Efficient simulation of tissue-like P systems by transition cell-like P systems

In this paper, the conventional database type fast forward solver for efficient simulation of eddy current testing (ECT) signals is upgraded by using an advanced multi-media finite element (MME) at the crack edge for treating inversion of complex shaped crack. Because the analysis domain is limited at the crack region, the fast forward solver can significantly improve the numerical accuracy and efficiency once the coefficient matrices of the MME can be properly calculated. Instead of the Gauss point classification, a new scheme to calculate the coefficient matrix of the MME is proposed and implemented to upgrade the ECT fast forward solver. To verify its efficiency and the feasibility for reconstruction of complex shaped crack, several cracks were reconstructed through inverse analysis using the new MME scheme. The numerical results proved that the upgraded fast forward solver can give better accuracy for simulating ECT signals, and consequently gives better crack profile reconstruction.

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Symmetry Breaking and the Turn-On Fluorescence of Small, Highly Strained Carbon Nanohoops

10.26434/chemrxiv.7580027.v1 ◽

2019 ◽

Author(s):

Terri Lovell ◽

Curtis Colwell ◽

Lev N. Zakharov ◽

Ramesh Jasti

Keyword(s):

Symmetry Breaking ◽

Theoretical Work ◽

P Systems ◽

Quantum Yields ◽

Size Dependent ◽

New Class ◽

Carbon Carbon Bond ◽

Conjugated Macrocycles ◽

Structural Manipulation ◽

Highly Strained

[n]Cycloparaphenylenes, or “carbon nanohoops,” are unique conjugated macrocycles with radially oriented p-systems similar to those in carbon nanotubes. The centrosymmetric nature and conformational rigidity of these molecules lead to unusual size-dependent photophysical characteristics. To investigate these effects further and expand the family of possible structures, a new class of related carbon nanohoops with broken symmetry is disclosed. In these structures, referred to as meta[n]cycloparaphenylenes, a single carbon-carbon bond is shifted by one position in order to break the centrosymmetric nature of the parent [n]cycloparaphenylenes. Advantageously, the symmetry breaking leads to bright emission in the smaller nanohoops, which are typically non-fluorescent due to optical selection rules. Moreover, this simple structural manipulation retains one of the most unique features of the nanohoop structures-size dependent emissive properties with relatively large extinction coefficents and quantum yields. Inspired by earlier theoretical work by Tretiak and co-workers, this joint synthetic, photophysical, and theoretical study provides further design principles to manipulate the optical properties of this growing class of molecules with radially oriented p-systems.

Download Full-text

Symmetry Breaking and the Turn-On Fluorescence of Small, Highly Strained Carbon Nanohoops

10.26434/chemrxiv.7580027 ◽

2019 ◽

Author(s):

Terri Lovell ◽

Curtis Colwell ◽

Lev N. Zakharov ◽

Ramesh Jasti

Keyword(s):

Symmetry Breaking ◽

Theoretical Work ◽

P Systems ◽

Quantum Yields ◽

Size Dependent ◽

New Class ◽

Carbon Carbon Bond ◽

Conjugated Macrocycles ◽

Structural Manipulation ◽

Highly Strained

[n]Cycloparaphenylenes, or “carbon nanohoops,” are unique conjugated macrocycles with radially oriented p-systems similar to those in carbon nanotubes. The centrosymmetric nature and conformational rigidity of these molecules lead to unusual size-dependent photophysical characteristics. To investigate these effects further and expand the family of possible structures, a new class of related carbon nanohoops with broken symmetry is disclosed. In these structures, referred to as meta[n]cycloparaphenylenes, a single carbon-carbon bond is shifted by one position in order to break the centrosymmetric nature of the parent [n]cycloparaphenylenes. Advantageously, the symmetry breaking leads to bright emission in the smaller nanohoops, which are typically non-fluorescent due to optical selection rules. Moreover, this simple structural manipulation retains one of the most unique features of the nanohoop structures-size dependent emissive properties with relatively large extinction coefficents and quantum yields. Inspired by earlier theoretical work by Tretiak and co-workers, this joint synthetic, photophysical, and theoretical study provides further design principles to manipulate the optical properties of this growing class of molecules with radially oriented p-systems.

Download Full-text