Sodium Borohydride Reduction of 9-Fluorenone

The crude prdduct mek{ng pdint is 153 'c, with a product yield of 95-100%. ... fluorenol Rt = 0.56, obtained using Eastman Kodak flno- ... when our co...
28 downloads 0 Views 1MB Size
edited by ARDEN P. ZIPP SUNY-Cartland

the microscale laboratory A Synthesis of 9-Fluorenol: Sodium Borohydride Reduction of 9-Fluorenone

c-1and,Ny13045

Literature Cited 1. Mayo.

D.W.; P ~ k e R. . M.: Butcher S. S. M , n n r . d e Orgnnir Lnhorninr:~,21E. Wilcy

,am

2. Mayo, D.W.: Pike. R. M.:Tiurnper P K . Micrnsm& O r ~ n ~ iLohoralo,:~, h. WE. Wiley

C. Susana Jones University of California. San Diego La Jolla, CA 92093-0303

The oxidation of 9-fluorenol by chromic acid-amberlite resin (I.2 ) is a common undereraduate exoeriment in mi., crosu:il(~ord;inic lal~oratones.The cost of the starring rnatt>rialii;louroximntelv .. " eleht rirnesrmentrr r h n n thnr ofthe product, 9-fluorenone. Thus, i t seemed worthwhile to investigate whether the reduction back to the alcohol was a reacGon that also could be carried out in the undergraduate laboratory. This new reaction, reduction of a ketone, could be assigned a s a special project to allow students in a second term of organic laboratory to gain experience with scaled-up reaction conditions. The product could be used for a class-wide microscale oxidation during the following semester. Students will be able to observe different percentage yield reactions. This borohydride reduction has a 95-100% yield, and the chromic acid-amberlite resin oxidation reaction has only up to a n 80% yield. Experimental Procedure For a microscale approach the chemicals in the next procedure may be reduced by a factor of 10. Caution Large scale preparation should be done in a hood because of the hydrogen gas evolved. A 5-g sample of 9-fluorenone is dissolved i n 30 mL of warm ethanol in a 100-mL beaker. To this solution is added, dropwise, 10 mL of a reducing reagent, freshly prepared, which consists of 200 mg sodium methoxide, 10 mL methanol, and 0.4 e sodium borohydride. This solution is allowed to stand undisturbed for 10-20 min. Acolor change is observed a s the reaction proceeds from the yellow 9-fluorenone to the white 9-fluorenol. The product i s precipitated by the addition of 50 mL of water and neutralized with 0.1 M HCI, vacuum filtered, and washed with cold water to remove any residual inorganic salt formed by the excess of the sodium horohvdride reaeent and hvdrochloric acid. The dried crude product is suffiyciently puEe for characterization bv meltine ~ o i n tinfrared . s ~ e c t r aand . NMR. The crude prdduct mek{ng pdint is 153 'c, with a product yield of 95-100%. Analytical Procedure Thin-layer chromatography (TLC) as indicated i n Mayo (1)could be used to monitor the progress of the reaction, the retention factor for 9-fluorenone is Rr = 0.80 and for fluorenol Rt = 0.56, obtained using Eastman Kodak flnorescent silica gel plates developed with 30% acetoneihexane as the chromatography eluent, and visualized under W light. Acknowledgment Support and suggestions from Barbara Sawrey improving this article are gratefully acknowledged. A252

Journal of Chemical Education

1994.

Microscale on a Budget R. Daniel Bishop, Jr. Colorado State University Fort Collins. CO 80523

The benefits to be obtained from converting an undera a d u a t e oreanic laboratorv o r o a a m to microscale exoeriLents havelbeen presented ion&cingly in several over the last few years ( 1 3 ) .One maior obstacle to makine the conversion, particularly for medium and large university programs, is the initial cost in new labware and eqnipment. In our program, there are 18 organic sections of 24 students each, so that complete conversion to microscale would require the purchase of 432 microscale lab kits. With even the least expensive kits retailing around $150 each, conversion costs could easily exceed $63,000. This challenge was confronted by selectively purchasing individual microware items, rather than complete kits, and incorporating inexpensive alternatives for items that could be omitted. The table itemizes both the labware omitted and the labware purchased for this conversion project. This approach, along with a manufacturer's discount, made the cost of glassware only $39 per drawer in 1990 when our conversion was made. (Today, the cost per drawer would come to about $58 before discount. All prices discussed in the remainder of this paper and i n the table are based on the 1994 undisconnted price list from Kontes.) Along with the glassware, 10 centrifuges, six digital 1.000mL microdisoensers. and 10 reaeent bottle-too. disoensers were purchased to equip our three labs for microscale work a t a total cost of $22.200. In addition. 72 aluminum heating blocks (one for each student station) were made by our machine shop. The microscale labware chosen was from the MicroFlex Kit line supplied by Kontes, designed for use with Kenneth Williamson's text, Macroscale a n d Microscale Organic Exoeriments (1989. D. C . Heath and Comoanv). However. " similar savings can be achieved with other manufacturers' labware bv selectine onlv " those items needed for the conversion. Our students are assigned locked drawers for their labware, which already included stainless steel spatulas, filter flasks. Hirsch funnels. and filter collars. so these items along with plastic storage cases were left off our shopping list for a savines of more than $41 Der drawer. The standari kit comes with twd 5-mL round-bottomed flasks, five calibrated reaction tubes (10 x 100 mm test tubes), and three 10-mL Erlenmeyer flasks . Each drawer was supplied with only one 5-mL RB flask, having selected the long-necked flask for its wider range of uses. Two reaction tubes and two 10-mL Erlenmeyer flasks were included. The three-armed connecting adapter, though useful, was felt to be redundant. Simple alternatives (see

.

.

-