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1. Hubble tension and gravitational self-interaction

   https://doi.org/10.1088/1402-4896/ad570f  

   Sargent, Corey; Clark, William; Deur, Alexandre; Terzić, Balša (June 2024, Physica Scripta)

   Abstract One of the most important problems vexing the ΛCDM cosmological model is the Hubble tension. It arises from the fact that measurements of the present value of the Hubble parameter performed with low-redshift quantities, e.g. the Type IA supernova, tend to yield larger values than measurements from quantities originating at high-redshift, e.g. fits of cosmic microwave background radiation. It is becoming likely that the discrepancy, currently standing at 5σ, is not due to systematic errors in the measurements. Here we explore whether the self-interaction of gravitational fields in General Relativity, which are traditionally neglected when studying the evolution of the Universe, can contribute to explaining the tension. We find that with field self-interaction accounted for, both low- and high-redshift data aresimultaneouslywell-fitted, thereby showing that gravitational self-interaction yield consistentH₀values when inferred from SnIA and cosmic microwave background observations. Crucially, this is achieved without introducing additional parameters. 

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2. Ductile Failure Under Combined Tension and Shear

   https://doi.org/10.1088/1742-6596/1063/1/012163  

   Chen, K; Scales, M; Kyriakides, S (July 2018, Journal of Physics: Conference Series)
3. Ultralight scalar decay and the Hubble tension

   https://doi.org/10.1088/1475-7516/2020/10/028  

   Gonzalez, Mark; Hertzberg, Mark P.; Rompineve, Fabrizio (October 2020, Journal of Cosmology and Astroparticle Physics)

   null (Ed.)
4. Tension Pistons: Amplifying Piston Force Using Fluid-Induced Tension in Flexible Materials

   Shuguang Li, Daniel M. (June 2019, Advanced functional materials)

   Pistons are ubiquitous devices used for fluid-mechanical energy conversion. However, despite this ubiquity and centuries of development, the forces and motions produced by conventional rigid pistons are limited by their design. The use of flexible materials and structures opens a door to the design of a piston with unconventional features. In this study, an architecture for pistons that utilizes a combination of flexible membrane materials and compressible rigid structures is proposed. In contrast to conventional pistons, the fluid- pressure-induced tension forces in the flexible membrane play a primary role in the system, rather than compressive forces on the internal surfaces of the piston. The compressive skeletal structures offer the opportunity for the production of tunable forces and motions in the “tension piston” system. The experimental results indicate that the tension piston concept is able to produce substantially greater force (more than three times), higher power, and higher energy efficiency (more than 40% improvement at low pressures) compared to a conventional piston, and these features enable myriad potential applications for the tension piston as a drop-in replacement for existing pistons. 

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5. Damage evolution and ductile fracture of commercially-pure titanium sheets subjected to simple tension and cyclic bending under tension

   https://doi.org/10.1016/j.jmrt.2024.07.149  

   Pitkin, Nicholas; Noell, Philip; Fullwood, David T; Knezevic, Marko (September 2024, Journal of Materials Research and Technology)