Rhodiumkatalysierte enantioselektive 1,2‐Addition von Organoaluminiumverbindungen an cyclische Enone

Abstract: Professor Armin de Meijere gewidmetDie 1,2-Addition von Organometallverbindungen an Carbonylgruppen zählt zu den wichtigsten Methoden der C-CBindungsbildung in der organischen Synthese. In den vergangenen Jahren wurden übergangsmetallkatalysierte Verfahren entwickelt, nach denen sich unterschiedlichste Aldehyde stereoselektiv umsetzen lassen.[1] Dagegen gestaltet sich die entsprechende Transformation von Ketonen und insbesondere konjugierten Enonen immer noch schwierig, und es existieren hierfür nur wenige gee… Show more

“…Using the optimised reaction conditions, various cycloalk‐2‐enones with 5–7‐membered rings were converted into the corresponding tertiary allylic alcohols, all with ≥ 95 % ee (Table 3). The yields achieved when 0.5 mol % of the dimeric [{Rh(cod)Cl} 2 ] precursor and 1.5 mol % of AgBF 4 were used compare very well to yields previously obtained with 2.5 mol % of [{Rh(cod)OMe} 2 ] in the absence of silver salts 6. When 6‐membered rings are used as substrates yields are generally ≥ 80 %, with the single exception of a substrate with geminal disubstitution at the C5 position (Table 3, entry 3).…”

“…This binap complex must be a precatalyst that slowly liberates the catalytically active species. Thus, we speculated that promoting the cleavage of this dimer would provide the key to a more active catalyst, even though we previously observed inferior results with [Rh(cod) 2 ]BF 4 as rhodium source 6. Fortunately, addition of a slight excess of AgBF 4 (based on the amount of chloride) led to a quantitative yield of the 1,2‐addition product 2 a with just 0.5 mol % of dimeric [{Rh(binap)Cl} 2 ].…”

“… [a] Isolated yield. Values in parentheses with 2.5 mol % [{Rh(cod)OMe} 2 ] without AgBF 4 6. [b] Determined by GC.…”

“…However, when using cycloalkenones as substrates, a substituent in the 2‐position is usually required to achieve high levels of selectivity 5f. g We have previously reported a Rh I /binap‐catalysed 1,2‐addition furnishing excellent levels of enantioselectity and high yields of product even in the case of unsubstituted cycloalkenones (Scheme ) 6. The utilisation of organoaluminium reagents as nucleophiles is an attractive feature of this method 7.…”

“…[5f, g] We have previously reported a Rh I /binap-catalysed 1,2-addition furnishing excellent levels of enantioselectity and high yields of product even in the case of unsubstituted cycloalkenones (Scheme 1). [6] The utilisation of organoaluminium reagents as nucleophiles is an attractive feature of this method. [7] Both inexpensive AlMe 3 and air-stable adduct DABCO-A C H T U N G T R E N N U N G (AlMe 3 ) 2 [8] (DABCO = 1,4-diazabicycloA C H T U N G T R E N N U N G [2.2.2]octane) can be used for the addition of a methyl group; aryl groups can be introduced from mixed alanes ArAlMe 2 .…”

Improved Synthesis of Cyclic Tertiary Allylic Alcohols by Asymmetric 1,2‐Addition of AlMe₃ to Enones

“…Using the optimised reaction conditions, various cycloalk‐2‐enones with 5–7‐membered rings were converted into the corresponding tertiary allylic alcohols, all with ≥ 95 % ee (Table 3). The yields achieved when 0.5 mol % of the dimeric [{Rh(cod)Cl} 2 ] precursor and 1.5 mol % of AgBF 4 were used compare very well to yields previously obtained with 2.5 mol % of [{Rh(cod)OMe} 2 ] in the absence of silver salts 6. When 6‐membered rings are used as substrates yields are generally ≥ 80 %, with the single exception of a substrate with geminal disubstitution at the C5 position (Table 3, entry 3).…”

“…This binap complex must be a precatalyst that slowly liberates the catalytically active species. Thus, we speculated that promoting the cleavage of this dimer would provide the key to a more active catalyst, even though we previously observed inferior results with [Rh(cod) 2 ]BF 4 as rhodium source 6. Fortunately, addition of a slight excess of AgBF 4 (based on the amount of chloride) led to a quantitative yield of the 1,2‐addition product 2 a with just 0.5 mol % of dimeric [{Rh(binap)Cl} 2 ].…”

“… [a] Isolated yield. Values in parentheses with 2.5 mol % [{Rh(cod)OMe} 2 ] without AgBF 4 6. [b] Determined by GC.…”

“…However, when using cycloalkenones as substrates, a substituent in the 2‐position is usually required to achieve high levels of selectivity 5f. g We have previously reported a Rh I /binap‐catalysed 1,2‐addition furnishing excellent levels of enantioselectity and high yields of product even in the case of unsubstituted cycloalkenones (Scheme ) 6. The utilisation of organoaluminium reagents as nucleophiles is an attractive feature of this method 7.…”

“…[5f, g] We have previously reported a Rh I /binap-catalysed 1,2-addition furnishing excellent levels of enantioselectity and high yields of product even in the case of unsubstituted cycloalkenones (Scheme 1). [6] The utilisation of organoaluminium reagents as nucleophiles is an attractive feature of this method. [7] Both inexpensive AlMe 3 and air-stable adduct DABCO-A C H T U N G T R E N N U N G (AlMe 3 ) 2 [8] (DABCO = 1,4-diazabicycloA C H T U N G T R E N N U N G [2.2.2]octane) can be used for the addition of a methyl group; aryl groups can be introduced from mixed alanes ArAlMe 2 .…”

Improved Synthesis of Cyclic Tertiary Allylic Alcohols by Asymmetric 1,2‐Addition of AlMe₃ to Enones

Trimethylaluminum

Enantioselective Rhodium‐Catalyzed Addition of Arylboronic Acids to α‐Ketoesters