Draft:Fausto Calderazzo

Submission declined on 3 May 2024 by Ldm1954 (talk). This submission does not appear to be written in the formal tone expected of an encyclopedia article. Entries should be written from a neutral point of view, and should refer to a range of independent, reliable, published sources. Please rewrite your submission in a more encyclopedic format. Please make sure to avoid peacock terms that promote the subject. The content of this submission includes material that does not meet Wikipedia's minimum standard for inline citations. Please cite your sources using footnotes. For instructions on how to do this, please see Referencing for beginners. Thank you. If you would like to continue working on the submission, click on the "Edit" tab at the top of the window. If you have not resolved the issues listed above, your draft will be declined again and potentially deleted. If you need extra help, please ask us a question at the AfC Help Desk or get live help from experienced editors. Please do not remove reviewer comments or this notice until the submission is accepted. Where to get help If you need help editing or submitting your draft, please ask us a question at the AfC Help Desk or get live help from experienced editors. These venues are only for help with editing and the submission process, not to get reviews. If you need feedback on your draft, or if the review is taking a lot of time, you can try asking for help on the talk page of a relevant WikiProject. Some WikiProjects are more active than others so a speedy reply is not guaranteed. How to improve a draft Wikipedia:Contributing to Wikipedia – a basic overview on how to edit Wikipedia. Help:Wikitext – how to use the markup Help:Referencing for beginners – how to include references Wikipedia:Article development – how to develop your article Wikipedia:Writing better articles – how to improve your article Wikipedia:Verifiability – make sure your article includes reliable third-party sources You can also browse Wikipedia:Featured articles and Wikipedia:Good articles to find examples of Wikipedia's best writing on topics similar to your proposed article. Improving your odds of a speedy review To improve your odds of a faster review, tag your draft with relevant WikiProject tags using the button below. This will let reviewers know a new draft has been submitted in their area of interest. For instance, if you wrote about a female astronomer, you would want to add the Biography, Astronomy, and Women scientists tags. Add tags to your draft Editor resources Find sources: Google (books · news · scholar · free images · WP refs) · FENS · JSTOR · TWL Easy tools: Citation bot (help) | Advanced: Fix bare URLs Declined by Ldm1954 3 days ago. Last edited by Diegoriccio98 16 hours ago. Reviewer: Inform author. Resubmit Please note that if the issues are not fixed, the draft will be declined again.

Submission declined on 18 April 2024 by Xkalponik (talk). This submission does not appear to be written in the formal tone expected of an encyclopedia article. Entries should be written from a neutral point of view, and should refer to a range of independent, reliable, published sources. Please rewrite your submission in a more encyclopedic format. Please make sure to avoid peacock terms that promote the subject. The content of this submission includes material that does not meet Wikipedia's minimum standard for inline citations. Please cite your sources using footnotes. For instructions on how to do this, please see Referencing for beginners. Thank you. Declined by Xkalponik 18 days ago.

• Comment: You have to rewrite this so it confirms to the accepted standard for articles in Wikipedia -- look at some others. If you continue submitting and ignoring this advice the article will probably be deleted completely. Ldm1954 (talk) 12:32, 3 May 2024 (UTC)

---

Fausto Calderazzo
Calderazzo in 2004
Born	(1930-03-08)March 8, 1930 Parma, Italy
Died	June 1, 2014(2014-06-01) (aged 84) Pisa, Italy.
Nationality	Italian
Education	University of Florence (BS)
Awards	A. Miolati award (1988) L. Sacconi Medal (1998)
Scientific career
Fields	Inorganic Chemistry Organometallic Chemistry
Institutions	University of Pisa Polytechnic University of Milan

Fausto Calderazzo (March 8, 1930. Parma – June 1, 2014. Pisa) was an Italian inorganic chemist. His academic career ranges from synthesis to mechanistic studies and he is considered a significant pioneer in the field of organometallic chemistry, especially in carbonyl chemistry^[1] where, with the colleague Klaus Noack, he proved the mechanism of migratory insertion through the MnCH₃(CO)₅ carbonylation reaction.

Biography^[2]

Early Life and Higher Education

Fausto was born in Parma, on March 8^th 1930, where his father served in the Royal Italian army. He graduated in Chemistry from the University of Florence, in 1952. His research project about coordination compounds of Ni(II) was completed under the guidance of Luigi Sacconi, Assistant Professor of Physical Chemistry.

Career

After the compulsory military service, Calderazzo joined the research group of Professor Giulio Natta, Nobel laureate in 1963 with Karl Ziegler ("for their discoveries in the field of the chemistry and technology of high polymers")^[3], at the Institute of Industrial Chemistry in Polytechnic Institute of Milan. In this first employment he started to devote his work to the organometallic chemistry, and in particular, to the carbonyl derivates of transition elements.^[4]

In Milan Calderazzo established a collaboration with Giulio Natta, Raffaele Ercoli, Piero Pino and Paolo Chini. In 1959 they published the novel discovery of the first paramagnetic low-spin metal carbonyl: V(CO)₆ (figure 1).^[5] The discovery was the outcome in the attempting to find new metal-catalyzed routes to organic oxygenated compounds from available precursors and CO.

In 1960 Calderazzo accepted the offer of being a Sloan Fellow with Frank Albert Cotton at Massachusetts Institute of Technology (MIT) in Cambridge, MA, USA. At the end of the postdoctoral period, he come back to Milan where he continued the studies on the chemistry of V(CO)₆ and the carbonylation of MnCH₃(CO)₅, until 1963.

Figure 1. Crystallographic structure of V(CO)_6.

  Oxygen

  Carbon

  Vanadium

A large static Jahn–Teller distortion is present.^[6] Axial and equatorial V–C distances of 1.993 Å and 2.005 Å, respectively

At the end of 1963 Calderazzo moved to Switzerland to join the Inorganic Synthesis Group at the Cyanamid European Research Institute, founded in 1959, in Geneva. He was assigned Director of the group in 1965 and he held this position until 1968. In Geneva, using ¹³CO labeling, Calderazzo and Noack were able to demonstrate that the decisive carbon−carbon bond forming step, in carbonylation of MnCH₃(CO)₅, involves an insertion rather than simple migration, as had previously been supposed.^[7] Migratory insertion takes part in several industrial catalytic cycles, and this specific experiment is used as a classical didactic model.^[8][9] For instance, migratory insertion is considered to be a key-step in Roelen process for hydroformylation of ethylene^[10] or methanol carbonylation,^[11] catalyzed by [Co(CO)₄]₂ and [RhI₂(CO)₂]⁻, respectively.

Calderazzo returned to Italy as Full Professor at the Institute of General and Inorganic Chemistry of the University of Pisa in 1968. He also taught advanced courses of inorganic chemistry at the Scuola Normale Superiore of Pisa. In Pisa he carried on the experimental activity, funded by American and European industries (particularly ENI), in parallel with teaching role. During his scientific activity, Calderazzo extended his interest in carbonyl chemistry of the late transition metals like Pd, Pt^[12] and Au (figure 2)^[13] in addition to the investigations in the field of, so called, “non classical” carbonyl compounds.^[14][15]

Figure 2. Crystallographic structure of the mixed valence gold chloride Au₄Cl₈.

  Gold

  Chlorine

Since middle 1970s Calderazzo carried out research projects with his collaborators, involving carbon dioxide as a C1 synthon for organic synthesis. They synthesized N,N-dialkylcarbamato complexes of elements, from transition to lanthanide metals, using secondary amines, CO₂ and suitable precursors.^[16][17]

Calderazzo died in Pisa, on June 1, 2014, at the age of 84.

Awards and Titles

Calderazzo was a member of the editorial or advisor board of international scientific journals such as Organometallics, Inorganic Chemistry, Dalton Transactions and Journal of Organometallic Chemistry. Furthermore, he was a member of international conference committees like the International Conferences on Organometallic Chemistry ICOMC, member of the Société Royale de Chemie (1987), Società Chimica Italiana and Accademia Nazionale dei Lincei (1989). He received the A. Miolati award in Inorganic Chemistry in 1988 and the L. Sacconi Medal in 1998.

Works

On Migratory Insertion

The equilibrium and the rates of the forward and reverse reactions in the system ${\displaystyle {\ce {[MnCH3(CO)5] + CO <=> [Mn(CO)CH3(CO)5]}}}$ were studied at atmospheric pressure of CO in various solvents and at several temperatures by Calderazzo and Cotton in 1961.^[18] The reaction proved to be first order in both MnCH₃(CO)₅ and CO and the effect of changing the solvent appeared to be mainly a function of the dielectric constant in stabilizing a somewhat polar transition state. The volume of CO absorbed or evolved at a given time was determined by gas-volumetric measurements. A scheme of the burette used for the experiments is shown in the figure 3. Once the volume of CO was measured, it was converted to moles of CO and the CO/Mn mole ratio was determined. By measuring the amount of CO absorbed as a function of time, it was possible to study the kinetics of the carbonylation reaction.

Figure 3. Gas-volumetric burette: A marks the 100 mL burette; B the Hg containing bulb; C the capillary tube connected to atmosphere; D the three-way stopcock (CO flux); E the 50 mL two-neck Erlenmayer flask (reaction system). Liquid Hg is colored Red and the Yellow meniscus is the same solvent contained in Erlenmayer flask. The apparatus is thermostatically controlled.

In 1967 Calderazzo and Noack re-examined the prototype system using ¹³CO, in gas phase 50% enriched.^[19] The reaction product was investigated by infrared spectroscopy, monitoring changes in terminal CO stretching bands. The compound MnL(CO)₅, where L can be a methyl or acetyl group, has three stretching active IR vibrations due to C_4v molecular symmetry. The key signals were the axial ¹²CO and ¹³CO stretching bands (trans to L), respectively at 1991 cm^-1 and 1949 cm^-1. Compared to ¹²CO, the 13-labelled molecule shows a C-O bond stretching absorption shifted to lower wavenumbers. First of all, it was observed that the incoming ¹³CO have not been inserted in between the metal carbon bond Mn-CH₃. They obtained a 100% cis isomer of [Mn(COCH₃)(¹³CO)(CO)₄] (scheme 1).

Scheme 1. Note the solvent changing in the backward reaction: heptane is a high-boiling solvent, suitable for the temperature indicated.

Two hypothetical mechanisms had been previously proposed: the CO or CH₃ intramolecular migration. Calderazzo and Noack designed an experiment based on the Principle of Microscopic Reversibility:^[20] in mechanistic terms, if a certain series of steps constitutes the mechanism of a reverse reaction, the mechanism of the forward reaction, under the same conditions, is given by the same steps traversed forwards. They examined the decarbonylation of acetyl complex, prepared either by about 50% enriched [MnCH₃(¹³CO)(CO)₄] or prepared from CH₃(¹³CO)CI and Na[Mn(CO)₅]. They found a mixture of cis and trans product [MnCH₃(CO)₄(¹³CO)], 50% and 25% respectively (in ratio of 2:1). They obtained also 25% of unlabelled CH₃Mn(CO)₅ (scheme 2). According to the Principle of Microscopic Reversibility, this result confirmed the intramolecular CH₃ migration hypothesis, because the carbonyl migration process should have shown only the cis product [MnCH₃(¹³CO)(CO)₄] with a probability of 75% and the free ¹³CO product with 25% .

Scheme 2. Methyl migration.

Successive researches revealed also that cis-regiospecific alkyl or aryl migrations occur due to addition of neutral ligands (2 electron donor),^[21] and that a penta-coordinate intermediate, involved in the intramolecular mechanism, allows the retention of configuration (scheme 3). The kinetics are reminiscent of dissociative substitution except that the vacant site is formed at the metal during the migratory step, not by loss of a ligand. Using the steady-state method, the rate is given: ${\textstyle v=-{d[R] \over dt}=\left({\frac {k(1)k(2)[L][R]}{k(-1)+k(2)[L]}}\right)}$

Further experiments revealed that, not only Lewis acids are able to increase the reaction rate activating the carbonyl group, but also stabilizing the product and transition state. Other factors accelerating the reaction are polar, electron-withdrawing containing solvent, and bulky ligands L_n.^[22][23]

Scheme 3. Kinetic constants K(n) are colored orange.

Manganese(I) Alkyl Carbonyl Complexes

The involvement of migratory insertion in catalytic cycles of large industrial interest has contributed to maintain continuous interest in this mechanism.^[24] For instance, recently it has been highlighted the potential of alkyl Mn(I) carbonyl-based homogenous catalysts. New investigations have explored the catalyzed activation under milder conditions of nonpolar or moderately polar bond such as H−H, B-H, C-H and Si-H.^[25] Chemists have taken advantage of the possibility that Mn(I) alkyl complexes undergo migratory insertion, yielding an unsaturated acyl intermediate. In fact, hydrogen atom abstraction by the acyl ligand  paves the way to an active species for a variety of fast and reversable transformations, proceeding via an inner-sphere process. A remarkable example is the dehydrogenative silylation of alkenes (scheme 4).

Scheme 4. Dehydrogenative Silylation of Styrene Yielding to the corresponding 96% Allyl Silane ([Si]= SiEt₃) catalyzed by Mn complex (R= iso-propyl). The reaction is diastereoselective with E/Z> 99:1.

On Early Transition Metals

The majority of neutral homoleptic transition metals carbonyls obeys the eighteen electrons rule and basically is low spin. In fact carbon monoxide is a strong field ligand and produces large splitting between π occupied and non-bonding e_g orbitals. When in 1959 Giulio Natta presented to the Accademia Nazionale dei Lincei the discovery of the first paramagnetic metal carbonyl (17 electrons species),^[26][27] the announcement was followed by a serious scientific controversy. Virtually at the same time, Pruett and Wyman (Union Carbide, West Virginia, USA) obtained vanadium carbonyl by a different route. They suggested the formation of a diamagnetic, binuclear species V₂(CO)₁₂ with Vanadium-Vanadium bond.^[28] By magnetic-susceptibility measurements Calderazzo and coworkers showed that vanadium carbonyl is a mononuclear, paramagnetic compound with a value for the effective magnetic moment, µ_eff, close to the spin-only value.^[29] They suggested a ground state ²T_2g for the open-shell d⁵ configuration.

In 1967 Pratt and Myers proved that, at liquid-helium temperatures, either a tetragonal or trigonal distortion is present.^[30] Some years later, Bernier and Kahn indicated that between 300 and 66 K, V(CO)₆ has roughly an octahedral geometry but that a dynamic Jahn-Teller effect is present, and further under 66K solid V(CO)₆ is antiferromagnetic.^[31] Finally in 1979 X-Ray diffraction analysis confirmed the monomeric structure of V(CO)₆ and the Jahn-Teller distortion^[32]. The 17-electron configuration confers to V(CO)₆ unique properties with respect of comparable neutral homoleptic hexacarbonyls: V(CO)₆ is stable only under inert atmosphere and shows high reactivity. It undergoes ligand substitution with Associative Mechanism (scheme 5).^[33] Moreover, it is readily reduced to the 18-electron hexacarbonylvanadate(-1).

Scheme 5. CO substitution with phosphine goes by associative pathway: the kinetic equation shows the dependence from both phosphine and V(CO)₆ concentration; the change in entropy of activation is negative.

The synthesis of V(CO)₆ started from (acetyl acetonate)vanadium or VCl₃ which was reacted with CO, under high pressure and temperature (135 atm and 135 ^oC), in the presence of pyridine and an electropositive metal like sodium to give sodium hexacarbonyl vanadate(-1), Na[V(CO)₆]. The sodium salt  was oxidized by HCl in ether. In 1982, following up the research on hexacarbonyl metalates(−I) of group 5, Calderazzo and G. Pampaloni optimized the reaction conditions.^[34] The team developed also a new process for the synthesis of V(CO)₆, consisting of a one-electron oxidation of Na[V(CO)₆] with HCl in pentane at −70 °C. All their efforts to isolate and characterize the Tantalum and Niobium (-1) neutral hexacarbonyls failed. However, they verified that under the same experimental conditions, Na[Nb(CO)₆] and Na[Ta(CO₆)] underwent two-electron oxidations to the halo-carbonyls of the metal, in the oxidation state (+1), (figure 4).^[35][36]

Figure 4. Crystallographic structure of [H(THF)₂][Nb₂(µ-Cl)₃(CO)₈]:

  Oxygen

  Carbon

  Chlorine

  Niobium

  Hydrogen (only one is showed)

In addition, their work led to the synthesis of Nb and Ta(0) carbonyl complexes, stabilized by mixed metal clusters containing Silver (see figure 5 for Tantalum species).^[37] Much later, in 2020, neutral homoleptic M₂(CO)₁₂ (M= Nb, figure 6, Ta) was finally isolated by I. Krossing and co-workers.^[38] They obtained stable crystals at room temperature for several hours, under CO pressure in pentane solution. The tantalum carbonyl, Ta₂(CO)₁₂, was prepared by direct oxidation of [Ta(CO)₆]^- with Ag⁺ and the displacement of one CO ligand of [Ta(CO)₇]⁺ by another equivalent of [Ta(CO)₆]⁻.

Figure 5. Chemical diagram of Ag₃Ta₃(CO)₁₂(Me₂PCH₂CH₂PMe₂)₃

Figure 6. Crystallographic structure of Nb₂(CO)₁₂:

  Oxygen

  Carbon

  Niobium

Descending the group 5, it is evident how Nb and Ta obey more strictly to eighteen electrons rule and they are not stable, under normal conditions, as neutral homoleptic hexacarbonyls. On the other hand, V(CO)₆ is  too sterically crowded to dimerize.

Arene Derivatives of Early Transition Metals^[39]

In 1964, during his period at the European Cyanamid Research Institute, Calderazzo obtained the V(η⁶-1,3,5-C₆H₃Me₃)₂ by the reaction of VCl₃ with Al/AlCl₃ in 1,3,5-C₆H₃Me₃ followed by hydrolysis in alkaline medium. However, the procedure led to product in low yield.^[40] Revisiting this work many years later, Calderazzo and colleagues performed a one-pot and high yield synthesis of V(η⁶-1,3,5-C₆H₃Me₃)₂, thanks to the change of the polarity of the medium and a large excess of Aluminum used as reducing agent. The same procedure was also applied to the synthesis of the bis-mesitylene derivatives of Nb^[41], Cr, Mo(0) and bis-arene of Ti(0).^[42] The method and its variants were patented as well as the use of V(η⁶-1,3,5-C₆H₃Me₃)₂ for preparing solid solutions of vanadium and titanium halides VTi₃Cl₁₂. The collaboration with ENI succeeded in producing V(η⁶-1,3,5-C₆H₃Me₃)₂ in almost quantitative yield from VCl₃ on a kilogram scale. The chemistry of these arene early metal derivates revealed to be a useful synthetic tool to access conspicuous derivates in non-aqueous systems (scheme 6).^[43] The driving force of this reactivity is the tendency toward high oxidation states attainment, for highly electron-positive metals such as group 5 metals.

Scheme 6. Reactivity of V(η⁶-mes)₂ (mes= 1,3,5-C₆H₃Me₃). Crystallographic structures (Hydrogens are omitted for simplicity)

•   Vanadium
•   Oxygen
•   Carbon
•   Flourine
•   Iodide
•   Aluminium
•   Chlorine

Furthermore, Calderazzo and coworkers presented the first example of a tetra-arylborate anion (behaving as a 12-electron donor) obtained by thermal decomposition of Niobium(I) bis-arene derivative.^[44] In the field of group 4 metal derivates, F. Calderazzo and co-workers studied the treatment of a toluene solution of Ti(η⁶ -1,3,5-iPr₃C₆H₃)₂ , as obtained in cooperation with M. L. H. Green of Oxford University, with [FeCp₂]BAr₄ which afforded the orange, paramagnetic cation [Ti(η⁶ -1,3,5-iPr₃C₆H₃)₂]⁺ (figure 7),^[45] representing the first fully characterized titanium(I) derivative.

Figure 7. Crystallographic structures of Nb(η²-C₂H₂)(η⁶-C₆H₄F)₂B(C₆H₄F)₂ and [Ti(η⁶ -1,3,5-iPr₃C₆H₃)₂][(p-C₆H₄F)₄] (Hydrogens are omitted for simplicity):

•   Carbon
•   Flourine
•   Borum
•   Titanium
•   Niobium

On Lanthanides

The lanthanide contraction was originally recognized and described on the basis of X-ray crystallographic determinations on the oxides and fluorides of the Ln(III) ions, which are not isostructural along the whole series.^[46] In 1999 Calderazzo et al. showed the trend of the Ln-Oxygen distances as a function of the electronic configuration of the neutral lanthanide carbamate, with the same types of ligand and the same coordination number and geometry.^[47] They prepared tetranuclear isotypic N,N-dialkylcarbamato complexes [Ln₄(O₂CNR₂)₁₂], following the procedure:

${\textstyle {\ce {[LnCl3(ether)x] + 6 NHR2 + 3 CO2 -> [Ln(O2CNR2)3] + 3 [NH2R2]Cl + x ether}}}$

The mean values of the distances for each coordination bond type were plotted against the number of f electrons of the metal cation Ln(III). The di-isopropyl derivatives, with four of the major coordination modes are shown qualitatively in figure 8. Along the series, curves have rather similar slopes, suggesting that the metal radius contraction should mainly account for the trend and that early lanthanides contract their radii slightly more rapidly than the later ones. The N,N-diisopropyl derivatives from Neodynium to Lutetium are isotypic species, consisting of tetranuclear molecules, [Ln₄(O₂CNiPr₂)₁₂], where the metal center is hepta-coordinated.

Figure 8. Polynomial fittings of Ln-Oxygen distances as a function of 4f electronic configuration.

References

1. P. M. Maitlis, D. B. Dell’Amico. "Fausto Calderazzo: Pioneer in Mechanistic Organometallic Chemistry". Organometallics. 2014, 33, 6989–7006. https://doi.org/10.1021/om5011963
2. R. Poli. “Celebration of inorganic lives: Interview with Fausto Calderazzo (University of Pisa)”. Coord. Chem. Rev. 1999, 188, 1-22. https://doi.org/10.1016/S0010-8545(99)00081-8.
3. Award ceremony speech. NobelPrize.org. Nobel Prize Outreach AB 2024. Thu. 25 Jan 2024. https://www.nobelprize.org/prizes/chemistry/1963/ceremony-speech/
4. G. Natta, R. Ercoli, F. Calderazzo, A. Rabizzoni. “A new synthesis of chromium hexacarbonyl”. J. Am. Chem. Soc. 1957, 79, 3611–3612. https://doi.org/10.1021/ja01570a092.
5. R. Ercoli, F. Calderazzo, F. Alberola. “Synthesis of Vanadium Hexacarbonyl”. J. Am. Chem. Soc. 1960, 82, 2966–2967. https://doi.org/10.1021/ja01496a073
6. T. J. Barton, R. Grinter, A. J. Thomson. “The magnetic circular-dichroism spectrum of matrix-isolated vanadium hexacarbonyl”. J. Chem. Soc., Dalton Trans., 1978, 608-611. https://doi.org/10.1039/DT9780000608.
7. K. Noack, F. Calderazzo. “The carbonylation of methylmanganese pentacarbonyl with ¹³CO”. J. Organomet. Chem. 1967, 10, 101-104. https://doi.org/10.1016/S0022-328X(00)81721-0.
8. R.H. Crabtree, The organometallic chemistry of the transition metals. Wiley, New York (2005).
9. C. Elschenbroich, Organometallics. Wiley-VCH, Weinheim (2006).
10. P. Kalck, C. Le Berre, P. Serp. “Recent advances in the methanol carbonylation reaction into acetic acid”. Inorg. Chem.Rev., 2020, 402, 213078. https://doi.org/10.1016/j.ccr.2019.213078.
11. G.D Frey. “75 Years of oxo synthesis-The success story of a discovery at the OXEA Site Rurhrchemie”. J. Organomet. Chem., 2014, 754, 5-7. https://dx.doi.org/10.1016/j.jorganchem.2013.12.023.
12. D. B. Dell'Amico, F. Calderazzo, F. Marchetti, S. Ramello. “Molecular Structure of [Pd₆Cl₁₂] in Single Crystals Chemically Grown at Room Temperature”. Angew. Chem., 1996, 35, 1331-1333. https://doi.org/10.1002/anie.199613311.
13. D. B. Dell'Amico, F. Calderazzo, F. Marchetti, S. Merlino, G. Perego. “X-Ray crystal and molecular structure of Au₄Cl₈, the product of the reduction of Au₂Cl₆ by Au(CO)Cl”. J. Chem. Soc., Chem. Commun., 1977, 31-32. DOI: https://doi.org/10.1039/C39770000031.
14. D. B. Dell'Amico, F. Calderazzo, P. Robino, A. Segre. “Halogenocarbonyl complexes of gold”. J. Chem. Soc., Dalton Trans., 1991, 3017–3020. https://doi.org/10.1039/DT9910003017.
15. G. Bistoni, S. Rampino, N. Scafuri, G. Ciancaleoni, D. Zuccaccia, L. Belpassi, F. Tarantelli. “How π back-donation quantitatively controls the CO stretching response in classical and non-classical metal carbonyl complexes”. Chem. Sci., 2016,7, 1174-1184. https://doi.org/10.1039/C5SC02971F.
16. D. B. Dell’Amico, F. Calderazzo, L. Labella, F. Marchetti, G. Pampaloni. “Converting Carbon Dioxide into Carbamato Derivatives”. Chem. Rev., 2003, 103, 3857−389. https://doi.org/10.1021/cr940266m.
17. G. Bresciani, L. Biancalana, G. Pampaloni, F. Marchetti. “Recent Advances in the Chemistry of Metal Carbamates”. Molecules. 2020, 25, 3603. https://doi.org/10.3390/molecules25163603.
18. F. Calderazzo, F. A. Cotton. “The Carbonylation of Methyl Manganese Pentacarbonyl and Decarbonylation of Acetyl Manganese Pentacarbonyl”. Inorg. Chem., 1962, 1, 30–36. https://doi.org/10.1021/ic50001a008.
19. See note 7.
20. R. L. Burwell Jr., R. G. Pearson. “The Principle of Microscopic Reversibility”. Phys. Chem., 1966, 70, 300–302. https://doi.org/10.1021/j100873a508.
21. K. Noack, M. Ruch, F. Calderazzo. “The Mechanism of Reaction of Methylmanganese Pentacarbonyl and Acetylmanganese Pentacarbonyl with Triphenylphosphine”. Inorg. Chem., 1968, 7, 345–349. https://doi.org/10.1021/ic50060a037.
22. E. J. Kuhlmann, J. J. Alexander. “Carbon monoxide insertion into transition metal-carbon sigma-bonds”. Coord. Chem. Rev., 1980, 33, 195-225. https://doi.org/10.1016/S0010-8545(00)80454-3.
23. F. Calderazzo. “Synthetic and Mechanistic Aspects of Inorganic Insertion Reactions. Insertion of Carbon Monoxide”. Angew. Chem. 1977, 165, 299-311. https://doi.org/10.1002/anie.197702991.
24. M. T. Whited, G. E. Hofmeister. “Synthesis and Migratory-Insertion Reactivity of CpMo(CO)₃(CH₃): Small-Scale Organometallic Preparations Utilizing Modern Glovebox Techniques”. J. Chem. Educ. 2014, 91, 1050–1053. https://doi.org/10.1021/ed500114a.
25. S. Weber, K. Kirchner. “Manganese Alkyl Carbonyl Complexes: From Iconic Stoichiometric Textbook Reactions to Catalytic Applications”. Acc. Chem. Res. 2022, 55, 2740−2751. https://doi.org/10.1021/acs.accounts.2c00470.
26. G. Natta, R. Ercoli, F. Calderazzo, A. Alberola, P. Corradini, G. Allegra, Atti. Acad. Naz. Lincei, Rend. Classe Sci. Mat. Nat., 1959, 27, 107. https://www.lincei.it/it.
27. See note 5.
28. R. Pruett, L. Wyman. Chem. Ind. (London)., 1960, 119-120.
29. F. Calderazzo, R. Cini, P. Corradini, R. Ercoli, G. Natta. Chem. Ind. (London)., 1960, 500 and 934.
30. [1] D. W. Pratt, R. J. Myers. “Electron spin resonance spectrum of vanadium hexacarbonyl at liquid-helium temperatures”. J. Am. Chem. Soc., 1967, 89, 6470–6472. https://doi.org/10.1021/ja01001a016
31. J.C. Bernier, O. Kahn. “Magnetic Behaviour of vanadium hexacarbonyl”. Chem. Phys. Letters, 1973, 19, 414. https://doi.org/10.1016/0009-2614(73)80394-X.
32. S. Bellard, A. K. Rubinson; M. G. Sheldrick. "Crystal and Molecular Structure of Vanadium Hexacarbonyl". Acta Crystallographica. 1979, B35, 271–274. https://doi.org/10.1107/S0567740879003332.
33. F. Basolo. “Kinetics and mechanisms of CO substitution of metal carbonyls”. Polyhedron, 1990, 9, 1503-1535.https://doi.org/10.1016/S0277-5387(00)86570-5.
34. F. Calderazzo, G. Pampaloni, G. Pelizzi. “The hexacarbonylniobate(−I) anion”. J. Organomet. Chem. 1982, 233, C41-C43. https://doi.org/10.1016/S0022-328X(00)85584-9.
35. F. Calderazzo, M. Castellani, G. Pampaloni, P. F. Zanazzi. “New carbonyl derivatives of niobium(I) and tantalum(I). Journal of the Chemical Society”. J. Chem. Soc., Dalton Trans., 1985, 1989-1995.[1]
36. F. Calderazzo, G. Pampaloni. “Metal carbonyl complexes of group VB metals”. J. Organomet. Chem., 1986, 303, 111-120. https://doi.org/10.1016/0022-328X(86)80116-4.
37. F. Calderazzo, G. Pampaloni, U. Englert, J. Strähle. “Electron-transfer processes with substituted group 5 metal carbonyls. Synthesis, crystal and molecular structure of Ag₃M₃(CO)₁₂(Me₂PCH₂CH₂PMe₂)₃, M = Nb, Ta, the first structurally characterized carbonyl derivatives of niobium(0) and tantalum(0)”. J. Organomet. Chem., 1990, 383, 45-57. https://doi.org/10.1016/0022-328X(90)85121-E.
38. W. Unkrig, M. Schmitt, D. Kratzert, D. Himmel, I. Krossing. “Synthesis and characterization of crystalline niobium and tantalum carbonyl complexes at room temperature”. Nat. Chem., 2020, 12, 647–653. https://doi.org/10.1038/s41557-020-0487-3.
39. G. Pampaloni. “Aromatic hydrocarbons as ligands. Recent advances in the synthesis, the reactivity, and the applications of bis(η⁶-arene) complexes”. Coord. Chem. Rev., 2010, 254, 402-419. https://doi.org/10.1016/j.ccr.2009.05.014.
40. F. Calderazzo. “The Dimesitylenevanadium(I) Cation”. Inorg. Chem., 1964, 3, 810–814. https://doi.org/10.1021/ic50016a006.
41. F. Calderazzo, G. Pampaloni, L. Rocchi, J. Strähle, K. Wurst. “Synthesis and reactivity of η⁶-arene derivatives of niobium(II), niobium(I), and niobium(0)”. J. Organomet. Chem., 1991, 413, 91-109. https://doi.org/10.1016/0022-328X(91)80041-H.
42. F. Calderazzo, U. Englert, G. Pampaloni, M. Volpe. “Redox reactions with bis(η⁶-arene) derivatives of early transition metals”. J. Organomet. Chem. ,2005, 690, 14, 3321–3332. https://doi.org/10.1016/j.jorganchem.2005.03.064.
43. F. Calderazzo, G. E. De Benedetto, G. Pampaloni, C. Maichle-Mössmer, J. Strähle, K. Wurst. “Bis(arene)vanadium(0) complexes as a source of Vanadium(II) derivatives by both disproportionation of the [V(η⁶-arene)₂]⁺ cations and oxidation of [V(η⁶-arene)₂]”. J. Organomet. Chem., 1993, 451, 73-81. https://doi.org/10.1016/0022-328X(93)83010-S.
44. F. Calderazzo, G. Pampaloni, L. Rocchi, U. Englert. “Synthesis, Reactivity, and Crystal and Molecular Structures of Nb(L)(η⁶-C₆H_5-nX_n)₂B(C₆H_5-nX_n)₂, a Class of Mononuclear Metal Compounds Containing the 12-Electron-Donor Tetraarylborato Ligand”. Organometallics, 1994, 13, 2592–2601. https://doi.org/10.1021/om00019a016.
45. [1] F. Calderazzo, I. Ferri, G. Pampaloni, U. Englert, M. L. H. Green. “Synthesis of [Ti(η⁶-1,3,5-iPr₃C₆H₃)₂][BAr₄] (Ar = C₆H₅, p-C₆H₄F, 3,5-(CF₃)₂C₆H₃), the First Titanium(I) Derivative”. Organometallics, 1997, 16, 3100–3101. https://doi.org/10.1021/om970155o.
46. D. H. Templeton,C. H. Dauben. “Lattice Parameters of Some Rare Earth Compounds and a Set of Crystal Radii”. J. Am. Chem. Soc., 1954, 76, 5237–5239. https://doi.org/10.1021/ja01649a087.
47. U. Abram, D. B. Dell’Amico, F. Calderazzo, C. Della Porta, A. Merigo, U. Englert, F. Marchetti. “Isotypical N,N-dialkylcarbamato lanthanide complexes covering a range of 11 atomic numbers: direct experimental assessment of the lanthanide contraction in trivalent molecular compounds”. Chem. Commun., 1999, 2053-2054. DOI: https://doi.org/10.1039/A904792A.