Abstract
Parallel (multi-sample) approaches, such as discrete combinatorial synthesis or continuous compositional-spread (CCS), can significantly increase the rate of materials discovery and process optimization. Here we review our generalized CCS method, based on pulsed-laser deposition, in which the synchronization between laser firing and substrate translation (behind a fixed slit aperture) yields the desired variations of composition and thickness. In situ alloying makes this approach applicable to the non-equilibrium synthesis of metastable phases. Deposition on a heater plate with a controlled spatial temperature variation can additionally be used for growth-temperature-dependence studies. Composition and temperature variations are controlled on length scales large enough to yield sample sizes sufficient for conventional characterization techniques (such as temperature-dependent measurements of resistivity or magnetic properties). This technique has been applied to various experimental studies, and we present here the results for the growth of electro-optic materials (SrxBa1-xNb 2O6) and magnetic perovskites (Sr 1-xCaxRuO3), and discuss the application to the understanding and optimization of catalysts used in the synthesis of dense forests of carbon nanotubes.
Original language | English |
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Pages (from-to) | 21-31 |
Number of pages | 11 |
Journal | Measurement Science and Technology |
Volume | 16 |
Issue number | 1 |
DOIs | |
State | Published - Jan 2005 |
Keywords
- Combinatorial materials synthesis
- Continuous compositional spread
- Pulsed-laser deposition
- Thin films