LDTD Technology
1
A cooled Fiber-Coupled Laser Diode Array and a heatsink to disregard room temperature variations.
2
The Fiber Optic Collimator allows unmatchable thermal uniformity at the back of the LazWell plate without having to directly interact with the sample.
3
A low-volume sample (50nl-10μl) is deposited on the LazWell plate and then fully dried. The patented LazWell design allows for the formation of a precisely centered nanolayer on the well surface.
4
The rapid and robust pneumatic design ensures that the gas-phase neutral molecules are carried from the LazWell plate to the mass spectrometer inlet while sealing the transfer tube to avoid any sample loss.
5
The thermally desorbed neutral molecules are carried into a corona discharge region to undergo ionization.
6
High-efficiency protonation and strong resistance to ionic suppression characterize this type of ionization and is the result of the absence of solvent and mobile phase.
A cooled Fiber-Coupled Laser Diode Array and a heatsink to disregard room temperature variations.
The Fiber Optic Collimator allows unmatchable thermal uniformity at the back of the LazWell plate without having to directly interact with the sample.
A low-volume sample (50nl-10μl) is deposited on the LazWell plate and then fully dried. The patented LazWell design allows for the formation of a precisely centered nanolayer on the well surface.
The rapid and robust pneumatic design ensures that the gas-phase neutral molecules are carried from the LazWell plate to the mass spectrometer inlet while sealing the transfer tube to avoid any sample loss.
The thermally desorbed neutral molecules are carried into a corona discharge region to undergo ionization.
High-efficiency protonation and strong resistance to ionic suppression characterize this type of ionization and is the result of the absence of solvent and mobile phase.
