Michael Müller scite author profile

Remote sensing enables the quantification of tropical deforestation with high spatial resolution. This in-depth mapping has led to substantial advances in the analysis of continent-wide fragmentation of tropical forests. Here we identified approximately 130 million forest fragments in three continents that show surprisingly similar power-law size and perimeter distributions as well as fractal dimensions. Power-law distributions have been observed in many natural phenomena such as wildfires, landslides and earthquakes. The principles of percolation theory provide one explanation for the observed patterns, and suggest that forest fragmentation is close to the critical point of percolation; simulation modelling also supports this hypothesis. The observed patterns emerge not only from random deforestation, which can be described by percolation theory, but also from a wide range of deforestation and forest-recovery regimes. Our models predict that additional forest loss will result in a large increase in the total number of forest fragments-at maximum by a factor of 33 over 50 years-as well as a decrease in their size, and that these consequences could be partly mitigated by reforestation and forest protection.

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Analytic bond-order potential for bcc and fcc iron—comparison with established embedded-atom method potentials

Müller

Erhart

Albe

2007

J. Phys.: Condens. Matter

163

179

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A new analytic bond-order potential for iron is presented that has been fitted to experimental data and results from first-principles calculations. The angular-dependent functional form allows a proper description of a large variety of bulk, surface and defect properties, including the Bain path, phonon dispersions, defect diffusivities and defect formation energies. By calculating Gibbs free energies of body-centred cubic (bcc) and face-centred cubic (fcc) iron as a function of temperature, we show that this potential is able to reproduce the transitions from α-iron to γ-iron and δ-iron before the melting point. The results are compared to four widely used embedded-atom-method potentials for iron.

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Lattice Monte Carlo simulations of FePt nanoparticles: Influence of size, composition, and surface segregation on order-disorder phenomena

2005

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1550-nm High-Speed Short-Cavity VCSELs

Müller

Hofmann

Gründl

et al. 2011

IEEE J. Select. Topics Quantum Electron.

138

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Surface structure and composition of flat titanium thin films as a function of film thickness and evaporation rate

Cai¹,

Müller²,

Bossert³

et al. 2005

Applied Surface Science

143

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Michael Müller

Global patterns of tropical forest fragmentation

Analytic bond-order potential for bcc and fcc iron—comparison with established embedded-atom method potentials

Lattice Monte Carlo simulations of FePt nanoparticles: Influence of size, composition, and surface segregation on order-disorder phenomena

1550-nm High-Speed Short-Cavity VCSELs

Surface structure and composition of flat titanium thin films as a function of film thickness and evaporation rate

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