In situ transmission electron microscopy reveals that an atomically thin crystalline phase at the surface of liquid Au-Si is stable over an unexpectedly wide range of conditions. By measuring the surface structure as a function of liquid temperature and composition, a simple thermodynamic model is developed to explain the stability of the ordered phase. The presence of surface ordering plays a key role in the pathway by which the Au-Si eutectic solidifies and also dramatically affects the catalytic properties of the liquid, explaining the anomalously slow growth kinetics of Si nanowires at low temperature. A strategy to control the presence of the surface phase is discussed, using it as a tool in designing strategies for nanostructure growth

Gamalski, AD

Hofmann, S

Panciera, F

Reuter, MC

Ross, FM

Stach, EA

Tersoff, J

Zakharov, D

English

Panciera, Federico

Tersoff, Jerry

Gamalski, Andrew D

Reuter, Mark C

Zakharov, Dmitri

Stach, Eric A

Hofmann, Stephan

Ross, Frances M

Apollo (Cambridge)

Surface Crystallization of Liquid Au-Si and Its Impact on Catalysis.

International audienceIn situ transmission electron microscopy reveals that an atomically thin crystalline phase at the surface of liquid Au–Si is stable over an unexpectedly wide range of conditions. By measuring the surface structure as a function of liquid temperature and composition, a simple thermodynamic model is developed to explain the stability of the ordered phase. The presence of surface ordering plays a key role in the pathway by which the Au–Si eutectic solidifies and also dramatically affects the catalytic properties of the liquid, explaining the anomalously slow growth kinetics of Si nanowires at low temperature. A strategy to control the presence of the surface phase is discussed, using it as a tool in designing strategies for nanostructure growth

Gamalski, Andrew,

Reuter, Mark,

Stach, Eric,

Ross, Frances,

Hal-Diderot

Surface Crystallization of Liquid Au-Si and Its Impact on Catalysis

Archive Ouverte en Sciences de l'Information et de la Communication

In situ transmission electron microscopy reveals that an atomically thin crystalline phase at the surface of liquid Au–Si is stable over an unexpectedly wide range of conditions. By measuring the surface structure as a function of liquid temperature and composition, a simple thermodynamic model is developed to explain the stability of the ordered phase. The presence of surface ordering plays a key role in the pathway by which the Au–Si eutectic solidifies and also dramatically affects the catalytic properties of the liquid, explaining the anomalously slow growth kinetics of Si nanowires at low temperature. A strategy to control the presence of the surface phase is discussed, using it as a tool in designing strategies for nanostructure growth

CUED - Cambridge University Engineering Department

Surface Crystallization of Liquid Au–Si and Its Impact on Catalysis

https://www.repository.cam.ac.uk/bitstream/handle/1810/287107/Panciera_SurfaceOrdering_Revised_Manuscript_AdvMat-accepted.pdf?sequence=1&isAllowed=y

Surface Crystallization of Liquid Au-Si and Its Impact on Catalysis.

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Apollo (Cambridge)

Hal-Diderot

Archive Ouverte en Sciences de l'Information et de la Communication

CUED - Cambridge University Engineering Department