The study of biological responses to specific wavelengths dates back to the late 19th century. Research primarily focused on assessing photodamage from solar radiation using broad-band lamps and narrow filters. These studies quantified effects such as cell viability, production of
erythema, vitamin D3 degradation, DNA changes, and
skin cancer appearance. The first
biological action spectrum was recorded by
Engelmann, who used a prism to produce different colors of light and then illuminated
cladophora in a bacteria suspension. He discovered the effects of different light wavelengths on
photosynthesis, marking the first recorded action spectrum of photosynthesis. Critical evaluations of active wavelength regions in these studies helped identify contributing
chromophores to processes such as photosynthesis. These chromophores are key for converting
solar energy into
chemical energy, with their absorption closely matching the rate of photosynthesis, usually determined by oxygen production or
carbon fixation. This correlation led to the discovery of
chlorophyll as a key chromophore in plant growth. Such studies have also been instrumental in identifying DNA as the core genetic material, key wavelengths leading to skin cancer, the transparent optical window of biological tissue, and the influence of color on circadian rhythms. In the late 20th century, action spectra became essential in developing optical devices for
photocatalysis and
photovoltaics, particularly in measuring
photocurrent efficiency at various wavelengths. These studies have been vital in understanding primary contributors to photocurrent generation, leading to advancements in materials, morphologies, and device designs for improved solar energy capture and utilization. In photochemistry, action spectra have been mainly used in
photodissociation studies. These involve a monochromatic light source, often a laser, coupled with a
mass spectrometer to record wavelength-dependent ion dissociation in gaseous phases. These spectra help identify contributing chromophores in molecular systems, characterize
radical generation and unstable
isomers, and understand higher state electron dynamics. The field underwent a transformation when a team led by
Barner-Kowollik and Gescheidt recorded the first modern-day photochemical action plot using a tuneable monochromatic
nanosecond pulsed
laser system, discovering a strong mismatch between photochemical reactivity and absorptivity and marking a critical advancement in mapping wavelength-dependent conversions in photoinduced polymerizations. == Experimental setup ==