Professor Stephen Blundell

Magnetic order in quasi-two-dimensional molecular magnets investigated with muon-spin relaxation

Physical Review B - Condensed Matter and Materials Physics 84:6 (2011)

Authors:

AJ Steele, T Lancaster, SJ Blundell, PJ Baker, FL Pratt, C Baines, MM Conner, HI Southerland, JL Manson, JA Schlueter

Abstract:

We present the results of a muon-spin relaxation (μ+SR) investigation into magnetic ordering in several families of layered quasi-two-dimensional molecular antiferromagnets based on transition-metal ions such as S=12 Cu2+ bridged with organic ligands such as pyrazine. In many of these materials magnetic ordering is difficult to detect with conventional magnetic probes. In contrast, μ+SR allows us to identify ordering temperatures and study the critical behavior close to TN. Combining this with measurements of in-plane magnetic exchange J and predictions from quantum Monte Carlo simulations we may assess the degree of isolation of the 2D layers through estimates of the effective inter-layer exchange coupling and in-layer correlation lengths at TN. We also identify the likely metal-ion moment sizes and muon stopping sites in these materials, based on probabilistic analysis of the magnetic structures and of muon-fluorine dipole-dipole coupling in fluorinated materials. © 2011 American Physical Society.

Probing magnetic order in LiMPO4, M = Ni, Co, Fe and lithium diffusion in LixFePO4

(2011)

Authors:

PJ Baker, I Franke, FL Pratt, T Lancaster, D Prabhakaran, W Hayes, SJ Blundell

Proximal magnetometry of monolayers of magnetic moments

(2011)

Authors:

Z Salman, SJ Blundell

The statistical mechanics of community assembly and species distribution

New Phytologist 191:3 (2011) 819-827

Authors:

CK Kelly, SJ Blundell, MG Bowler, GA Fox, PH Harvey, MR Lomas, F Ian Woodward

Abstract:

Theoretically, communities at or near their equilibrium species number resist entry of new species. Such 'biotic resistance' recently has been questioned because of successful entry of alien species into diverse natural communities. Data on 10409 naturalizations of 5350 plant species over 16 sites dispersed globally show exponential distributions both for species over sites and for sites over number of species shared. These exponentials signal a statistical mechanics of species distribution, assuming two conditions. First, species and sites are equivalent, either identical ('neutral') or so complex that the chance a species is in the right place at the right time is vanishingly small ('idiosyncratic'); the range of species and sites in our data disallows a neutral explanation. Secondly, the total number of naturalizations is fixed in any era by a 'regulator'. Previous correlation of species naturalization rates with net primary productivity over time suggests that the regulator is related to productivity. We conclude that biotic resistance is a moving ceiling, with resistance controlled by productivity. The general observation that the majority of species occur naturally at only a few sites, and only a few species occur at many sites, now has a quantitative (exponential) character, offering the study of species' distributions a previously unavailable rigor. © 2011 The Authors. New Phytologist © 2011 New Phytologist Trust.

The statistical mechanics of community assembly and species distribution.

New Phytol 191:3 (2011) 819-827

Authors:

Colleen K Kelly, Stephen J Blundell, Michael G Bowler, Gordon A Fox, Paul H Harvey, Mark R Lomas, F Ian Woodward

Abstract:

• Theoretically, communities at or near their equilibrium species number resist entry of new species. Such 'biotic resistance' recently has been questioned because of successful entry of alien species into diverse natural communities. • Data on 10,409 naturalizations of 5350 plant species over 16 sites dispersed globally show exponential distributions both for species over sites and for sites over number of species shared. These exponentials signal a statistical mechanics of species distribution, assuming two conditions. First, species and sites are equivalent, either identical ('neutral') or so complex that the chance a species is in the right place at the right time is vanishingly small ('idiosyncratic'); the range of species and sites in our data disallows a neutral explanation. Secondly, the total number of naturalizations is fixed in any era by a 'regulator'. • Previous correlation of species naturalization rates with net primary productivity over time suggests that the regulator is related to productivity. • We conclude that biotic resistance is a moving ceiling, with resistance controlled by productivity. The general observation that the majority of species occur naturally at only a few sites, and only a few species occur at many sites, now has a quantitative (exponential) character, offering the study of species' distributions a previously unavailable rigor.