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…the glassware is not moisture-free?
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Deactivation or hydrolysis of the reagent can occur.
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Difficultly initiating the reaction is possible.
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Loss of substrate/low yield of the product. Elevated risks during quenching and cleanup
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Glassware should be flame-dried under vacuum or flowing dry inert gas. Alternatively, assemble immediately after removal from a drying oven and allow to cool to room temperature under vacuum or dry inert gas.
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…the reaction flask is not large enough to hold the entire reaction volume?
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Overflow of the reaction flask occurs.
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Fire and chemical exposure
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As a rule, aim for a vessel that is no more than 50% full when all reaction con- tents have been added.
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…the reaction setup is not adequate for effective stirring?
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Uncontrolled, localized heating results.
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Chemical spill with the risk of a fire
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Use a suitable oval-shaped magnetic stir bar or over- head mechanical stirrer to stir the mixture.
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…the cooling bath is not adequate for effective cooling?
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Excessive heat generation
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Uncontrolled reaction occurs.
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Chemical spill with the risk of a fire
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Ensure that the cooling bath is large enough to accommodate a range of reaction flask depths for control of the cooling rate. Alternatively, use a suitable boiling-point solvent and reflux condenser for heat removal.
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…there is uncontrolled addition of the reagent?
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Excessive heat generation
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Uncontrolled reaction occurs.
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Chemical spill with the risk of a fire; substrate decomposition
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Add reagent slowly using an addition funnel. Control the addition to avoid excessive heat generation. For larger scale, monitor the internal reaction temperature and adjust the addition rate as needed to maintain the target temperature.
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…the reagent container is over-pressurized?
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The container can rupture.
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Possibility of reagent spill
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Control the pressure of the inert gas using Schlenk line techniques or an oil bubbler.
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…a syringe method is used for a large-scale reagent transfer?
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Multiple transfers are required.
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Possibility of reagent spill3
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For a large-scale reagent transfer (>25 mL), always use a cannula transfer method.
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…an insufficiently long needle is used to transfer the reagent from the bottle?
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Difficulty in withdrawing the reagent, and the bottle is tilted to withdraw the reagent
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Difficulty in withdrawing the reagent, and possibility of reagent spill
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Chemical spill with the risk of a fire
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Use a longer needle to withdraw the reagent, and eliminate the risk associated with tilting the bottle.
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…the substrate is contaminated with unknown impurities?
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There is a possibility of side-product formation.
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Runaway reaction with energetic release of chemicals
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Risk of chemical fire or explosion
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Any substrate used for the lithiation should be purified.
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…the addition funnel starts leaking during the alkyllithium addition?
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There is a loss of reagent.
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Possibility of a fire; incomplete reaction
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If using an addition funnel, thoroughly test it before use with pyrophoric reagents.
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…the concentration of the alkyllithium reagent is not accurate?
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The completeness of the reaction is unknown.
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Incomplete reaction, or excess alkyllithium will remain
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Incomplete reaction or fire hazard
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Always titrate reagents before use.
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…the reaction or quenching is incomplete?
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An unanticipated hazard remains during cleanup.
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The leftover reagent will react vigorously and unexpectantly
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Risk of fire or explosion hazard
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Many accidents happen with pyrophoric chemicals during workup and cleanup. Have a plan prepared for these often-overlooked steps.
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