C=4e-
(on Periodic Table you find C in the Group 4 / 4valence electrons)
S=6e- (Group 6/ 6 valence electrons) multiply by 2
12e-
4e-
+ 12e-
____
16 valence electrons in CS2
The electron-pair geometry of CS2 is linear because the Lewis structure is S=C=S. Double bonds act as one electron pair to help determine electron-pair geometries of molecules according to VESPR theory
Yes, CS2 is a nonpolar molecule because it has a linear structure with symmetrical dipole moments that cancel each other out, resulting in no overall dipole moment.
The electron pair geometry of CS2 is linear. This is because the central sulfur atom has two electron pairs around it, which repel each other as far apart as possible, resulting in a linear molecular geometry.
The molecular geometry of CS2 is linear. This molecule consists of a central carbon atom bonded to two sulfur atoms, and there are no lone pairs on the central atom. The bonds and atoms are arranged in a straight line, giving it a linear molecular geometry.
Cesium forms Cs+ ions, as it typically loses one electron to achieve a stable electron configuration. It is highly unlikely for cesium to form Cs2+ ions as this would require the loss of two electrons, which is energetically unfavorable.
The electron pair geometry for CS2 is Linear.
The electron domain geometry for CS2 is linear, as sulfur has two bonding pairs and no lone pairs of electrons around it.
The electron-pair geometry of CS2 is linear because the Lewis structure is S=C=S. Double bonds act as one electron pair to help determine electron-pair geometries of molecules according to VESPR theory
Yes, CS2 is a nonpolar molecule because it has a linear structure with symmetrical dipole moments that cancel each other out, resulting in no overall dipole moment.
The most idealized bond angle would be in CS2, which has a linear molecular geometry with a bond angle of 180 degrees. PF3, SBr2, and CHCl3 have trigonal pyramidal, angular, and tetrahedral geometries, respectively, which deviate from the ideal angles due to lone pair repulsions.
Carbon disulfide (CS2) has 2 lone pairs of electrons on the sulfur atom, giving a total of 2 lone pairs in the molecule.
Yes, CS2 has a dipole moment of zero because the two sulfur atoms pull the electron density towards them equally, canceling out any net dipole moment.
The electron pair geometry of CS2 is linear. This is because the central sulfur atom has two electron pairs around it, which repel each other as far apart as possible, resulting in a linear molecular geometry.
48,5 g sample of CS2 is the equivalent of 0,637 moles.
The molecular geometry of CS2 is linear. This molecule consists of a central carbon atom bonded to two sulfur atoms, and there are no lone pairs on the central atom. The bonds and atoms are arranged in a straight line, giving it a linear molecular geometry.
To find the number of moles in 19.2 g of CS2, we need to divide the given mass by the molar mass of CS2. The molar mass of CS2 is 76.14 g/mol. So, 19.2 g ÷ 76.14 g/mol ≈ 0.252 moles of CS2.
In CS2, there is 1 sulfur atom per molecule. Therefore, 4.2 moles of CS2 would contain 4.2 moles of sulfur atoms.