Oxygen and Sulfur has same number of valance electrons in their outer most shell. Explanation: Oxygen and Sulfur has 6 electrons each in their out most shell. A valance electron is the outer shell electron that revolves around an atom. The count of valance electron might differ up on various elements in the periodic table. The number of valence electrons in an element affects the reactivity of that element. Which element listed has the fewest valence electrons? (Na) and potassium (K.
- Quantum Numbers For Valence Electrons In Potassium
- How To Find The Number Of Valence Electrons In Potassium
What is the number of valence electrons in potassium?
Lewis suggested that the number of valences of an atom was equal to the number of electrons in its valence shell or to the number of electrons which would have to be added to the valence shell to achieve the electronic shell structure of the next noble gas. Potassium (K) has 19 total electrons, as indicated by its atomic number (the number of electrons equals the number of protons in a neutral atom). See full answer below. .For atoms with LESS than 4valence electrons, they’re going to lose/give upelectrons to form positive cations.For atoms with MORE than 4valence electrons, they’re going to gain/stealelectrons to form negative anions.For atoms with 4 valence electrons, it can go either way.For atoms with 8 valence electrons, there is no change.
2 Answers
Explanation:
As Potassium is present in the first group of the modern periodic table
Potassium which is also represented as K
it has only ONE valence electron..I.e only on electron is present in the outermost shell
What are valence electrons
Valence electrons are the electrons present in the outermost shell of an atom
Explanation:
Just like sodium potassium has one valence electron and is highly reactive. (it is monovalent).
Related questions
Lewis used simple diagrams (now called Lewis diagrams) to keep track of how many electrons were present in the outermost, or valence, shell of a given atom. The kernel of the atom, i.e., the nucleus together with the inner electrons, is represented by the chemical symbol, and only the valence electrons are drawn as dots surrounding the chemical symbol. Thus the three atoms shown in Figure 1 from Electrons and Valence can be represented by the following Lewis diagrams:
If the atom is a noble-gas atom, two alternative procedures are possible. Either we can consider the atom to have zero valence electrons or we can regard the outermost filled shell as the valence shell. The first three noble gases can thus be written as:
Example (PageIndex{1}): Lewis Structures
Draw Lewis diagrams for an atom of each of the following elements: Li, N, F, Na
Solution
We find from the periodic table inside the front cover that Li has an atomic number of 3. It thus contains three electrons, one more than the noble gas He. This means that the outermost, or valence, shell contains only one electron, and the Lewis diagram is
Following the same reasoning, N has seven electrons, five more than He, while F has nine electrons, seven more than He, giving
Na has nine more electrons than He, but eight of them are in the kernel, corresponding to the eight electrons in the outermost shell of Ne. Since Na has only 1 more electron than Ne, its Lewis diagram is
Notice from the preceding example that the Lewis diagrams of the alkali metals are identical except for their chemical symbols. This agrees nicely with the very similar chemical behavior of the alkali metals. Similarly, Lewis diagrams for all elements in other groups, such as the alkaline earths or halogens, look the same.
The Lewis diagrams may also be used to predict the valences of the elements. Lewis suggested that the number of valences of an atom was equal to the number of electrons in its valence shell or to the number of electrons which would have to be added to the valence shell to achieve the electronic shell structure of the next noble gas. As an example of this idea, consider the elements Be and O. Their Lewis diagrams and those of the noble gases He and Ne are
Comparing Be with He, we see that the former has two more electrons and therefore should have a valence of 2. The element O might be expected to have a valence of 6 or a valence of 2 since it has six valence electrons—two less than Ne. Using rules of valence developed in this way, Lewis was able to account for the regular increase and decrease in the subscripts of the compounds in the table found in the Valence section, and reproduced here. In addition he was able to account for more than 50 percent of the formulas in the table. (Those that agree with his ideas are shaded in color in the table. You may wish to refer to that table now and verify that some of the indicated formulas follow Lewis’ rules.) Lewis’ success in this connection gave a clear indication that electrons were the most important factor in holding atoms together when molecules formed.
Despite these successes, there are also difficulties to be found in Lewis’ theories, in particular for elements beyond calcium in the periodic table. The element Br (Z = 35), for example, has 17 more electrons than the noble-gas Ar (Z = 18). This leads us to conclude that Br has 17 valence electrons, which makes it awkward to explain why Br resembles Cl and F so closely even though these two atoms have only seven valence electrons.
Quantum Numbers For Valence Electrons In Potassium
| Element | Atomic Weight | Hydrogen Compounds | Oxygen Compounds | Chlorine Compounds |
|---|---|---|---|---|
| Hydrogen | 1.01 | H2 | H2O, H2O2 | HCl |
| Helium | 4.00 | None formed | None formed | None formed |
| Lithium | 6.94 | LiH | Li2O, Li2O2 | LiCl |
| Beryllium | 9.01 | BeH2 | BeO | BeCl2 |
| Boron | 10.81 | B2H6 | B2O3 | BCl3 |
| Carbon | 12.01 | CH4, C2H6, C3H8 | CO2, CO, C2O3 | CCl4, C2Cl6 |
| Nitrogen | 14.01 | NH3, N2H4, HN3 | N2O, NO, NO2, N2O5 | NCl3 |
| Oxygen | 16.00 | H2O, H2O2 | O2, O3 | <Cl2O, ClO2, Cl2O7 |
| Fluorine | 19.00 | HF | OF2, O2F2 | ClF, ClF3, ClF5 |
| Neon | 20.18 | None formed | None formed | None formed |
| Sodium | 22.99 | NaH | Na2O, Na2O2 | NaCl |
| Magnesium | 24.31 | MgH2 | MgO | MgCl2 |
| Aluminum | 26.98 | AlH3 | Al2O3 | AlCl3 |
| Silicon | 28.09 | SiH4, Si2H6 | SiO2 | SiCl4, Si2Cl6 |
| Phosphorus | 30.97 | PH3, P2H4 | P4O10, P4O6 | PCl3, PCl5, P2Cl4 |
| Sulfur | 32.06 | H2S, H2S2 | SO2, SO3 | S2Cl2, SCl2, SCl4 |
| Chlorine | 35.45 | HCl | Cl2O, ClO2, Cl2O7 | Cl2 |
| Potassium | 39.10 | KH | K2, K2O2, KO2 | KCl |
| Argon | 39.95 | None formed | None formed | None formed |
| Calcium | 40.08 | CaH2 | CaO, CaO2 | CaCl2 |
| Scandium | 44.96 | Relatively Unstable | Sc2O3 | ScCl3 |
| Titanium | 47.90 | TiH2 | TiO2, Ti2O3, TiO | TiCl4, TiCl3, TiCl2 |
| Vanadium | 50.94 | VH2 | V2O5, V2O3, VO2, VO | VCl4, VCl3, VCl2 |
| Chromium | 52.00 | CrH2 | Cr2O3, CrO2, CrO3 | CrCl3, CrCl2 |
Contributors
How To Find The Number Of Valence Electrons In Potassium
Ed Vitz (Kutztown University), John W. Moore (UW-Madison), Justin Shorb (Hope College), Xavier Prat-Resina (University of Minnesota Rochester), Tim Wendorff, and Adam Hahn.