Chemistry lewis dot structure calculator online Every chemistry student has to learn how to draw Lewis Dot Structures. The key is to understand the steps and practice.

Lewis Structures are important to learn because they help us predict:

Given descriptions, diagrams, scenarios, or chemical symbols, students will model covalent bonds using electron dot formula (Lewis structures). Lewis Electron Dot Structure Calculator. What is the lewis dot structure for ozone? Chemistry stack exchange electron (lewis) structures pages 1 4 flip pdf download fliphtml5 why hcooh written like bottom but not top? Doesn t top satisfy octet rule?: chemhelp formation of kcl with an structure? Quora diagram chemical bonds full version hd quality diagramtonyb nowroma it.

  • the shape of a molecule.
  • how the molecule might react with other molecules.
  • the physical properties of the molecule (like boiling point, surface tension, etc.).

That helps us understand and predict interactions with things like medicine and our body, materials used to make buildings and airplanes, and all sorts of other substances. Lewis structures don't tell us everything, but along with molecule geometry and polarity they are hugely informative.


Search 100+ Lewis Structures on our site.
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Click the Chemical Formula to see the Lewis Structure

Acetone(C3H6O)
AsCl3(Arsenic Trichloride)
AsF3(Arsenic Trifluoride)
AsF5(Arsenic Pentafluoride)
AsF6-(AsF6-)
AsH3(Arsenic Trihydride)
AsO33-(Arsenite Ion)
BBr3(Boron Tribromide)
BCl3(Boron Trichloride)
BF3(Boron Trichloride)
BF4-(Tetrafluoroborate Ion)
BH3(Boron Hydride)
BH4-(BH4-)
B(OH)3(B(OH)3)
BeCl2(Beryllium Chloride)
BeF2(Beryllium Fluoride)
BeH2(Beryllium Hydride)
Br2(Bromine Gas or Elemental Bromine)
Br3-(Tribromide Ion)
BrF(Bromine Monofluoride)
BrF2(Bromine Difluoride)
BrCl3(Bromine Trichloride)
BrF3(Bromine Trifluoride)
BrF5(Bromine Pentafluoride)
BrO-(Hypobromite Ion)
BrO2-(Bromite Ion)
BrO3-(Bromate Ion)
C22-(Dicarbide Ion)
CBr4(Carbon Tetabromide)
CCl4(Carbon Tetachloride)
ClF(Chlorine Monofluoride)
CF2Cl2(Dichlorodifluoromethane)
CH2Cl2(CH2Cl2)
CH3-(CH3-)
CH3Br(CH3Br)
CH3Cl(Chloromethane or Methyl Chloride)
CH3CN(Acetonitril or Methyl Cyanide)
CH3COO-CH3COO-
CH3COOH(Acetic Acid)
CH3F(CH3F)
CH3NH2(Methylamine)
CH3NO2(CH3NO2)
CH3OCH3(Dimethyl Ether or Methoxymethane)
CH3OH(Methanol or Methyl Alcohol)
CH4(Methane)
C2F4(C2F4)
C2H2(Ethyne or Acetylene)
C2H2Br2(C2H2Br2)
C2H2Cl2(C2H2Cl2)
C2H4(Ethene)
C2H6(Ethane)
C2H6OC2H6O
C3H6(C3H6)
C3H8(Propane)
C4H10(Butane)
C6H6(Isomers - including Benzene)
C6H12(C6H12)
CHCl3(Chloromethane)
CH2F2(Difluoromethane)
CH2O(Methanal or Formaldehyde)
CH4O(CH4O)
Cl2(Chlorine Gas or Elemental Chlorine)
Cl2CO(Cl2CO)
Cl2O(Dichlorine Monoxide)
Cl3PO(Phosphoryl Trichloride)
ClF3(Chlorine Trifluoride)
ClF5(Chlorine Tetrafluoride)
ClO-(Hypochlorite Ion)
ClO2(Chlorine Dioxide)
ClO2-(Chlorite Ion)
ClO3-(Chlorate Ion)
ClO4-(Perchlorate Ion)
CO(Carbon monoxide)
CO2(Carbon Dioxide)
CO32-(Carbonate Ion)
COCl2(COCl2)
COF2(COF2)
COH2(COH2)
CN-(Cyanide Anion)
CS2(Carbon Disulfide)
F2(Fluorine Gas, Difluorine)
H2(Hydrogen Gas or Elemental Hydrogen)
H2CO(Formaldehyde or Methanal)
H2CO3(Carbonic Acid)
H2O(Water or Dihydrogen monoxide)
H3O+(Hydronium Ion)
H2O2(Hydrogen Peroxide or Dihydrogen Dioxide)
HBr (Hydrogen Bromide or Hydrobromic Acid)
HF (Hydrogen Fluoride or Hydrofluoric Acid)
HCCH (Ethyne)
HCl (Hydrogen Chloride or Hydrochloric Acid)
HCO2- (Formate Ion)
HCO3- (Hydrogen Carbonate Ion or Bicarbonate Ion)
HCOOH (Methanoic Acid or Formic Acid)
HI (Hydrogen Iodide or Hydroiodic Acid)
HClO3 (Chloric Acid)
HCN (Hydrogen Cyanide)
HNO2 (Nitrous Acid)
HNO3 (Nitric Acid)
H2S (Dihydrogen Sulfide)
HOCl (Hypochlorous Acid)
H2Se(Dihydrogen Selenide)
HSO3- (Bisulfite Ion)
HSO4- (Bisulfate Ion)
H2SO3 (Sulfurous Acid)
H2SO4 (Sulfuric Acid)
H3PO4 (Phosphoric Acid)
I2(Iodine Gas or Elemental Iodine)
I3-(I3-)
IBr2- (IBr2-)
ICl (Iodine Chloride)
ICl2- (ICl2-)
ICl3 (ICl3)
ICl4- (ICl4-)
ICl5 (Iodine Pentachloride)
IF2- (IF2-)
IF3 (Iodine Trifluoride)
IF4- (IF4-)
IF5 (Iodine Pentafluoride)
IO3- (Iodate Ion)
IO4- (Perioiodate Ion)
N2(Nitrogen Gas, also called Elemental Nitrogen)
N3-(Azide Ion)
N2F2 (Dinitrogen Difluoride)
N2H2 (Dinitrogen Dihydride)
N2H4 (Dinitrogen Tetrahydride or Hydrazine or Diamine)
N2O3 (Dinitrogen Trioxide)
N2O4 (Dinitrogen Tetroxide)
N2O5 (Dinitrogen Pentoxide)
NCl3(Nitrogen Trichloride)
NF3(Nitrogen Trifluoride)
NH2-(NH2-)
NH2Cl(Chloroamine)
NH2OH(Hydroxylamine)
NH3(Ammonium or Nitrogen Trihydride)
NH4+(Ammonium Ion)
NI3(Nitrogen Triiodide)
NO+(Nitrosonium Ion)
NO(Nitric Oxide or Nitrogen Monoxide)
N2O(Nitrous Oxide or Dinitrogen Monoxide)
NO2(Nitrogen Dioxide)
NO2-(Nitrite Ion)
NO2Cl(NO2Cl)
NO2F(NO2F)
NO3-(Nitrate Ion)
NOBr (Nitrosyl Bromide)
NOCl (Nitrosyl Chloride)
NOF (Nitrosyl Fluoride)
O2(Oxygen Gas, also called Elemental Oxygen)
O22-(Perioxide Ion)
O3(Ozone)
O3O3 Resonance Structures
OCl2(OCl2)
OCN-(Cyanate Ion)
OCS(OCS)
OF2(Oxygen Difluoride)
OH-(Hydroxide Ion)
PBr3Phosphorus Tribromide
PBr5Phosphorus Pentabromide
PCl3Phosphorus Trichloride
PCl4-PCl4-
PCl5Phosphorus Pentachloride
PF3Phosphorus Trifluoride
PF5Phosphorus Pentafluoride
PF6-Hexafluorophosphate Ion
PH3Phosphorus Trihydride
POCl3Phosphoryl Chloride or Phosphorus Oxychloride
PO33-(Phosphite Ion)
PO43-(Phosphate Ion)
SBr2(Sulfur Dibromide)
SCl2(Sulfur Dichloride)
SCl4(Sulfur Tetrachloride)
SCN-(Thiocyanate)
SeF4(Selenium Tetrafluoride)
SeF6(Selenium Hexafluoride)
SeO2(Selenium Dioxide)
SF2(Sulfur Difluoride)
SF4(Sulfur Tetrafluoride)
SF6(Sulfur Hexafluoride)
S2Cl2(Diulfur Dichloride)
SiCl4(Silicon Tetrachloride)
SiF4(Silicon Tetrafluoride)
SiF62-(Silicon Hexafluoride Ion)
SiH4(Silicon Tetrahydride)
SiO2(Silicon Dioxide)
SnCl2(Tin (II) Chloride)
SOCl2(SOCl2)
SO2(Sulfur Dioxide)
SO3(Sulfur Dioxide)
SO32-(Sulfite Ion)
SO42-(Sulfate Ion)
Water (H2O)
XeCl4Xenon Tetrachloride
XeF2XeF2
XeF4Xenon Tetrafluoride
XeF6Xenon Hexafluoride
XeH4XeO4
XeO3XeO3
XeO2F2XeO2F2

Steps for Writing Lewis Structures

  1. Find the total valence electrons for the molecule. Explain How Examples: H2S, NCl3, OH-

  2. Put the least electronegative atom in the center.
    Note: H always goes outside.
    Examples: NOCl, CF2Cl2, HCN

  3. Put two electrons between atoms to form a chemical bond. Examples: CH4, NH3, I2

  4. Complete octets on outside atoms.
    Note: H only needs two valence electrons.

  5. If central atom does not have an octet, move electrons from outer atoms to form double or triple bonds.
    Examples: O2, N2, C2H4

  6. Advanced Steps

  7. If you have extra electrons after the above steps add them to the central atom. Note: elements in the Period Three (usually S, P, or Xe) can have more than eight valence electrons.
    Examples: ClF3, SF4,XeH4

  8. Check the Formal Charges to make sure you have the best Lewis Structure. Explain How
    Examples: SO42-, N2O, XeO3

Notable Exceptions to the Octet Rule

  • H only needs 2 valence electrons.
  • Be and B don’t need 8 valence electrons.
  • S and P sometimes have more than 8 val. Electrons.
  • Elements in Period Three, Four, etc (on the periodic table) can hold more than 8 valence electrons.

Lewis Dot Structure Chemistry Worksheet

Learning Objectives

  • State the octet rule.
  • Define ionic bond.
  • Draw Lewis structures for ionic compounds.

In Section 4.7 we saw how ions are formed by losing electrons to make cations or by gaining electrons to form anions. The astute reader may have noticed something: many of the ions that form have eight electrons in their valence shell. Either atoms gain enough electrons to have eight electrons in the valence shell and become the appropriately charged anion, or they lose the electrons in their original valence shell; the lower shell, now the valence shell, has eight electrons in it, so the atom becomes positively charged. For whatever reason, having eight electrons in a valence shell is a particularly energetically stable arrangement of electrons. The octet rule explains the favorable trend of atoms having eight electrons in their valence shell. When atoms form compounds, the octet rule is not always satisfied for all atoms at all times, but it is a very good rule of thumb for understanding the kinds of bonding arrangements that atoms can make.

Chemistry Lewis Dot Structure Calculator

It is not impossible to violate the octet rule. Consider sodium: in its elemental form, it has one valence electron and is stable. It is rather reactive, however, and does not require a lot of energy to remove that electron to make the Na+ ion. We could remove another electron by adding even more energy to the ion, to make the Na2+ ion. However, that requires much more energy than is normally available in chemical reactions, so sodium stops at a 1+ charge after losing a single electron. It turns out that the Na+ ion has a complete octet in its new valence shell, the n = 2 shell, which satisfies the octet rule. The octet rule is a result of trends in energies and is useful in explaining why atoms form the ions that they do.

Now consider an Na atom in the presence of a Cl atom. The two atoms have these Lewis electron dot diagrams and electron configurations: Star wars old republic starships.

[mathbf{Na, cdot }; ; ; ; ; ; ; ; ; ; mathbf{cdot }mathbf{ddot{underset{.: .}Cl}}mathbf{: :}]

[left [ Ne right ]3s^{1}; ; ; ; left [ Ne right ]3s^{2}3p^{5}]

For the Na atom to obtain an octet, it must lose an electron; for the Cl atom to gain an octet, it must gain an electron. An electron transfers from the Na atom to the Cl atom:

[mathbf{Na, cdot }curvearrowright mathbf{cdot }mathbf{ddot{underset{.: .}Cl}}mathbf{: :}]

Chemistry Lewis Dot Structure Calculator

resulting in two ions—the Na+ ion and the Cl ion:

[mathbf{Na}^{+}; ; ; ; ; ; ; ; mathbf{:}mathbf{ddot{underset{.: .}Cl}}mathbf{: :}^{-}]

[left [ Ne right ]; ; ; ; ; left [ Ne right ]3s^{2}3p^{6}]

Both species now have complete octets, and the electron shells are energetically stable. From basic physics, we know that opposite charges attract. This is what happens to the Na+ and Cl ions:

[mathbf{Na}^{+}; + ; mathbf{:}mathbf{ddot{underset{.: .}Cl}}mathbf{: :}^{-}rightarrow Na^{+}Cl^{-}; ; or; ; NaCl]

where we have written the final formula (the formula for sodium chloride) as per the convention for ionic compounds, without listing the charges explicitly. The attraction between oppositely charged ions is called an ionic bond, and it is one of the main types of chemical bonds in chemistry. Ionic bonds are caused by electrons transferring from one atom to another.

In electron transfer, the number of electrons lost must equal the number of electrons gained. We saw this in the formation of NaCl. A similar process occurs between Mg atoms and O atoms, except in this case two electrons are transferred:

The two ions each have octets as their valence shell, and the two oppositely charged particles attract, making an ionic bond:

Chemistry Lewis Dot Structure Practice

[mathbf{Mg,}^{2+}; + ; left[mathbf{:}mathbf{ddot{underset{.: .}O}}mathbf{: :}right]^{2-}; ; ; ; ; Mg^{2+}O^{2-}; or; MgO]

Remember, in the final formula for the ionic compound, we do not write the charges on the ions.

What about when an Na atom interacts with an O atom? The O atom needs two electrons to complete its valence octet, but the Na atom supplies only one electron:

[mathbf{Na, cdot }curvearrowright mathbf{cdot }mathbf{ddot{underset{.}O}}mathbf{: :}]

Stranded deep versi terbaru. The O atom still does not have an octet of electrons. What we need is a second Na atom to donate a second electron to the O atom:

These three ions attract each other to give an overall neutral-charged ionic compound, which we write as Na2O. The need for the number of electrons lost being equal to the number of electrons gained explains why ionic compounds have the ratio of cations to anions that they do. This is required by the law of conservation of matter as well.

Example (PageIndex{1}): Synthesis of calcium chloride from Elements

With arrows, illustrate the transfer of electrons to form calcium chloride from (Ca) atoms and (Cl) atoms.

Chemistry Lewis Dot Structure Calculator Online

Solution

A (Ca) atom has two valence electrons, while a (Cl) atom has seven electrons. A (Cl) atom needs only one more to complete its octet, while (Ca) atoms have two electrons to lose. Thus we need two (Cl) atoms to accept the two electrons from one (Ca) atom. The transfer process looks as follows:

The oppositely charged ions attract each other to make CaCl2.

Exercise (PageIndex{1})

With arrows, illustrate the transfer of electrons to form potassium sulfide from (K) atoms and (S) atoms.

Answer
Structure

Summary

  • The tendency to form species that have eight electrons in the valence shell is called the octet rule.
  • The attraction of oppositely charged ions caused by electron transfer is called an ionic bond.
  • The strength of ionic bonding depends on the magnitude of the charges and the sizes of the ions.

Contributions & Attributions

Lewis Dot Structures Chemistry Definition

Sasural simar ka theme music download. This page was constructed from content via the following contributor(s) and edited (topically or extensively) by the LibreTexts development team to meet platform style, presentation, and quality:

Lewis Dot Structures

  • Marisa Alviar-Agnew (Sacramento City College)

  • Henry Agnew (UC Davis)