R. R. Weerasiri scite author profile

The nuclear magnetic moment of the ground state of 57 Cu(I π = 3/2 − , T 1/2 = 196.3 ms) has been measured to be |µ( 57 Cu)| = (2.00 ± 0.05)µN using the β-NMR technique. Together with the known magnetic moment of the mirror partner 57 Ni, the spin expectation value was extracted as Σσz = −0.78 ± 0.13. This is the heaviest isospin T = 1/2 mirror pair above the 40 Ca region for which both ground state magnetic moments have been determined. Discrepancy between present results and shell model calculations in full f p shell giving µ( 57 Cu) ∼ 2.4µN and Σσz ∼ 0.5 implies significant shell breaking at 56 Ni with the neutron number N = 28. The magnetic moment is one of the important fundamental properties of the nucleus and provides key information to understand nuclear structure, especially ideas built on core polarization and the meson exchange effects in the shell model. While the magnetic moments near the stability line in the nuclear chart are well known, we have only limited information on the magnetic moments far from the stability line. Some of the challenges facing ground state nuclear moment measurements include the small spin polarization and low cross sections encountered in the production mechanism for nuclei far removed from the stability line. It is important, however, to go far from the stability line in order to test predictive powers of theoretical models and to find possible variations of nuclear structure from the stability line.In this Letter, we report the first measurement of the magnetic moment of 57 Cu. Since 57 Cu has one proton outside of the 56 Ni core and the magnetic moment of T = 1/2 mirror partner 57 Ni is known, the current result completes the mirror pair and contributes important information for this shell region. The difficulties in the small polarization and low cross section were overcome by using a proton pick up reaction of an intermediate-energy primary beam. The small value for the 57 Cu magnetic moment, discussed later in this paper, implies possible shell breaking at the neutron number N = 28.The magnetic moment can be expressed as the sum of isoscalar Σµ 0 and isovector Σµ z components aswhere l and σ are the orbital and spin angularmomentum operators of the nucleon, respectively, τ is the isospin operator, µ p and µ n are the magnetic moments of free proton and neutron, respectively, and the sum is over all nucleons. The isovector Σµ z part is proportional to the isospin, T z , and changes its sign for T = ±T z . Provided that isospin is a good quantum number, the spin expectation value Σσ z , which is a contribution from nucleon spins to the magnetic moment, can be extracted [1] from the sum of mirror pair magnetic moments aswhere the total spin is I = Σl z + Σσ z /2. In the sd shell, all of the ground state magnetic moments of T = 1/2 mirror nuclei have been measured and there remain several T = 1 and 3/2 isospin multiplets to be measured. There exists, however, virtually no information regarding similar T = 1/2 pairs in the f p shell. A systematic trend of the spin expect...

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Experimental and numerical study of shape-stable phase-change nanocomposite toward energy-efficient building constructions

Sayyar

Weerasiri

Soroushian

et al. 2014

Energy and Buildings

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Inherently adaptive polymer nanocomposites

Sayayr

Weerasiri

Balachandra

et al. 2014

J of Applied Polymer Sci

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A new class of inherently adaptive polymer nanocomposites is developed where stress‐enabled redox reactions are used in the context of a solid polymer electrolyte to form deposits which render mechanical strengthening effects. Experimental investigations were conducted to provide insight into this self‐adaptation phenomenon. Results of tests conducted on bolted composite joints demonstrated the occurrence of this self‐adaptation phenomenon. Experiments were also performed on cracked composite specimens where the potential of the self‐adaptation phenomenon to repair cracks was demonstrated. © 2014 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2014, 131, 40620.

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Amperometric Detection and Quantification of Nitrate Ions Using a Highly Sensitive Nanostructured Membrane Electrocodeposited Biosensor Array

Gokhale

Weerasiri

et al. 2015

Electroanalysis

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2,18‐Bis(diphenylphosphino)porphyrins undergo peripheral cyclometalation with group 10 transition‐metal salts to afford the corresponding porphyrin‐based PCP pincer complexes. The porphyrinic plane and the PCP‐pincer unit are apparently coplanar, with small strain. The catalytic activities of the porphyrin‐based pincer complexes at the periphery were investigated in the allylation of benzaldehyde with allylstannane and in the 1,4‐reduction of chalcone to discover the electronic interplay between the inner metal and the outer metal in catalysis.

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R. R. Weerasiri

Nuclear Magnetic Moment of theCu57Ground State

Experimental and numerical study of shape-stable phase-change nanocomposite toward energy-efficient building constructions

Inherently adaptive polymer nanocomposites

Amperometric Detection and Quantification of Nitrate Ions Using a Highly Sensitive Nanostructured Membrane Electrocodeposited Biosensor Array

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