<h2>Answer with Explanation </h2>
I have been as of late pondering, on the off chance that I take a sufficiently incredible vitality source (photon) and I have an ideal mirror precisely before it and expect a "producer" shot the light towards the mirror. As impeccable mirrors assimilate no vitality of ANY sort from photons, should this imply the ideal mirrors could never move because of exchange of force of the light? it depends on the mass of the mirror, obviously. Your ideal mirror would have a vast mass, in which case it could assimilate the force change, without engrossing any vitality. A reflection of limited mass will ingest some vitality in a crash that will change the vitality and along these lines the wavelength of the photon. There is no logical inconsistency here.
Solar energy is more Natural since it comes from the sun and easier to harness, while chemical energy is Dangerous because it may fail and cause damage.
As a wavelength increases in size, its frequency and energy (E) decrease. From these equations you may realize that as the frequency increases, the wavelength gets shorter.
Explanation:
Glucocorticoids are hormones of the family of corticosteroids that participate in the regulation of carbohydrate metabolism favoring gluconeogenesis and glycogenolysis; They also have immunosuppressive activity. Its regulatory action also extends to the intermediate metabolism of fats and proteins. Glucocorticoids are mainly produced in the adrenal cortex of humans and are cortisol, cortisone and corticosterone. Cortisol is the most important glucocorticoid in humans.
From the pharmacological point of view they are corticosteroids for systemic use whose reference drug is hydrocortisone, which at high concentrations can suppress the production of ACTH adrenocorticotropic hormone in the adenohypophysis.
One of the characteristics you're looking for is whether the organism is a vertebrate (with a backbone) or an invertebrate (without a backbone).
