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1. A Study of Java Microbenchmark Tail Latencies

   https://doi.org/10.1145/3578245.3584690  

   He, Sen; Kim, In Kee; Wang, Wei (April 2023, Companion of the 2023 ACM/SPEC International Conference on Performance Engineering)
2. A tale of two fish tails: does a forked tail really perform better than a truncate tail when cruising?

   https://doi.org/10.1242/jeb.244967  

   Tack, Nils B.; Gemmell, Brad J. (November 2022, Journal of Experimental Biology)

   ABSTRACT Many fishes use their tail as the main thrust producer during swimming. This fin's diversity in shape and size influences its physical interactions with water as well as its ecological functions. Two distinct tail morphologies are common in bony fishes: flat, truncate tails which are best suited for fast accelerations via drag forces, and forked tails that promote economical, fast cruising by generating lift-based thrust. This assumption is based primarily on studies of the lunate caudal fin of Scombrids (i.e. tuna, mackerel), which is comparatively stiff and exhibits an airfoil-type cross-section. However, this is not representative of the more commonly observed and taxonomically widespread flexible forked tail, yet similar assumptions about economical cruising are widely accepted. Here, we present the first comparative experimental study of forked versus truncate tail shape and compare the fluid mechanical properties and energetics of two common nearshore fish species. We examined the hypothesis that forked tails provide a hydrodynamic advantage over truncate tails at typical cruising speeds. Using experimentally derived pressure fields, we show that the forked tail produces thrust via acceleration reaction forces like the truncate tail during cruising but at increased energetic costs. This reduced efficiency corresponds to differences in the performance of the two tail geometries and body kinematics to maintain similar overall thrust outputs. Our results offer insights into the benefits and tradeoffs of two common fish tail morphologies and shed light on the functional morphology of fish swimming to guide the development of bio-inspired underwater technologies. 

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3. Turbulence in the tail of a jellyfish galaxy

   https://doi.org/10.1093/mnras/stad874  

   Li, Yuan; Luo, Rongxin; Fossati, Matteo; Sun, Ming; Jáchym, Pavel (March 2023, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT When galaxies move through the intracluster medium (ICM) inside galaxy clusters, the ram pressure of the ICM can strip the gas from galaxies. The stripped gas forms tails on the trailing side. These galaxies are hence dubbed ‘jellyfish galaxies’. ESO 137-001 is a quintessential jellyfish galaxy located in the nearest rich cluster, the Norma cluster. Its spectacular multiphase tail has complex morphology and kinematics both from the imprinted galaxy’s interstellar medium (ISM) and as a result of the interactions between the stripped gas and the surrounding hot plasma, mediated by radiative cooling and magnetic fields. We study the kinematics of the multiphase tail using high-resolution observations of the ionized and the molecular gas in the entire structure. We calculate the velocity structure functions in moving frames along the tail and find that turbulence driven by Kelvin–Helmholtz (KH) instability quickly overwhelms the original ISM turbulence and saturates at ∼30 kpc. There is also a hint that the far end of the tail has possibly started to inherit pre-existing large-scale ICM turbulence likely caused by structure formation. Turbulence measured by the molecular gas is generally consistent with that measured by the ionized gas in the tail but has a slightly lower amplitude. Most of the measured turbulence is below the mean free path of the hot ICM (∼11 kpc). Using warm/cool gas as a tracer of the hot ICM, we find that the isotropic viscosity of the hot plasma must be suppressed below 0.01 per cent Spitzer level. 

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4. Testing Tail Weight of a Distribution Via Hazard Rate

   Aliakbarpour, M.; Biswas, A.S.; Ravichandran, K.; Rubinfeld, R. (January 2023, International Conference on Algorithmic Learning Theory (ALT 2023))

   Understanding the shape of a distribution of data is of interest to people in a great variety of fields, as it may affect the types of algorithms used for that data. We study one such problem in the framework of {\em distribution property testing}, characterizing the number of samples required to to distinguish whether a distribution has a certain property or is far from having that property. In particular, given samples from a distribution, we seek to characterize the tail of the distribution, that is, understand how many elements appear infrequently. We develop an algorithm based on a careful bucketing scheme that distinguishes light-tailed distributions from non-light-tailed ones with respect to a definition based on the hazard rate, under natural smoothness and ordering assumptions. We bound the number of samples required for this test to succeed with high probability in terms of the parameters of the problem, showing that it is polynomial in these parameters. Further, we prove a hardness result that implies that this problem cannot be solved without any assumptions. 

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5. A Gittins Policy for Optimizing Tail Latency

   https://doi.org/10.1145/3695411.3695418  

   Harlev, Amit; Yu, George; Scully, Ziv (September 2024, ACM SIGMETRICS Performance Evaluation Review)

   Service level objectives (SLOs) for queueing systems typically relate to the tail of the system's response time distribution T. The tail is the function mapping a time t to the probability P[T > t]. SLOs typically ask that high percentiles of T are not too large, i.e. that P[T > t] is small for large t. 

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