The development of the valid strategy to enhance laser
desorption/ionization
efficiency gives rise to widespread concern in surface-assisted laser
desorption/ionization mass spectrometry (SALDI-MS) technology. Herein,
a hybrid of Au NP-decorated graphdiyne (Au/GDY) was fabricated and
employed as the SALDI-MS matrix for the first time, and a mechanism
based on photothermal and photochemical energy conversions was proposed
to understand LDI processes. Given theoretical simulations and microstructure
characterizations, it was revealed that the formation of a coupled
thermal field and internal electric field endow the as-prepared Au/GDY
matrix with superior desorption and ionization efficiency, respectively.
Moreover, laser-induced matrix ablation introduced strain and defect
level into the Au/GDY hybrid, suppressing the recombination of charge
carriers and thereby facilitating analyte ionization. The optimized
Au/GDY matrix allowed for reliable detection of trace sulfacetamide
and visualization of exogenous/endogenous components in biological
tissues. This work offers an integrated solution to promote LDI efficiency
based on collaborative photothermal conversion and internal electric
field, and may inspire the design of novel semiconductor-based surface
matrices.