Roughness Scaling in Cyclical Surface Growth

The scaling behavior of cyclical growth (e.g. cycles of alternating deposition and desorption primary processes) is investigated theoretically and probed experimentally. The scaling approach to kinetic roughening is generalized to cyclical processes by substituting the time by the number of cycles \...

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Bibliographic Details
Published in:arXiv.org 2001-05
Main Authors: Raychaudhuri, Subhadip, Shapir, Yonathan, Foster, David G, Jorne, Jacob
Format: Article
Language:English
Subjects:
Accelerated tests
Computer simulation
Dissolution
Electrodissolution
Exponents
Nonlinear analysis
Rechargeable batteries
Roughening
Roughness
Scaling
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Summary:The scaling behavior of cyclical growth (e.g. cycles of alternating deposition and desorption primary processes) is investigated theoretically and probed experimentally. The scaling approach to kinetic roughening is generalized to cyclical processes by substituting the time by the number of cycles \(n\). The roughness is predicted to grow as \(n^{\beta}\) where \(\beta\) is the cyclical growth exponent. The roughness saturates to a value which scales with the system size \(L\) as \(L^{\alpha}\), where \(\alpha\) is the cyclical roughness exponent. The relations between the cyclical exponents and the corresponding exponents of the primary processes are studied. Exact relations are found for cycles composed of primary linear processes. An approximate renormalization group approach is introduced to analyze non-linear effects in the primary processes. The analytical results are backed by extensive numerical simulations of different pairs of primary processes, both linear and non-linear. Experimentally, silver surfaces are grown by a cyclical process composed of electrodeposition followed by 50% electrodissolution. The roughness is found to increase as a power-law of \(n\), consistent with the scaling behavior anticipated theoretically. Potential applications of cyclical scaling include accelerated testing of rechargeable batteries, and improved chemotherapeutic treatment of cancerous tumors.
ISSN:2331-8422
DOI:10.48550/arxiv.0105483