how many constitutional isomers are possible for the formula C4H9Cl, draw them in skeletal form
There is a total of seventeen constitutional isomers for the molecular formula C5H13N. Draw the skeletal formula of all eight constitutional isomers that are primary amines.
There is a total of seventeen constitutional isomers for the molecular formula C5H13N. Draw the skeletal formula of all six constitutional isomers that are secondary amines.
Write the structure of all possible constitutional isomers of: C4H10O C5H12O C4H9Cl C4H9Br C5H11Cl C5H11Br
3. Draw all possible constitutional isomers of aldehydes and ketones with molecular formula C5H100 and name all isomers. 1. Identify a pair of skeletal isomers? 2. Identify a pair of positional isomers? 3. Identify a pair of functional isomers?
Laboratory Work 1. Draw the skeletal formulas and make models of the three constitutional isomers of C5H12. 2. Draw Kekule structures and make models of all the constitutional isomers of C2H4Cl2. 3. Draw Kekule formulas and make models of ethane, ethene, and ethyne. How does the geometry of their structures differ? Which compound contains sp hybridized carbons? 4. Draw and label the Newman projection and make the model of the anti-conformation of 1,2-dibromoethane. Rotate around the carbon-carbon bond...
How many constitutional isomers of C4H9Br are possible? Draw the structures and give your reasons.
Draw at least four constitutional isomers (using bond-line/skeletal representations) with the molecular formula C5H10O. Make sure that each constitutional isomer has a different functional group present.
Draw and name skeletal structures for all the 17 constitutional isomers of 2,2,4-trimethylpentane that contains 1Br and 1F atoms, molecular formula C8H16BrF.
Draw the possible constitutional isomers of compounds containing the molecular formula C,H12 and provide the IUPAC name of the molecules (3 points): 6.
3B) Draw the constitutional isomers of trimethylcyclopropane as skeletal structures. 3C) For each constitutional isomer you drew in part (a), draw any stereoisomers of that structure, explicitly showing stereochemistry with dash/wedge bonds. Use skeletal structures. 2. This molecule has a ring strain of 70 kl/mol. Circle which type of strain is most important, and explain why you circledit: Angle torsional steric 3. Only one stereoisomer of this compound is stable - draw the relative stereochemistry at the ring Junction with...