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Discuss what you learned from reading the article and whether or not you would consider applying servant leadership in a similar way. In the Main Forum, post a short summary and a link to the article. Anonymous comment on Learn about current trends in servant leadership by conducting your own research and locating an article that illustrates how the principles of servant leadership are being employed in the workplace, as part of a volunteer or service effort, or in an individual’s personal life.For an inlet area of 800 cm2, determine the velocity and the volume flow rate of the steam f at the nozzle exit. Anonymous comment on Steam enters a nozzle at 400☌ and 800 kPa with a velocity of 10 m/s, and leaves at 300☌ and 200 kPa while losing heat at a rate of 25 kW.Graph the benefit and cost functions and show the net benefit maximizing value for x.Graph the marginal benefit and marginal cost and show this equilibrium graphically.Calculate the values of the benefit, cost and net benefit for this value of x.Find the value of x for which the net benefit is maximized.Anonymous comment on Consider the following cost and benefit functions: C(X, Y) = 150 X + 30 X2.Linnaeus evolved a system of nomenclature called (a) mononomial (b) vernacular (c) binomial (d) polynomial.Basic unit or smallest taxon of taxonomy/ classification is (a) species (b) kingdom (c) family (d) variety.A taxon is (a) a group of related families (b) a group of related species (c) a type of living organisms (d) a taxonomic group of any ranking.Malignant tertian malaria parasite, belongs to class (a) Plasmodium falciparum (b) P.African sleeping sickness is due to (a) Plasmodium vivax transmitted by Tsetse fly (b) Trypanosoma lewsii transmitted by Bed Bug (c) Trypanosoma gambiense transmitted by Glossina palpalis (d) Entamoeba gingivalis spread by Housefly.A test of these indices using 6 extinct species yielded results consistent with more-detailed descriptions of the functional morphology of these taxa, indicating that our quantitative proxies provide an important basis for comparisons of fossorial adaptations across divergent mammalian clades. Additionally, more subtle distinctions between subterranean taxa (which rarely emerge above ground) and other burrowers as well as between mammals using different methods of burrow excavation were identified from these characters. Discriminant analyses revealed that these quantitative characters successfully distinguish nonburrowing taxa from those that are adapted to a burrowing lifestyle. This study presents several quantitative indices of the morphology of burrowing mammals based on 20 measurements of skull and skeletal morphology taken from 123 different mammalian species, both burrowing and nonburrowing. A reliable quantitative proxy for fossoriality (burrowing) is necessary for such comparisons as well as for detailed descriptions of ecology from specimens of rare, extinct, and fossil mammals. While extensive research has been devoted to the morphological, ecological, and evolutionary implications of burrowing, it remains difficult to compare burrowing adaptations between mammals of widely divergent ancestry. Burrowing behavior is widespread among mammals and has generated a diverse array of adaptive responses to the physical demands of this lifestyle.