The advantages of triphenylsilanol as a catalyst in organic synthesis are mainly reflected in the following aspects:

Efficient catalytic performance: triphenylsilanol and hydrogen-containing silicone oil can undergo dehydrogenation reaction under appropriate conditions (such as catalyzed by chloroplatinic acid, the reaction temperature is 110°C), and when the mass ratio between the two is not greater than 2.20, Triphenylsilanol can be completely converted after the reaction. This indicates that triphenylsilanol has higher activity and selectivity in catalytic reactions.
Good stability: The melting point of triphenylsilanol is 150-153°C, the boiling point is 389°C (at 760mmHg), and the flash point is greater than 200°C.

These physical properties enable it to remain stable during organic synthesis. Good stability, not easy to decompose or volatilize.
Wide range of applications: Triphenylsilanol can not only be used as a catalyst, but also as a reagent and intermediate in a variety of organic synthesis reactions. For example, it is widely used in the synthesis of pharmaceutical intermediates or other polymers, reflecting its broad application value in the field of organic synthesis.

Easy to handle and store: Triphenylsilanol is white granular or powdery crystal, insoluble in water but soluble in general chemical solvents. This makes it easy to handle and store in laboratories and industrial production, reducing operational difficulty and cost.

In summary, triphenylsilanol has the advantages of high efficiency, stability, wide application and easy handling as a catalyst in organic synthesis. These advantages make triphenylsilanol have an important position and application value in the field of organic synthesis.