Multimodal signalling in estrildid finches: song, dance and colour are associated with different ecological and life-history traits

Sexual traits (e.g. visual ornaments, acoustic signals, courtship behaviour) are often displayed together as multimodal signals. Some hypotheses predict joint evolution of different sexual signals (e.g. to increase the efficiency of communication) or that different signals trade off with each other (e.g. due to limited resources). Alternatively, multiple signals may evolve independently for different functions, or to communicate different information (multiple message hypothesis). We evaluated these hypotheses with a comparative study in the family Estrildidae, one of the largest songbird radiations, and one that includes many model species for research in sexual selection and communication. We found little evidence for either joint evolution or trade-offs between song and colour ornamentation. Some negative correlations between dance repertoire and song traits may suggest a functional compromise, but generally courtship dance also evolved independently from other signals. Instead of correlated evolution, we found that song, dance and colour are each related to different socio-ecological traits. Song complexity evolved together with ecological generalism, song performance with investment in reproduction, dance with commonness and habitat type, whereas colour ornamentation was shown previously to correlate mostly with gregariousness. We conclude that multimodal signals evolve in response to various socio-ecological traits, suggesting the accumulation of distinct signalling functions.This work was funded by grants PTDC/BIA-BEC/098414/2008, PTDC/BIAEVF/116758/2010, and PTDC/BIA-EVF/4852/2014, and fellowships SFRH/BPD/46873/2008 and SFRH/BPD/110165/2015 from the Fundacao para a Ciencia e a Tecnologia, and grants from the U.S. National Science Foundation (IOS 9412399, DEB 0089757). (PTDC/BIA-BEC/098414/2008 - Fundacao para a Ciencia e a Tecnologia; PTDC/BIAEVF/116758/2010 - Fundacao para a Ciencia e a Tecnologia; PTDC/BIA-EVF/4852/2014 - Fundacao para a Ciencia e a Tecnologia; SFRH/BPD/46873/2008 - Fundacao para a Ciencia e a Tecnologia; SFRH/BPD/110165/2015 - Fundacao para a Ciencia e a Tecnologia; IOS 9412399 - U.S. National Science Foundation; DEB 0089757 - U.S. National Science Foundation)Accepted manuscrip

Sistema acuapónico con humedal subsuperficial para producción de carpa (Cyprinus carpio L.), fresa (Fragaria x ananassa (Duchesne ex Weston) y canola (Brassica napus L.)

Objective: a greenhouse pilot aquaponic system was installed, operated, and evaluated to produce carps-strawberry-canola. Design / methodology / approach: the proposed aquaponics system was made of 4 modules: 1) module for the production of carp (Cyprinus Carpio comunis), 2) hydroponic module, deep flow type for the production of duckweed (Lemna minor L.) used to feed the carps, 3) hydroponic module for the strawberry production (Fragaria × ananassa), 4) hydroponic module with substrate (medium gravel) for the canola production (Brassica napus). The carps (Cyprinus carpio) had an average weight of 0.92 g at the beginning of the study (July 2018), the density was 500 carps/ 0.7 m3 of water. From September to December, a sample of 5% was taken to quantify their growth (length and weight) employing a Vernier, and a triple beam balance (OHAUS®). The carps were fed only with duckweed (Lemna minor L.). The carps were fed daily with 1.5% of duckweed as fresh matter concerning the average live weight of the 500 carps. Module 2 had an area of ??0.26 m2. The dry matter of duckweed was quantified using a PVC cylinder that had an area of ??0.010 m2, and then the fresh sample was weighed and dried at 105º C until constant weight. Module 3 (0.42 m2) had 23 plants in a vegetative state, the growth of 5 plants was evaluated by measuring the size of the root (cm), the height of the plant (cm), the length and width of the leaves (cm) and the foliar area (cm2). Module 4 had 0.42 m2, canola seed was sown at a density of 1.2 g/m2 that represented 185 seedlings. The growth of 9 plants was evaluated by measuring the same variables of strawberry plants. Results: in module 1, an average weight per carp of 17.7 g was obtained, representing an average weight increase of 16.8 g in the period from September to December. Module 2 produced 12 kg of duckweed in a fresh basis with 5.6% of dry matter. duckweed production was maintained using the nutrients from the effluent of module 1. In module 3, it was observed that strawberry plants presented an increase of 2.5 g in the fresh weight, 1 cm in root size, 0.9 cm in plant height, 0.2 cm in leaf length, 0.2 cm in leaf width and 0.4 cm2 in the leaf area. In module 4, there was an increase of 8.1 g in plant height, 0.2 cm in the leaf length, 0.2 cm in the leaf width and 0.1 cm2 in the leaf area. Limitations of the study/ implications: for the canola crop, only results of the vegetative growth were reported. For the carps, only three months were reported. However, there was evidence of the feasibility of the system. Findings/ Conclusions: an aquaponic system was installed, operated, and evaluated to produce carps-strawberry-canola. The duckweed was the only source of dry matter for carps. The effluent from the carp module provided nutrients for strawberry growth, bearing fruits of the right color. Canola plants developed adequately, although they had a purple color on the leaves, indicating a possible phosphorus deficiency.Objetivo: se instaló, opero y evaluó un sistema acuapónico piloto bajo invernadero para la producción de carpa-fresa-canola utilizando lenteja de agua como única fuente de alimento. Diseño/metodología/aproximación: el sistema acuapónico propuesto consistió en 4 módulos: 1) módulo para la producción de carpa (Cyprinus Carpio comunis), 2) módulo hidropónico tipo flujo profundo para la producción de lenteja de agua (Lemna minor L.) que se utilizó para alimentar a las carpas, 3) módulo hidropónico tipo raíz flotante para el cultivo de fresa (Fragaria × ananassa), 4) módulo hidropónico con sustrato (grava media) para el cultivo de canola (Brassica napus). En el módulo 1 se crio carpa (Cyprinus carpio) con peso promedio inicial de 0.92 g, a una densidad de 500 peces/0.7 m3 de agua en el mes de julio de 2018. De septiembre a diciembre del mismo año se tomó una muestra del 5% de la población para medir su crecimiento (longitud y peso) empleando un vernier de campo, y se obtuvo el peso (g) por carpa con una balanza granataria. Las carpas se alimentaron solamente con lenteja de agua (Lemna minor L.), se les ofreció 1.5% de peso fresco de Lemna con respecto al peso promedio de las 500 carpas. El módulo 2 tuvo un área de 0.26 m2, se cuantifico la producción de materia seca de la lenteja de agua mediante un cilindro de PVC con un área de 0.010 m2, la muestra fresca se pesó al momento del muestreo y posteriormente se secó a 105º C hasta peso constante. En el módulo 3 de 0.42 m2 se cultivaron 23 plantas de fresa en estado vegetativo, se monitoreó el crecimiento de 5 plantas mediante la medición del tamaño de la raíz (cm), la altura de la planta (cm), el largo y ancho de las hojas (cm) y el área foliar. El módulo 4 tuvo una superficie de 0.42 m2, se sembró semilla de canola a una densidad de 1.2 g/m2 que representó 185 plántulas. Se monitorio el crecimiento de 9 plantas y se evaluaron las mismas variables para las plantas de fresa.   Resultados: en el módulo 1 se obtuvo un peso promedio por carpa de 17.7 g representando un incremento de peso promedio de 16.8 g en el periodo de septiembre a diciembre. En el módulo 2 se produjo 12 kg de lenteja de agua fresca en un área de 0.26 m2 con 5.6% de materia seca. La producción de lenteja de agua se mantuvo utilizando los nutrientes del efluente del módulo 1. En el módulo 3 se observó que las plantas de fresa se adaptaron al sistema hidropónico tipo raíz flotante. En promedio se cuantifico un incremento de 2.5 g en el peso fresco de la planta, 1 cm en el tamaño de raíz, 0.9 cm en la altura de planta, 0.2 cm en el largo de hoja, 0.2 cm en el ancho de hoja y 0.4 cm2 en el área foliar. En el módulo 4 se cuantifico en promedio un incremento de 8.1 g en la altura de planta, 0.2 cm en el largo de hoja, 0.2 cm en el ancho hoja y 0.1 cm en el área foliar. Limitaciones del estudio/implicaciones: se reportan resultados del crecimiento vegetativo para la canola, para las carpas solamente se reporta el crecimiento en tres meses, no obstante, se muestra evidencia de la factibilidad del sistema. Hallazgos/conclusiones: se instaló, operó y evaluó un sistema acuapónico recirculante para la producción de carpa-fresa-canola. La lenteja de agua funcionó como la única fuente de alimento para el crecimiento de la carpa. El efluente del módulo carpa proporcionó nutrientes para el crecimiento de la fresa, dando frutos de buen color. Las plantas de canola se desarrollaron adecuadamente, aunque presentaron un color purpura en las hojas, lo que indicó una posible deficiencia de fosforo

The structure of the Yang-Mills spectrum for arbitrary simple gauge algebras

The mass spectrum of pure Yang-Mills theory in 3+1 dimensions is discussed for an arbitrary simple gauge algebra within a quasigluon picture. The general structure of the low-lying gluelump and two-quasigluon glueball spectrum is shown to be common to all algebras, while the lightest $C=-$ three-quasigluon glueballs only exist when the gauge algebra is A$_{r\geq 2}$, that is in particular $\mathfrak{su}(N\geq3)$. Higher-lying $C=-$ glueballs are shown to exist only for the A$_{r\geq2}$, D$_{{\rm odd}-r\geq 4}$ and E$_6$ gauge algebras. The shape of the static energy between adjoint sources is also discussed assuming the Casimir scaling hypothesis and a funnel form; it appears to be gauge-algebra dependent when at least three sources are considered. As a main result, the present framework's predictions are shown to be consistent with available lattice data in the particular case of an $\mathfrak{su}(N)$ gauge algebra within 't Hooft's large-$N$ limit.Comment: 21 pages, 4 figures; remarks added, typos corrected in v2. v3 to appear in EPJ