerted" reaction as a closed shell singlet; as
shown in the [ IRC computed from
TS(CC](http://www.ch.imperial.ac.uk/rzepa/blog/?p=8961){target="_blank"}). 

Yamabe and co\[cite\]10.1039/b909313c\[/cite\] have come to similar
conclusions (their model used a dication rather than an ion-pair). In
the latest twist, Ghigo *et
al*\[cite\]10.1016/j.tet.2012.01.014\[/cite\] used the same model as
here (HCl to provide protonation as an ion-pair) but identified
biradical (radical-cation) character at the transition state. The latter
group also calculated kinetic isotope
effects\[cite\]10.1002/ejoc.201001636\[/cite\] for the open shell
biradical TS, finding an even better match with experiment than above.

So this see-saw mechanism has oscillated between a stepwise π-complex,
then a direct \[5,5\] rearrangement and in more recent times using
computational modelling, a concerted \[5,5\] sigmatropic proceeding
*via* an initially formed π-complex, and (finally) *via* a multi-step
mechanism proceeding through a biradical π-complex and involving radical
coupling, which nevertheless appears to behave in some aspects as a
concerted \[5,5\] rearrangement. It is fascinating that a simple
diprotonation of a hydrazine could so readily induce biradical
character, and that such an apparently simple reaction could have so
many twists and turns!

------------------------------------------------------------------------

^‡^ For one ^14^C-^12^C pair.

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rel="author"}
:::


Kinetic isotope effects have become something of a lost art when it comes to exploring reaction mechanisms. But in their heyday they were absolutely critical for establishing the mechanism of the benzidine rearrangement[cite]10.1021/ja00373a028[/cite]. This classic mechanism proceeds
<em>
 via
</em>
<em>
 bis
</em>
protonation of diphenyl hydrazine, but what happens next was the crux.

Rogue Scholar Beiträge

Why diphenyl peroxide does not exist.

Aromaticity in the benzidine-like π-complex formed from PhNHOPh.

The π-complex in the benzidine rearrangement: a molecular orbital analysis.

The Benzidine rearrangement. Computed kinetic isotope effects.