Alkanes(Paraffin): Lecture 2 Hydrocarbons with Only Single ...
Transcript of Alkanes(Paraffin): Lecture 2 Hydrocarbons with Only Single ...
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Alkanes(Paraffin): Lecture 2 Hydrocarbons with Only Single Bonds ; A hydrocarbon that contains only single bonds is
where n is a (, 2n+2HnCan alkane (general formula
positive integer). For example, if n = 5, the formula
. 12 H5 C or ] [(2x5) +2H 5C is
The alkanes comprise a homologous series, one in
which each member differs from the next by a
— CH2– (methylene) group.
Because hybridized, 3spis CIn an alkane, each
each C is bonded to the maximum number of other
atoms (C or H), alkanes are referred to as saturated
hydrocarbons.
Naming Alkanes: ( IUPAC )
Here we discuss general rules for naming any
alkane and, by extension, other organic compounds
as well. The key point is that each chain, branch, or
ring has a name based on the number of C atoms.
The name of a compound has three portions:
PREFIX + ROOT + SUFFIX
Root: The root tells the number of C atoms in the
longest continuous chain in the molecule. The roots
for the ten smallest alkanes are shown in Table
below.
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Prefix: Each prefix identifies a group attached to
the main chain and the number of the carbon to
which it is attached. Prefixes identifying
hydrocarbon branches are the same as root names
but have -yl as their ending (alkyl group).
Each prefix is placed before the root. For example,
in the name 2-methylbutane, -but- is the root (the
main chain has four C atoms), -ane is the suffix
(the compound is an alkane), and 2-methyl- is the
prefix a one-carbon branch is attached to C-2 of the
main chain).
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To obtain the systematic name of a compound ,
1. Name the longest chain (root).
2. Add the compound type (suffix).
3. Name any branches (prefix).
Table below presents the rules for naming any
organic compound and applies them to an alkane
component of gasoline.
Other organic compounds are named with a variety
of other prefixes and suffixes. In addition to these
systematic names, we’ll also note important
common names still in use.
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-: Alkyl group
بعد حذف ذرة هيدروجين alkaneتعرف المجوعة المتبقية من ال
توضع اصرة تساهمية للارتباط بدل ذرة . وعادة alkylبال
-وبالشكل الاتي : alkane الهيدروجين التي فقدها
2n+HnC 1- اصرة تساهمية
Alkane Alkyl group
4 CHmethane
-3CH methyl
3CH-3CH ethane
-2CH3CHethyl
3 CH-2CH -3CHpropane
-2CH2CH3CH propyl
3 CH2CH3CHpropane
3CHCH3CH I iso propyl
│
nomenclature of alkanesIUPAC نظام التسمية للبارافينات ) ايوباك (
3CH5 -- 2 CH4 – 2CH 3–CH 2–3 CH 1
I
3CH
ذرات الكاربون من الطرف القريب أطول سلسلة متصلة من ترقم -1
وهنا هو ( (Rootلأقرب تفرع ويعطى لها اسم الالكان المقابل
(pent-) المساوي لخمسة ذرات كاربون ، ثم تسمية نوع
ويصبح الأسم عندها :ane وهنا المقطع هو suffix المركب
Pentane ) )
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مجاميع الكيل وهي prefixes الفروع تعيين مواقع وانواع -2
(alkyl او )أرقام ذرات الكاربون المرتبطة ب المجاميع المعوضة
. وتصبحبها
( 2- methyl pentane )
3- ، الفوارز) الارقام استعمال بين ) , ( الرقم -والخط بين )
والاسم في التسمية .
المعوضة -4 المجاميع عدد على المتشابهة المتماثلة للدلالة ( )
-نستعمل المقاطع الاتية :
monoاحادي -ا
di ثنائي -ب
tri ثلاثي -ج
tetraرباعي -د
pentaخماسي -ه
لغرض تسمية موقع المجموعة من السلسلة ، فأن المجموعة -5
الرئيسة ترقم من الطرف الأقرب للفرع للحصول على أقل الأرقام
للفرع ، وعندما يكون هناك اكثر من فرع فأنها تثبت حسب الحروف
. الإنكليزيةالأبجدية باللغة
Depicting Alkanes with Formulas and Models:
Chemists have several waysصور الألكانات بالصيغ والنماذج
to depict organic compounds: 1- Expanded,
2- condensed 3- carbon-skeleton formulas are
easy to draw,4- ball and stick and 5-space-filling
models show the actual shapes.
The expanded formula shows each atom and bond.
One type of condensed formula groups each C
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atom with H atoms. Carbon- skeleton formulas
show only carbon-carbon bonds and appear as
zig-zag lines, often with branches. Each end or
bend of a zig- zag line or branch represents a C
atom attached to the number of H atoms that give it
a total of four bonds. (see FiG. below).
Cyclic Hydrocarbons ;
A cyclic hydrocarbon contains الهيدروكاربونات الحلقية
one or more rings in its structure. When a straight-
forms a ring, two H atoms )2n+2Hn(Cchain alkane
are lost as the C—C bond forms to join the two
ends of the chain. Thus, cycloalkanes have the
. Cyclic hydrocarbons are 2nHnCgeneral formula
often drawn with carbon-skeleton formulas, as
shown at the top of Figure below.
Except for three-carbon rings, cycloalkanes are
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nonplanar: This structural feature arises from the
tetrahedral shape around each C atom and the
need to minimize electron repulsions between
adjacent H atoms. As a result, orbital overlap of
adjacent C atoms is maximized. The most stable
form of cyclohexane, called the chair conformation,
is shown in Figure D.
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Constitutional Isomerism and the Physical
Properties of Alkanes;
that two or more compounds with الايزومرات الهيكلية
the same molecular formula but different properties
are called isomers. Isomers with different
arrangements of bonded atoms are constitutional
(or structural) isomers; alkanes with the same
number of C atoms but different skeletons are
examples.
The smallest alkane to exhibit constitutional
isomerism has four C atoms: two different
compounds have the formula C4H10, as shown
before. The unbranched one is butane (common
name), n-butane:( n- stands for "normal,” or having
a straight chain), and the other isomer is
2-methylpropane (common name, isobutane).
Similarly, three compounds have the formula
C5H12 (shown in Table below).
The unbranched isomer is pentane (common
name, n-pentane); the one with a methyl group at
C-2 of a four-C chain is 2-methylbutane (common
name, isopentane). The third isomer has two
methyl branches on C-2 of a three-C chain, so its
name is 2,2-dimethylpropane (common name,
neopentane).
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-Physical properties :
1-Insoluble in water but soluble in nonpolar
solvent such as benzene.
2- As its molecular weight increase its boiling
and melting points increase , due to Van
Der walls inter action .
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3- Liner alkanes have greater boiling and
melting points from those corresponding
branch alkanes with the same molecular weight.
Because alkanes are nearly nonpolar, their
physical properties are determined by
dispersion forces, as the boiling points (see table
below).
The four-C alkanes boil lower than the five-C
compounds. Moreover, within each group of
isomers, the more spherical member isobutane or
neopentane) boils lower than the more elongated
one (n-butane or n-pentane). This trend occurs
because a spherical shape leads to less
intermolecular contact, and thus lower total
dispersion forces (such as Van Der walls inter
action), than does an elongated shape.
A particularly clear example of the effect of
dispersion forces on physical properties occurs
among the unbranched alkanes (n-alkanes).
Among these compounds, the longer the chain, the
greater the intermolecular contact, the stronger the
dispersion forces, and the higher the boiling point
(Figure below).
The solubility of alkanes, and of all hydrocarbons, is
easy to predict from the ( like -dissolves-like )
rule. . Alkanes are miscible in each other and in
other nonpolar solvents, such as benzene, but are
nearly insoluble in water. The solubility of pentane
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in water, for example, is only 0.36 g/L at room
temperature.
Chiral Molecules and Optical Isomerism ;
Another type of البصرية الجزيئات نوع كايرل والأيزومرات
isomerism exhibited by some alkanes and many
other organic (as well as some inorganic)
compounds is called stereoisomerism.
Stereoisomers; are molecules with the same
arrangement of atoms but different orientations of
groups in space.
Optical isomerism is one type of
stereoisomerism; when two objects are mirror
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images of each other and cannot be superimposed,
they are optical isomers, also called enantiomers.
To use a familiar example, your right hand is an
optical isomer of your left. Look at your right hand in
a mirror, and you will see that the image is identical
to your left hand . No matter how you twist your
arms around, however, your hands cannot lie on top
of each other with all parts superimposed. They are
not superimposable because each is asymmetric:
there is no plane of symmetry that divides your
hand into two identical parts.
An asymmetric molecule is called chiral.
Typically, an organic molecule is chiral if it contains
a carbon atom that is bonded to four different
groups. This C atom is called a chiral center or an
asymmetric carbon. In 3-
methylhexane, for example, C-3 is a chiral center
because it is bonded to four different groups:
H- , CH3- , CH3 -CH2- , and
.(Figure below) -CH2-CH2-CH3
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Like your two hands, the two forms are mirror
images and cannot be superimposed on each other.
when two of the groups are superimposed, the
other two are opposite each other. Thus, the two
forms are optical isomers.
Unlike constitutional isomers, optical isomers are
identical in all but two respects:
1. In their physical properties, optical isomers differ
only in the direction that each isomer rotates the
plane of polarized light.
A Polari meter is used to measure the angle that
the plane is rotated. A beam of light consists of
waves that oscillate in all planes. A polarizing filter
blocks all waves except those in one plane, so the
light emerging through the filter is plane-polarized.
An optical isomer is optically active because it
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rotates the plane of this polarized light.
The dextrorotatory isomer (designated D or +)
rotates the plane of the light clockwise; the
levorotatory isomer (designated L or -) is the mirror
image of the D isomer and rotates the plane
counterclockwise.
An equimolar mixture of the two isomers does not
rotate the plane at all because the opposing
rotations cancel.
2. In their chemical properties, optical isomers
differ only in a chiral (asymmetric) chemical
environment.
one that distinguishes "right-handed" from “left-
handed” molecules. As an analogy, your right hand
fits well in your right glove but not in your left glove.
Optical isomerism plays a vital role in living
cells. Nearly all carbohydrates and amino
acids are optically active, but only one of the
isomers is biologically usable.
For example, d-glucose is metabolized for energy,
but l-glucose is excreted unused.
Similarly, l-alanine is incorporated naturally into
proteins, but d-alanine is not.
Many drugs are chiral molecules of which one
optical isomer is biologically active and the other
has either a different type of activity or none at all.
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- :Laboratory preparation of Alkanes
1-Heating the salts of organic acids :-
3+ BaCO 3CO2Na + 4˃2CH------ ∆ ---- 2+ Ba(OH) COONa32CH
methane e Barium hydroxid Sodium acetate
3CO2Na + 3CH -3˃ CH----- ∆ -----NaOH COONa +2 CH– 3CH
Sodium ethanoate ethane
2- Using Grignard Reagent :-
كرينيارد كاشف فلز RMgX يحضر مع الكيل هاليد معاملة من
: المغنيسيوم في الايثر الجاف كمذيب
R – X + Mg ------dry ether----------˃ R Mg X
Grignard reagent
I-Mg-3CH ˃ -------dry ether -------I + Mg 3CH
Methyl iodide methyl magnesium iodide
ويمكن تحضير الالكانات من هذا الكاشف بطريقتين :
A- Hydrolysis of Grignard التحلل المائي لكاشف كرينيارد -1
reagent
R – Mg- X + HOH ----------˃ RH + Mg(OH) X
+ Mg(OH) I 4˃ CH--------- HOH + Mg I 3CH
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B- Reaction of عل كاشف كرينيارد مع هاليد الكيلتفا -2
Grignard reagent with alkyl halide
2+ MgXR' –˃ R -------------X –X + R' -Mg-R
Ex:
2MgI + 3CH – 3CH ˃ ----------- I -3I + CH-Mg -3CH
) Mg (Br)( Cl+ 3 CH-2CH-3˃ CH--------Br 3Cl + CH-Mg-2CH -3CH
C- Hydrogenation of Alkenes using Pt or Ni
Pt or Ni
3CH – 3CH ˃ ----------------- 2+ H 2 = CH2 CH
Ethylene Ethane
Chemical properties of alkane
1-Combustion:
O2+ 2H 2˃ CO---------- 2+ 2O 4CHطاقة حرارية +
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2- Thermal decomposition
2 = CH 2+ CH 4CH
methane ethylene
∆
˃-----------3 CH -2CH -3CH
CH3- CH = CH2 + H2
Propene
3- Halogenation :-
EX :- a- Chlorination of methane:-
CH4 + Cl2 ----light or U.V------˃ CH3Cl + HCl
CH3Cl + Cl2 --- light or U.V -----˃ CH2Cl2 + HCl
CH2Cl2 + Cl2 ----light or U .V-- ---˃ CHCl3 + HCl
CHCl3 + Cl2 ----light or U..V -----˃ CCl4 + HCl
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Chlorination of other alkanes :-
EX :- ( propane )
CH3- CH2CH2Cl
n- propyl chloride
CH3- CH2 – CH3 + Cl2 ----- U.V ----
propane Cl
CH3- CH – CH3
2-chloro propane