Mechanically
responsive crystals have been increasingly explored,
mainly based on photoisomerization. However, photoisomerization has
some disadvantages for crystal actuation, such as a slow actuation
speed, no actuation of thick crystals, and a narrow wavelength range.
Here we report photothermally driven fast-bending actuation and simulation
of a salicylideneaniline derivative crystal with an o-amino substituent in enol form. Under ultraviolet (UV) light irradiation,
these thin (<20 μm) crystals bent but the thick (>40 μm)
crystals did not due to photoisomerization; in contrast, thick crystals
bent very quickly (in several milliseconds) due to the photothermal
effect, even by visible light. Finally, 500 Hz high-frequency bending
was achieved by pulsed UV laser irradiation. The generated photothermal
energy was estimated based on the photodynamics using femtosecond
transient absorption. Photothermal bending is caused by a nonsteady
temperature gradient in the thickness direction due to the heat conduction
of photothermal energy generated near the crystal surface. The temperature
gradient was calculated based on the one-dimensional nonsteady heat
conduction equation to simulate photothermally driven crystal bending
successfully. Most crystals that absorb light have their own photothermal
effects. It is expected that the creation and design of actuation
of almost all crystals will be possible via the photothermal effect,
which cannot be realized by photoisomerization, and the potential
and versatility of crystals as actuation materials will expand in
the near future.