Palladium | EPFL Graph Search

Palladium is a chemical element with the symbol Pd and atomic number 46. It is a rare and lustrous silvery-white metal discovered in 1803 by the English chemist William Hyde Wollaston. He named it after the asteroid Pallas, which was itself named after the epithet of the Greek goddess Athena, acquired by her when she slew Pallas. Palladium, platinum, rhodium, ruthenium, iridium and osmium form a group of elements referred to as the platinum group metals (PGMs). They have similar chemical properties, but palladium has the lowest melting point and is the least dense of them. More than half the supply of palladium and its congener platinum is used in catalytic converters, which convert as much as 90% of the harmful gases in automobile exhaust (hydrocarbons, carbon monoxide, and nitrogen dioxide) into nontoxic substances (nitrogen, carbon dioxide and water vapor). Palladium is also used in electronics, dentistry, medicine, hydrogen purification, chemical applications, groundwater treatment, and jewelry. Palladium is a key component of fuel cells, in which hydrogen and oxygen react to produce electricity, heat, and water. Ore deposits of palladium and other PGMs are rare. The most extensive deposits have been found in the norite belt of the Bushveld Igneous Complex covering the Transvaal Basin in South Africa, the Stillwater Complex in Montana, United States; the Sudbury Basin and Thunder Bay District of Ontario, Canada, and the Norilsk Complex in Russia. Recycling is also a source, mostly from scrapped catalytic converters. The numerous applications and limited supply sources result in considerable investment interest. Palladium belongs to group 10 in the periodic table, but the configuration in the outermost electrons is in accordance with Hund's rule. Electrons that by the Madelung rule would be expected to occupy the 5s instead fill the 4d orbitals, as it is more energetically favorable to have a completely filled 4d10 shell instead of the 5s2 4d8 configuration.

Modular Synthesis of Benzocyclobutenes via Pd(II)-Catalyzed Oxidative [2+2] Annulation of Arylboronic Acids with Alkenes

Qian Wang, Jieping Zhu, Takuji Fujii, Simone Gallarati

Benzocyclobutenes (BCBs) are highly valuable compounds in organic synthesis, medicinal chemistry, and materials science. However, catalytic modular synthesis of functionalized BCBs from easily accessible starting materials remains limited. We report herein an efficient synthesis of diversely functionalized BCBs by a Pd(II)-catalyzed formal [2+2] annulation between arylboronic acids and alkenes in the presence of N-fluorobenzenesulfonimide (NFSI). An intermolecular carbopalladation followed by palladium oxidation, intramolecular C(sp2)−H activation by a transient C(sp3)−Pd(IV) species, and selective carbon−carbon (C−C) bond-forming reductive elimination from a high-valent five-membered palladacycle is proposed to account for the reaction outcome. Kinetically competent oxidation of alkylPd(II) to alkylPd(IV) species is important to avoid the formation of a Heck adduct. The reaction forges two C−C bonds of the cyclobutene core and is compatible with a wide range of functional groups. No chelating bidentate directing group in the alkene part is needed for this transformation.

2022

New Strategies for the Functionalization of Alkenes Exploiting Tethering Chemistry and Ring Strain

Bastian Antoine Rodolphe Claude Muriel

Amino alcohols, cyclopropanes and nitriles are privileged structural motifs found in the scaffold of natural products and bioactive compounds. In addition, they are versatile building blocks in organic chemistry. The development of new and increasingly efficient synthetic methods to access these chemical motifs from readily available feedstocks is therefore highly desirable. In this context, alkenes have been substrates of choice to rapidly access complex molecules, as two new functionalities can be installed across their double bond. To achieve such transformations, palladium catalysis and radical chemistry stand as two of the most efficient strategies. In this thesis, a new palladium-catalyzed carboamination of allylic alcohols using a trifluoroacetaldehyde-based tether was first investigated. The tether could be easily installed on diverse allylic alcohol substrates, the formed hemiaminals underwent in high yield and diastereoselectivities the desired transformation under optimized conditions. Both alkynyl- and aryl-bromides could be used as electrophilic partners in the reaction. For the latter, in order to supress a competitive Heck-pathway, a new phosphine-based ligand âFuXPhosâ had to be developped and was key to reach high yields for the aminoarylation in combination with CsOTf as additive. The tether in the obtained products could be cleaved under acidic conditions delivering valuable amino alcohol derivatives. This difunctionalization strategy mediated by palladium was then applied to the strained alkene of cyclopropenes. While preliminary results for the intramolecular carbo-amination and carbo-etherification of cyclopropenes could be obtained, the difficulty to access the starting materials for these transformations led to consider a more convergent approach to access functionalized cyclopropanes. Using radical chemistry, a novel synthesis of bicyclo[3.1.0]hexanes could be developed, by a (3+2) annulation of cyclopropylanilines with cyclopropenes mediated by photoredox. The scope of the transformation was broad for both reaction partners, but the products were obtained with low diastereoselectivities. It was found that by combining difluorocyclopropenes with a bulky aromatic N-substituent on the cyclopropylamine, the corresponding fluorinated bicyclo[3.1.0]hexanes could be accessed in good yields and diastereoselectivities under slightly re-optimized conditions. Finally, the possibility to achieve an amination reaction of cyclopropenes using N-centered radicals was investigated. It was discovered that the addition of azidyl radicals to the double bond of cyclopropenes under photoredox conditions led to the formation of two new products coming from an unexpected ring cleavage: an alkenyl nitrile and a quinoline. While the formation of the quinoline product could not be optimized above 47% yield, conditions could be found for the selective formation of the alkenyl nitrile in high yields using cheap and commercial reagents. Through the scope investigations it was discovered that an aryl-substituent on the double bond of the cyclopropene substrates was necessary for the transformation to proceed. Despite this limitation various substrates could be engaged in the transformation and delivered the corresponding alkenyl nitriles in high yields. With 1,2-diaryl substituted cyclopropenes a synthesis of valuable polycyclic aromatic compounds could be developed, through a one pot radical amination / oxidative cyclization.

EPFL2021

Axially Chiral Dibenzazepinones by a Palladium(0)-Catalyzed Atropo-enantioselective C-H Arylation

Nicolai Cramer, Matthew Wodrich, Christopher Gordon Newton, Elena Braconi, Jennifer Kuziola

Atropo‐enantioselective C−H functionalization reactions are largely limited to the dynamic kinetic resolution of biaryl substrates through the introduction of steric bulk proximal to the axis of chirality. Reported herein is a highly atropo‐enantioselective palladium(0)‐catalyzed methodology that forges the axis of chirality during the C−H functionalization process, enabling the synthesis of axially chiral dibenzazepinones. Computational investigations support experimentally determined racemization barriers, while also indicating C−H functionalization proceeds by an enantio‐determining CMD to yield configurationally stable eight‐membered palladacycles.

2018

New Strategies for the Functionalization of Alkenes Exploiting Tethering Chemistry and Ring Strain

Bastian Antoine Rodolphe Claude Muriel

EPFL2021