Imperative Tampio, 930 bytes Yöllä on ilot.Olkoon oma ilo uusi yö, jonka iloja ovat ilo"1s",ilo"2s",ilo"2p",ilo"3s",ilo"3p",ilo"3d",ilo"4s",ilo"4p",ilo"4d",ilo"5s",ilo"5p",ilo"4f",ilo"5d",ilo"6s",ilo"6p",ilo"5f",ilo"6d",ilo"7s"ja ilo"7p".Olkoon iso yö uusi yö, jonka iloja ovat 2,2,6,2,6,10,2,6,10,2,6,14,10,2,6,14,10,2 ja 6.Kun iso luku juo ison ilon,iso ilo näyttää oman yön,missä oma yö on oman ilon ensimmäinen ilo ja ujo ilo on ison yön ensimmäinen ilo,jos iso luku on suurempi kuin ujo ilo,niin iso ilo näyttää ujon ilon,iso ilo näyttää ilon" ",oman ilon iloiksi asetetaan oman ilon ilot toisesta alkaen,ison yön iloiksi asetetaan ison yön ilot toisesta alkaen ja iso luku vähennettynä ujolla ilolla juo ison ilon ja,jos iso luku on pienempi tai yhtä suuri kuin ujo ilo,niin iso ilo näyttää ison luvun.Olkoon oma muuttuja uusi muuttuja.Kun iso sivu avautuu,omaan muuttujaan luetaan luku ja oman muuttujan arvo juo ison sivun. This is code-golf, the shortest code wins! Here is a complete list and a reference implementation of sorts ( Try it online!) The maximum values they can contain are below the name: name: 1s 2s 2p 3s 3p 3d 4s 4p 4d 5s 5p 4f 5d 6s 6p 5f 6d 7s 7p Here is a list of all the electronic orbitals. However, superscripts are unnecessary the output for Iron (26) should be along the lines of 1s2 2s2 2p6 3s2 3p6 3d6 4s2. Iron (26) has the electron configuration 1s 2 2s 2 2p 6 3s 2 3p 6 3d 6 4s 2. Your challenge is to take a number representing the atomic number of an element and output the electron configuration of that element as defined by the Aufbau principle. For example, the electron configuration of the neon atom is 1s 2 2s 2 2p 6 (From Wikipedia) Challenge So those are the exceptions the main exceptions that you'll see when dealing with lifetime configuration.In atomic physics and quantum chemistry, the electron configuration is the distribution of electrons of an atom in atomic orbitals. So, again, I'm going to make this argon just make it for myself 4s1, 3d10 and again you might see it as argon 3d10, 4s1 same exact thing. That way this d orbital or d sublevel be completely filled which is very stable versus the s orbital will be halfway filled. Okay so anytime that it ends in d9 we're going to fix it up a little bit, same exact way we're going to take an electron from the 4s and we're going to move it over to the 3d. So let's make the electron configuration for that 1s2, 2s2, 2p6, 3s2, 3p6, 4s2, 3d9 from here on out anytime you see d9 we're going to change it. So you might see either one but they're the same.ĭown here the other exception that you're going to see is copper, or anything along copper which we'll talk about. So this is talking about the order of energy you might see it also looking like this, this is just doing it in order of number 3 comes before 4 but they're exactly the same thing, they're depicting the exact same thing, nothing different about them. You might see this is the diagram or the electron configuration that you're going to see and this is actually higher in energy than this. So instead we're going to write actually we're going to make this argon as we noted before in the noble gas configuration and we're going to make this 4s1, 3d5 this is halfway filled which is pretty stable and this is much more stable being half way filled rather than being the d4. So what we're going to do, we're going to, that should be a 2 there, sorry, and we're going to take one of the electrons in the 4s orbital and move it over to the 3d orbital. Right now we're 1 electron short of it being halfway filled. The d sublevel is more stable when its either half full all the orbitals are filled with at least 1 electron or completely filled. If we're going to make this short hand and make the electron configuration for this we would make this 1s2, 2s2, 2p6, 3s2, 3p6, 4s2, 3d4 okay from now on every time you see 3d4 you're going to change it, we do not like 3d4. Chromium is a transition metal and it has 24 electrons and here is the orbital diagram. Okay alright so let's talk about the exceptions you're going to see when you're dealing with electron configuration there's going to be a few around but we're going to talk about the main ones you're probably going to see in class.
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