Abstract
Catalysis fulfills the promise that high-yielding chemical transformations will require little energy and produce no toxic waste. This message is carried by the study of the evolution of molecular catalysis of some of the most important reactions in organic chemistry. After reviewing the conceptual underpinnings of catalysis, we discuss the applications of different catalysts according to the mechanism of the reactions that they catalyze, including acyl group transfers, nucleophilic additions and substitutions, and C–C bond forming reactions that employ umpolung by nucleophilic additions to C=O and C=C double bonds. We highlight the utility of a broad range of organocatalysts other than compounds based on proline, the cinchona alkaloids and binaphthyls, which have been abundantly reviewed elsewhere. The focus is on organocatalysts, although a few examples employing metal complexes and enzymes are also included due to their significance. Classical Brønsted acids have evolved into electrophilic hands, the fingers of which are hydrogen donors (like enzymes) or other electrophilic moieties. Classical Lewis base catalysts have evolved into tridimensional, chiral nucleophiles that are N- (e.g., tertiary amines), P- (e.g., tertiary phosphines) and C-nucleophiles (e.g., N-heterocyclic carbenes). Many efficient organocatalysts bear electrophilic and nucleophilic moieties that interact simultaneously or not with both the electrophilic and nucleophilic reactants. A detailed understanding of the reaction mechanisms permits the design of better catalysts. Their construction represents a molecular science in itself, suggesting that sooner or later chemists will not only imitate Nature but be able to catalyze a much wider range of reactions with high chemo-, regio-, stereo- and enantioselectivity. Man-made organocatalysts are much smaller, cheaper and more stable than enzymes.
Highlights
In 1746, Roebuck developed the lead chamber for sulfuric acid production in which nitrogen oxides catalyze the oxidation of SO2 into SO3
Organocatalysis refers to a form of catalysis, in which the rate of a chemical reaction is increased by an organic compound referred to as an organocatalyst consisting of carbon, hydrogen, nitrogen, oxygen, phosphorus, sulfur, and other nonmetal elements
In the two last decades, organocatalysis has become a pillar of asymmetric organic synthesis [4,5,6,7,8,9,10]
Summary
In 1746, Roebuck developed the lead chamber for sulfuric acid production in which nitrogen oxides catalyze the oxidation of SO2 into SO3. A good catalyst is a compound that does not bind too strongly to the reactants, does not form intermediates that are more stable than the products, that lowers the activation free energies of all the elementary processes converting the reactants into the initial complex first, and converts this complex into the intermediate, retarded (increase of Δ‡G) if the reactants and/or the transition structure (activated complex) are associated (make complexes) with one or more than one (cluster) spectator molecules (solvent, additive, catalyst, inhibitor and combination of them) Beyond the properties of bulk water, a single molecule of H2O, or an aggregate may influence the raFtigeuorfea11.r. (eA(aA)c)tFirFoernee[e1ne7en,re1gr8yg]y.dFidaogiarrgairnmasmtfaonrfocaren,aunwnaucatnetcaralytfaozlreymdzegsdacsgopamhspapslheeaxbseiems bwoilmeitcohulleracarudrlieacaracrltseioaancntcidoonnpvcoeolrantrivnemgrtAoinle+gcules in theBArm→+aBlPr;→e(aBc)Pti;for(enBes)e[f1nr9er,e2g0ye]ndaeirnagdgyrsadumicahgforcaromamcfpaoltreaxlayazcteiaodtan(lcyaazltteaedlryss(cttahCtea)lrybesiamtcCtoil)oencbuiamlacortilvreecaautciltoaionr nrf;erea(Ccet)eionfnree;reg(Ceine)sef.rrgKeyeinetic studideenisaegarrsgaywmdefiloalrgaarsabqmimuafoonlretcuaumlbaircmrheoealmectciiuoclnaalrinmrheeiabccihtieaodnnbiciynaalhdcibdailittceiuvdleabDtyi.oIanfdsDdhiitasivvineessDuhb.osIwtfoDinchtihisoamitneotsnruiecbmcstooonilceehcniuotrmlaeteiotorfniwc, ater accelceornacteensthraytidorno, gtheenuanbcasttaralyczteiodnrefarcotimona(cAe)twalidllechoymdpeetbeywhityhd(Cro).xTyhlerraedtaicrdaal,titoon pefrfoecdtuocfeDaicnectryealsreasdical and awwithatietsrcmonocleencturaleti,oans. represented in Figure 2 [21]
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