Why do some elements produce colorful flames?

Answer 1

Adding energy to an atom can force one or more of its electrons to become "excited," which means they jump out to a higher energy level than their normal place, or ground state. In making this jump, they absorb the energy put into them. According to the Law of Conservation of Energy, they must release this same energy when they fall back to their ground state from that excited state. In doing so, this energy is often released in the form of a visible wavelength of light. The color depends upon the wavelength. Some visible examples: copper - green, potassium - violet, strontium - red. Every element has its own signature wavelength, which makes the presence of certain elements easily detectable by a "flame test."

Answer 2

The colors are caused by electrons that have been heated and raised to a higher energy state, and then immediately drop back down to the ground state. When the electrons drop from the higher to the lower energy states, they lose energy which is emitted as visible light and heat.

Answer 3

Flame colours are produced from the movement of the electrons in the metal ions present in the compounds.

For example, a sodium ion in an unexcited state has the structure 1s22s22p6.

When you heat it, the electrons gain energy and can jump into any of the empty orbitals at higher levels - for example, into the 7s or 6p or 4d or whatever, depending on how much energy a particular electron happens to absorb from the flame.

Because the electrons are now at a higher and more energetically unstable level, they tend to fall back down to where they were before - but not necessarily all in one go.

An electron which had been excited from the 2p level to an orbital in the 7 level, for example, might jump back to the 2p level in one go. That would release a certain amount of energy which would be seen as light of a particular colour.

However, it might jump back in two (or more) stages. For example, first to the 5 level and then back to the 2 level.

Each of these jumps involves a specific amount of energy being released as light energy, and each corresponds to a particular colour.

As a result of all these jumps, a spectrum of coloured lines will be produced. The colour you see will be a combination of all these individual colours.

The exact sizes of the possible jumps in energy terms vary from one metal ion to another. That means that each different ion will have a different pattern of spectral lines, and so a different flame colour.

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How is the test performed?

First, you need a clean wire loop! Platinum or nickel-chromium loops are most common. They may be cleaned by dipping in hydrochloric or nitric acid, followed by rinsing with distilled or deionized water. Test the cleanliness of the loop by inserting it into a Bunsen burner flame. If a burst of color is produced, the loop was not sufficiently clean. Ideally, a separate loop is used for each sample to be tested, but a loop may be carefully cleaned between tests.

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It is based on the observation that light emitted by any element gives a unique spectrum when passed through a spectroscope. When a salt of the metal is introduced into a Bunsen burner flame, the metallic ion produces characteristic color in the flame. Some metals and the colors they produce are: barium, yellow-green; calcium, red-orange; copper salts (except halides), emerald green; copper halides or other copper salts moistened with hydrochloric acid, blue-green; lithium, crimson; potassium, violet; sodium, yellow; and strontium, scarlet. The value of this simple flame test is limited by interferences (e.g., the barium flame masks calcium, lithium, or strontium) and by ambiguities (e.g., rubidium and cesium produce the same color as potassium). A colored glass is sometimes used to filter out light from one metal; for instance, blue cobalt glass filters out the yellow of sodium.

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Answer 4

Heat energy is absorbed by the electrons so that they 'jump' to a differnt energy level. When the electron moves back to a lower energy level it releases the energy as part of the e-m spectrum, some of which is light. Since different elements have electrons in different energy levels to start with, the absorbed and released energy will be a different amount which creates a different color of light.

Answer 5

Some elements produce colorful flames because when they are heated, the electrons in their atoms become excited and jump to higher energy levels. When the electrons fall back to their original energy levels, they release energy in the form of light, causing the colors we see in the flames. Each element has unique energy levels, so they produce different colors.

Answer 6

there are different ions and things in it

Answer 7

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