Margaret M. Boorum scite author profile

Isolable quantities of C60, the smallest stable fullerene, have been synthesized in 12 steps from commercially available starting materials by rational chemical methods. A molecular polycyclic aromatic precursor bearing chlorine substituents at key positions forms C60 when subjected to flash vacuum pyrolysis at 1100 degrees C. No other fullerenes are formed as by-products. The methods we have developed for the target-specific synthesis of fullerenes, applied here to a synthesis of C60, should make possible the directed laboratory preparation of other fullerenes as well, including those not accessible by graphite vaporization.

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Groundwork for a Rational Synthesis of C ₆₀ : Cyclodehydrogenation of a C ₆₀ H ₃₀ Polyarene

Boorum

Vasil’ev

Drewello

et al. 2001

Science

187

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A C60H30 polycyclic aromatic hydrocarbon (PAH) that incorporates all 60 carbon atoms and 75 of the 90 carbon-carbon bonds required to form the fullerene C60 has been synthesized in nine steps by conventional laboratory methods. Laser irradiation of this C60H30 PAH at 337 nanometers induces hydrogen loss and the formation of C60, as detected by mass spectrometry. A specifically labeled [13C3]C60H30 retains all three 13C atoms during the cage formation process. A structurally related C48H24 PAH that lacks the three peripheral benzene rings cannot be transformed into C60, whereas the next higher homolog, a C80H40 PAH, degrades to the C60H30 PAH, which then loses hydrogen to give [60]fullerene. These control experiments verify that the C60 is formed by a molecular transformation directly from the C60H30 PAH and not by fragmentation and recombination in the gas phase.

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The Synthesis of Tris‐Annulated Benzenes by Aldol Trimerization of Cyclic Ketones

Boorum¹,

Scott²

2002

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For the synthesis of tris-annulated benzene rings, the aldol trimerization of cyclic ketones has been known as a powerful tool since the 19 th century. Why the reaction works so well with some ketones (e.g., indanone) but fails so miserably with others (e.g., tetralone), however, has never been adequately explained. This chapter outlines the development and scrutiny of a hypothesis that says: formation of an a,b-unsaturated (conjugated) dimer from a cyclic ketone is vital to the success of an aldol trimerization reaction for the synthesis of a tris-annulated benzene; the reaction will fail with ketones that form only b,g-unsaturated (unconjugated) dimers. This hypothesis unifies much experimental chemistry and is supported by theoretical calculations.

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The Synthesis of Tris‐Annulated Benzenes by Aldol Trimerization of Cyclic Ketones

Boorum

Scott

2004

ChemInform

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