Biology Chapter 2 Part 1 - Tagged PDF

Summary

This document covers a variety of concepts related to atomic structure, molecules, compounds, chemical bonds, and chemical reactions as part of a biology course. It includes details on chemical bonding, ionic and covalent bonds and chemical reactions used to detail biological processes.

Full Transcript

BIOLOGY
1
COMPOSITION OF MATTER
Atoms
Building blocks of elements
Atoms of elements di5er from one another
Subatomic Particles
Nucleus
Protons (p+) are positively charged
Neutrons (n0) are uncharged or neutral
Orbiting the nucleus
Electrons (e–) are negatively charged
Atoms are electrically neutral:
Number of protons equals numbers of electrons in
an atom
Ions are atoms that have lost or gained electrons5
Subatomic Particles

6
(a) Hydrogen (H) (b) Helium (He) (c) Lithium (Li)
(1p+; 0n0; 1e–) (2p+; 2n0; 2e–) (3p+; 4n0; 3e–)

KEY:
Proton
Neutron
Electron

F I G U R E 2. 2 ATO M I C S T R U C T U R E O F T H E T H R E E S M A L L E S T ATO M S.

7
MOLECULES AND COMPOUNDS
Molecule—two or more atoms of the same
elements combined chemically
Example: H (atom)  H (atom) H2
(molecule)
(reactants) (product)
Compound—two or more atoms of dierent
elements combined chemically to form a
molecule of a compound
Example: 4H  C CH4 (methane)

8
CHEMICAL BONDS AND CHEMICAL REACTIONS

- Electrons are distributed around the dense
core of atoms in shells (orbitals):
- 1st shell takes only 2 electrons to Cll up
(stabilize). That is why atoms of helium He2
are stable (nonreactive or inert).
- 2nd, 3rd, …7th shell: each takes 8 electrons
to be complete.
- Number of electrons in the last shell
(valence shell) is key in determining the
chemical bonding behavior of atoms

9
CHEMICAL BONDS AND CHEMICAL REACTIONS

If valence shell of an atom has 2 (helium) or
8 (Neon, Argon, Xenon, …etc) electrons, the
atom is stable (non-reactive or chemically
inert)
When the valence shell is less than 8, the
atom tends to gain, lose, or share electrons
with other atoms to complete their
outermost orbital.
Chemical bonds form. This will lead to:
Atoms reach a stable state
Bond formation produces a stable valence
shell 10
 (a) Chemically inert elements
Outermost energy level
(valence shell) complete

8e
2e 2e
He Ne

Helium (He) Neon (Ne)
(2p+; 2n0; 2e–) (10p+; 10n0; 10e–)

F I G U R E 2. 5 A C H E M I C A L LY I N E R T A N D R E A C T I V E E L E M E N T S.
11
 (b) Chemically reactive elements
Outermost energy level
(valence shell) incomplete

4e
1e 2e
H C

Hydrogen (H) Carbon (C)
(1p+; 0n0; 1e–) (6p+; 6n0; 6e–)

1e
6e 8e
2e 2e
O Na

Oxygen (O)
(8p+; 8n0; 8e–) Sodium (Na)
(11p+; 12n0; 11e–)
F I G U R E 2. 5 B C H E M I C A L LY I N E R T A N D R E A C T I V E E L E M E N T S. 12
CHEMICAL BONDS
Ionic bonds
Form when electrons are completely
transferred from one atom to another
Allow atoms to achieve stability through the
transfer of electrons
Ions
Result from the loss or gain of electrons
Anions have negative charge due to gain of
electron(s)
Cations have positive charge due to loss of
electron(s)
Tend to stay close together because
opposite charges attract 13
 Chemical Bonds
Ionic bonds

+ –

Na Cl Na Cl

Sodium atom (Na) Chlorine atom (Cl) Sodium ion (Na+) Chlorine ion (Cl–)
(11p+; 12n0; 11e–) (17p+; 18n0; 17e–)
Sodium chloride (NaCl)

F I G U R E 2. 6 F O R M AT I O N O F A N I O N I C B O N D. 14
CHEMICAL BONDS
Covalent bonds
Atoms become stable through shared electrons
Electrons are shared in pairs
Single covalent bonds share one pair of
electrons
Double covalent bonds share two pairs of
electrons
Examples of atoms that can make covalent
bond:
C and C, C and H, O and O, O and H, N and H,
etc.

15
Chemical Bonds
Covalent bonds

16
 Chemical Bonds
Covalent bonds
Reacting atoms Resulting molecules

H
H

H

C H C H or

H

H
H

Hydrogen atoms Carbon atom Molecule of methane gas (CH4)
(c) Formation of four single covalent bonds

F I G U R E 2. 7 C F O R M AT I O N O F C O VA L E N T B O N D S. 17
CHEMICAL BONDS
COVALENT B ONDS

Covalent bonds are either nonpolar or polar
Nonpolar
Electrons are shared equally between the
atoms of the molecule (e.g.: C-C and C-H)
Electrically neutral as a molecule
Example: carbon dioxide

(a) Carbon dioxide (CO2)

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CHEMICAL BONDS
COVALENT B ONDS

Polar
Electrons are not shared equally between
the atoms of the molecule (one of the
atoms have higher aHnity for the
electrons than the other
Molecule has a positive and negative side,
or pole δ–
Example: water
δ+ δ+

(b) Water (H2O)
19
CHEMICAL BONDS

Hydrogen bonds
Form between atoms in molecules with
polar covalent bonds
Weak chemical bonds
Hydrogen is attracted to the negative
portion of a polar molecule
Provides attraction between molecules
Responsible for the surface tension of water
Important for forming intramolecular bonds,
as in protein structure

20
 Hydrogen Bonds
δ+
H H
O
δ–

Hydrogen
bonds
δ+

δ+
δ– δ– δ–
H H
O O
δ+
δ+
H H
H
δ+
O
H
δ–
(a) (b)

21
F I G U R E 2. 9 H Y D R O G E N B O N D I N G B E T W E E N P O L A R WAT E R M O L E C U L E S.
PATTERNS OF CHEMICAL REACTIONS
Synthesis reaction (A  B AB)
 Atoms or molecules combine
 Energy is absorbed for bond formation
 Underlies all anabolic activities in the body
Decomposition reaction (AB A  B)
 Molecule is broken down
 Chemical energy is released
 Underlies all catabolic activities in the body
Exchange reaction (AB  C AC  B and AB  CD
AD  CB)
 Involves both synthesis and decomposition
reactions as bonds are both made and broken
In general, most chemical reactions are reversible 22
 CHEMICAL REACTIONS

Absorb energy Release energy
Absorb & release energy
Anabolic Catabolic Anabolic /
catabolic (condensation) 23
Factors inIuencing rate of chemical reactions

24
TA B L E 2. 4 FA C T O R S I N C R E A S I N G T H E R AT E O F C H E M I C A L R E A C T I O N S.
BIOCHEMISTRY: CHEMICAL
COMPOSITION OF LIVING MATTER
Chemicals found in the body are either
Inorganic or Organic compounds
-Inorganic compounds: mostly lack carbon
and/or small;
e.g., CO2, H2O, NH3, NaCl, Calcium, etc.
Inorganic compounds in biological systems
include water, salts, acids, and bases
- Organic compounds: contain Carbon, tend
to be larger in size than inorganic
compounds; e.g., glucose (C6H12O6), lipids,
proteins, etc.
Organic compounds in living matter include
proteins, lipids, sugars and nucleic acids25
 INORGANIC COMPOUNDS

Water :
All properties are related to its ability to form
hydrogen bonds
High Heat capacity: amount of heat required
to raise the temperature of one mole or one
gram of a substance by one degree Celsius
without change of phase.
This means that water can absorb or release
large amount of heat before changing
temperature suddenly (sun exposure, winter,
etc.)
Polarity/solvent properties: because of its
polarity, water is the most common solvent
for inCnite number of solutes; it is a
Universal solvent. 26
 INORGANIC COMPOUNDS

Water properties (cont.)
Capillary action: ability of water to Iow in
narrow spaces without the assistance of, and
in opposition to external forces like gravity
High Surface tension: increased cohesion of
water molecules to each others. Think of the
ability of some insects (e.g., water striders) to
run on the water surface
Chemical Reactivity: Water is an important
reactant in many types of chemical reactions.
Hydrolysis is the breakdown of large
molecules due to addition of water into the
reaction
Cushioning /protection: Iuids (water solutions)
around heart, brain (CSF), developing fetus, 27
INORGANIC COMPOUNDS

Salts:
Ionic compounds that contain cations (other
than H+) and anions (other than OH-)
Salts of many metals are present in our bodies.
e.g.: calcium salts (found in bone & teeth) and

phosphorous (found in bone, teeth,
nucleic acid)
Easily dissolve (dissociate) in solvents like water
Salts dissolved in body Iuids to form ions
(electrolytes= conductors of electricity).
e.g.: Sodium Chloride (Na+ and Cl-) is an example
of electrolyte in blood
Electrolyte (ionic) balance is very important for
the normal functioning of the body  loss of 28
INORGANIC COMPOUNDS
Acids:
Substances that release H+ (protons)
Taste sour, very corrosive and damaging.
Acids that ionize completely and release their
protons are called strong acids (HCl)
HCl  H+ + Cl- (complete dissociation)
(proton) (anion)

Acids that dissolve partially are called weak
acids (e.g., carbonic acid).
H2CO3  H+ + HCO3- + H2CO3 (partial
dissociation)
(proton) (anion)
29
 100 HCl 100 H+ + 100 Cl-

100 NaOH 100 Na+ + 100 OH-

H+
100

H Cl
100

100 Cl-

pH= - log [H+]
= - log

30
INORGANIC COMPOUNDS
Bases:
Substances that accept H+ (protons) 
release OH- to accept H+ and form water
Taste bitter and have a slippery feeling to
them,
NaOH  Na+ + OH-
cation hydroxyl ion

Bases that dissociate completely and release
all their OH- are considered strong bases
(NaOH)
HCO3- can function as a weak base as it
accepts H+
Neutralization Reaction: Type of exchange
31
INORGANIC COMPOUNDS
The pH concept
- The concentration of protons [H+] in
solutions (in blood, body Iuids, etc.) reIects
the degree of acidity or alkalinity of the
solution.
- It is not easy to directly measure proton [H+]
concentration in a solution.
-But as protons are ions (conductors of
electricity), we can indirectly measure their
relative concentration by measuring their
degree of conductivity in the solution.
-The output (reading) is called the pH = which
is a measure of proton activity ([H+]) in a
32
INORGANIC COMPOUNDS
The pH concept (cont.)
-Example 1: if [H+]= 0.00001=10-5, then pH=
-Log [10-5]  -(-5)=5
-Quiz 1: if [H+]= 0.000001, then pH=?
-Example 2: If pH=3, then–log
H+=3[H+]=10-3= 0.001
-Quiz 2: if pH=8, then H+ = ?
A di5erence of 1 unit = 10x up- or down-
change in [H+];
A change in pH from 4 to 5 = 10-fold
decrease in [H+]
A change in pH from 6 to 5 = 10-fold
increase in [H+] 33
INORGANIC COMPOUNDS
The pH concept (cont.)
pOH is also a measure of proton activity in a
solution.
Example: if [OH-] = 10-7, then
pOH = -Log [OH-]  - (-7) = 7

Hence, pH = 14 – 7 = 7 (neutral solution)
Range of pH scale = Zero (very acidic) to 14
(very basic)
pH 7 is basic or alkaline
34
The pH scale and
pH values of
representative
substances

35
INORGANIC COMPOUNDS
Bu5ers
In biological systems, range of [H+] (or
proton activity) is narrow. Increased or
decreased [H+] can disrupt or damage
biological molecules, halt metabolism or kill
cells.
Example: [H+] in blood is around = 10-7 M;
any sudden change in blood [H+] could be
fatal  needs to be regulated
Bu5ering systems exist to prevent sudden or
dramatic changes in [H+]
Weak acids and weak bases are good bu5ers
36