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• Journal article
  El Khoury K, Vollum R, Izzuddin B, Forth Jet al., 2026,

  Experimental investigation into cracking in edge restrained concrete walls (vol 345, 121536, 2025)

  , ENGINEERING STRUCTURES, Vol: 347, ISSN: 0141-0296
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• Journal article
  Caillet AH, Phillips ATM, Carty C, Farina D, Modenese Let al., 2026,

  Hill-type models of skeletal muscle and neuromuscular actuators: a systematic review

  , IEEE Reviews in Biomedical Engineering, Vol: 19, Pages: 159-181, ISSN: 1937-3333

  Backed by a century of research and development, Hill-type models of skeletal muscle, often including a muscle-tendon complex and neuromechanical interface, are widely used for countless applications. Lacking recent comprehensive reviews, the field of Hill-type modeling is, however, dense and hard-to-explore, with detrimental consequences on innovation. Here we present the first systematic review of Hill-type muscle modeling. It aims to clarify the literature by detailing its contents and critically discussing the state-of-the-art by identifying the latest advances, current gaps, and potential future directions in Hill-type modeling. For this purpose, fifty-eight criteria-abiding Hill-type models were assessed according to a completeness evaluation, which identified the modelled muscle properties, and a modeling evaluation, which considered the level of validation and reusability of the models, as well as their modeling strategy and calibration. It is concluded that most models (1) do not significantly advance beyond historical foundational standards, (2) neglect the importance of parameter identification, (3) lack robust validation, and (4) are not reusable in other studies. Besides providing a convenient tool supported by extensive supplementary materials for navigating the literature, the results of this review highlight the need for global recommendations in Hill-type modeling to optimize inter-study consistency, knowledge transfer, and model reusability.

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• Journal article
  Shi D, Malaga-Chuquitaype C, Wang X, Marano GC, Demartino Cet al., 2026,

  Glubam roof trusses: Uncertainty quantification and partial safety factors calibration based on Bayesian methods

  , RELIABILITY ENGINEERING & SYSTEM SAFETY, Vol: 265, ISSN: 0951-8320
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• Journal article
  El Khoury K, Vollum R, Izzuddin B, Forth Jet al., 2025,

  Experimental investigation into cracking in edge restrained concrete walls

  , Engineering Structures, Vol: 345, ISSN: 0141-0296

  The paper describes an experimental investigation into cracking in edge-restrained reinforced concrete walls cast onto concrete bases. The aim of the investigation was to study the mechanics of cracking in relatively thin edge-restrained walls (< ∼ 500 mm) in which through thickness temperature variations due to heat of hydration can be neglected. Twelve walls, each 5.2 m in length, but with varying thickness, height, concrete mix design, reinforcement, and formwork insulation were monitored over a period of at least 3 months. Detailed measurements were made of the temperature rise during heat of hydration, strain and crack width. The paper describes the experimental results in detail, including the development of cracking with time. The measured restrained strains, time of cracking and crack widths are compared with those calculated with EC2–04, EC2–23 and Ciria Report C766 which all adopt the same unrealistic model for calculation of crack width. EC2–04 gives the greatest crack widths and C766 the least due to the lower adopted restraint factor. Significantly, C766 was found to greatly underestimate the maximum measured crack widths with EC2–04 and EC2–23 providing more realistic estimates. Based on the observed cracking behaviour, the paper proposes a simplified mechanical model for the calculation of crack width in relatively thin edge-restrained walls.

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• Journal article
  Chen Y, Málaga-Chuquitaype C, Zhou F, Gardner Let al., 2025,

  Predicting local buckling in steel members under cyclic loads: a strain-based approach using the CSM

  , Engineering Structures, Vol: 345, ISSN: 0141-0296

  A new approach, based on the Continuous Strength Method (CSM), is presented for the prediction of cross-section failure through inelastic local buckling in steel members under cyclic loading. Cross-section local buckling failure is predicted to occur when a prescribed strain limit is reached; the effect of loading history is accounted for by considering the cumulative strain from each loading cycle. The strain limit is related to the cross-section slenderness, which is based on the local buckling behaviour of the full cross-section, rather than the individual plate width-to-thickness ratios, making it suitable for different section profiles (e.g., hollow sections and I-sections). Finite element models are established, validated and used to conduct parametric studies, covering a series of steel grades, a wide range of cross-section slendernesses and various cyclic axial loading protocols. The resulting numerical data sets are employed to develop a means of rationally considering the contribution of both the compressive and tensile strain ranges in each loading cycle to cross-section failure. The suitability of the newly proposed method is verified against experimental results on beam-columns with hollow sections and I-sections under cyclic loading, as well as numerical results. The findings indicate that the cumulative deformation capacity and local buckling failure of steel cross-sections can be accurately predicted using the developed strain-based design method. The method can be applied in the inelastic analysis of structures under seismic loading and in the seismic design of steel cross-sections.

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• Journal article
  Bomben L, Macorini L, Chisari C, Izzuddin Bet al., 2025,

  Mesoscale and macroscale modelling for nonlinear analysis of masonry wall structures under cyclic loading

  , Structures, Vol: 82, ISSN: 2352-0124

  The paper investigates the nonlinear response of unreinforced masonry wall components under seismic loading. Finite element models formulated according to different scales of representation for masonry are compared, focusing on the hysteretic behaviour under in-plane cyclic loading up to collapse. To this aim, brick-masonry wall structures, including two panels with different aspect ratios and a large two-storey perforated wall, as well as block-masonry wall panels subjected to various vertical loads, all previously tested under horizontal cyclic loading, are analysed. The results of macro and mesoscale simulations are compared against the experimental findings to assess the ability to represent strength and stiffness degradation and the amount of dissipated energy. Emphasis is laid upon the objectivity of the definition and calibration of the model material parameters to assess how their selection affects the response predictions. The comparison highlights differences in predictive accuracy, numerical robustness, variability of results, and computational cost. The results show that the macroscale approach adopted herein, despite its computational robustness, yields widely variable results and may significantly deviate from experimental observations. In contrast, the mesoscale results appear less scattered and accurate, but the computational burden is far more significant.

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• Journal article
  Dai R, Gardner L, Wadee MA, 2025,

  Stability and design of fixed-ended stainless steel unequal-leg angle section columns

  , Structures, Vol: 82, ISSN: 2352-0124

  The stability and design of fixed-ended stainless steel unequal-leg angle section members subjected to axial compression are studied herein. The critical buckling behaviour is first described; existing experimental data on stainless steel and aluminium alloy unequal-leg angle section columns collected from the literature are then employed to validate nonlinear finite element models developed within the commercial package ABAQUS. A comprehensive numerical parametric study is subsequently conducted considering members made from the three main families of stainless steel (austenitic, ferritic and duplex) with a broad spectrum of geometric configurations and slenderness values. The behaviour and load-carrying capacity of the studied columns are shown to depend not only on the global slenderness, but also on the ratio of the elastic torsional-flexural to minor-axis flexural buckling loads. The collected experimental data and generated numerical results are employed to evaluate the ultimate resistance predictions given by the current Eurocode 3 design provisions, revealing an excessive level of conservatism, particularly for cases where torsional-flexural buckling is dominant. A new design approach for fixed-ended stainless steel unequal-leg angle section columns, suitable for incorporation into future revisions of Eurocode 3, is subsequently proposed, reflecting the aforementioned observations. The proposed approach significantly improves the accuracy and consistency of the resistance predictions compared to the current design provisions. Finally, a reliability analysis is conducted following the EN 1990 procedure, resulting in a recommended partial safety factor of 1.1.

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• Journal article
  Chan HU, Walport F, Slack H, Wadee MA, Gardner Let al., 2025,

  Practical rules for defining initial geometric imperfections for in-plane stability design of steel frames

  , Structures, Vol: 82, ISSN: 2352-0124

  The appropriate modelling of initial imperfections, in terms of both amplitude and shape/direction, is a key challenge in the design of structures by geometrically and materially nonlinear analysis with imperfections (GMNIA). While recent research has addressed the amplitude aspect of imperfection modelling, there remains a lack of clear guidance for determining the appropriate imperfection shape. This is tackled herein through the establishment of comprehensive rules for introducing global sway and member bow imperfections in the in-plane stability design of steel frames. The proposed rules cover the two most commonly used imperfection definition approaches – the direct definition (DD) method and the elastic buckling mode (EBM) method. In the DD method recommended herein, the directions of global sway and member bow imperfections are introduced following a set of prescribed rules. Two EBM methods are recommended. In the first EBM method, the ultimate capacity is taken as the lowest among n values obtained by considering the first n buckling modes as imperfection shapes individually, with n = 6 recommended. In the second EBM method, the bow and sway components of the imperfection shape are determined separately from different LBA in which loads are applied on the key load paths. The bow components are established by combining the first buckling mode for each key vertical and horizontal load path, while the sway component is based on the first mode – provided it is a sway mode – obtained from an LBA considering the maximum gravity load case. The consequences of using no imperfections are also explored. The accuracy of the proposed methods is verified based on a series of moment frames and braced frames considering both regular and irregular configurations.

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• Journal article
  Dai R, Gardner L, Wadee MA, 2025,

  Behaviour, numerical modelling and design of fixed-ended unequal-leg angle section steel columns

  , Journal of Constructional Steel Research, Vol: 235, ISSN: 0143-974X

  The mechanical behaviour and design of fixed-ended unequal-leg angle section steel members subjected to axial compression are studied herein. The mechanical response of unequal-leg angle section columns is first described, with a particular emphasis on the relationship between torsional and local buckling, alongside the important transition from equal-leg to unequal-leg angle behaviour. Existing experimental data on unequal-leg angle section steel columns are then employed to validate numerical models developed within the commercial finite element package ABAQUS. A comprehensive parametric study is subsequently conducted that encompasses a broad spectrum of geometric configurations and global slenderness values. The mechanical behaviour and ultimate resistance of fixed-ended unequal-leg angle section columns are shown to be dependent on not only the global slenderness, but also on the ratio of the elastic torsional-flexural to minor-axis flexural buckling loads. The existing experimental data alongside the numerical parametric study results are employed to evaluate the resistance predictions given by the current Eurocode 3 design provisions, revealing an excessive level of conservatism. Finally, a new design approach for fixed-ended unequal-leg angle section steel columns, suitable for incorporation into future revisions of Eurocode 3, is proposed that significantly improves the accuracy and consistency of the resistance predictions. A reliability analysis of the proposed design approach is conducted in accordance with the procedure within EN 1990, resulting in a recommended partial safety factor γ_M₁=1.0.

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• Journal article
  Fang Q, Grosman S, Pullen A, Macorini L, Izzuddin Bet al., 2025,

  3D digital image correlation for field assessment of masonry arch bridges

  , Construction and Building Materials, Vol: 494, ISSN: 0950-0618

  Masonry arch bridges with observed or suspected defects require effective structural health monitoring to ensure their safety under increasing traffic loads. Traditional methods, such as visual inspections, provide only qualitative assessments and do not capture the variations in key local and global response characteristics under traffic loading. More advanced structural health monitoring techniques can measure the variations in displacements and strain fields under traffic; however, they typically require contact sensors and partial or complete occupation of the monitored spans. This study examines, for the first time, the application of 3D Digital Image Correlation (DIC) as a non-invasive method for monitoring masonry arch bridges in the field. It offers a refined 3D DIC monitoring technique specifically designed for such structures under traffic loading, providing improved accuracy through various error mitigation strategies. Using a case study of the Mill Road Viaduct, a multi-span railway bridge in Lewisham (London, UK), 3D DIC effectively captured full-field displacements and crack openings caused by live traffic loads. The results revealed significant 3D effects, particularly in the arch barrel, and confirmed crack development in different directions, highlighting the superiority of 3D DIC monitoring over the conventional 2D DIC counterpart. The accuracy of the 3D DIC measurements was validated against 3D scanning data, demonstrating its reliability for bridge monitoring applications. Despite its advantages, factors such as camera stability, environmental noise and calibration complexities are identified in this paper as critical challenges that should be addressed for successful deployment in the field. This study highlights 3D DIC as a real-time, high-resolution structural monitoring tool, offering valuable insights for proactive maintenance strategies.

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