Download
1 / 75
750 likes | 762 Views
Explore the basics of biochemistry, from atoms to compounds and chemical reactions. Learn about isotopes, bonds, water properties, and more. Discover the fundamental concepts that govern the chemistry of life.
E N D
Biochemistry The Chemistry of Life
Basic Chemistry • Atom • Simplest unit of matter • Made up of three different “subatomic” particles
Subatomic Particles • Protons • Have a positive charge (+) • Have mass • Located in nucleus • Neutrons • Are neutral, have no charge (0) • Have mass • Located in nucleus • Electrons • Have a negative charge (-) • Almost no mass • Located in “energy levels” outside of nucleus
Atomic Number: • Tells you the number of protons an atom has, and also the # of electrons Atoms are neutral # Protons (+) = # Electrons (-)
Atomic Mass: • Add together the number of protons and neutrons in nucleus of atom • Electrons hardly contribute any mass
Isotopes: • Atoms of one type of element with different atomic masses • Same # of protons • Different # neutrons • Changes the mass only, the properties are the same
Radioactive Isotopes: • The nucleus of some isotopes is unstable • The atom with emit radiation • Radiation can be measured with tools • ex. Geiger counter • These isotopes can be used as useful tools in science • Ex: • Carbon-14 dating • Radiation treatment for cancer
Elements • Substance made of only one type of atom • Each element has a unique atomic # • Elements most commonly found in living things • Carbon (C) • Hydrogen (H) • Oxygen (O) • Nitrogen (N)
Compounds • Two or more elements chemically combined • Atoms held together by bonds. • Once bonds form, compounds will have new, and different properties
Organic Compounds • Contains carbon and hydrogen (and often O, N) • Ex: Glucose (C6H12O6), carbohydrate, lipids, proteins • Inorganic Compounds • Doesn’t contain carbon and hydrogen together • Ex: H2O, CO2, NH3, NaCl
Why do atoms form compounds? • Bonds that form between atoms give atoms a stable outer electron level. • Called a “stable octet” of valence electrons (8)
Types of Chemical Bonds • Ionic Bonds: • One or more electrons are transferred from one atom to another. • Neutral atoms become positive & negative ions • Forms salts • (Ex: NaCl) Ionic bond = attraction between (+) and (-) ions
Covalent Bonds: • Electrons are shared between atoms • Each bond represents a shared pair of electrons • Can form single, double or even triple bonds
Covalent bonds form molecules • Subscripts in the formula tell # of each atom • Ex: H2O, NH3, CO2, CH4
Ionic Bonds: Transfer electrons Covalent Bonds: Share Electrons
Properties of Water • Water is necessary for life • Contains covalent bonds
Water Molecules: H2O (look like Mickey Mouse)
Water is a “Polar” molecule (like a magnet) • The bonds are “polar” • Oxygen attracts the electrons more than Hydrogen
Hydrogen Bonding: bonding between the (+) H of one molecule and the (-) end of another molecule. • Makes water good at sticking to itself and other substances • Makes water good dissolver
Cohesion: water sticks to itself • Ex: • Water forms “beads” on smooth surface • Surface Tension allows insect to “skate”
Adhesion: water sticks to other substances • Ex: Capillary action: water molecules rise up small tubes
Heat Capacity: • Water has a relatively high heat capacity • Ex: • Lakes and oceans can absorb a lot of heat from sun without a drastic temperature change
Water as a Solvent: • Dissolves most ionic and covalent substances • “Universal Solvent” = many things can dissolve in it.
Solute: substance being dissolved • Solvent: substance in which solute dissolves • Solution: evenly disbursed mixture • Suspensions: material in the water but just suspended not dissolved (ex: blood cells in blood)
pH of Solutions • pH Scale: way to measure concentration of H+ ions in solution • Ranges from 0 to 14 • Pure water is neutral pH = 7
Litmus Paper: • Used to test pH of a solution • Red = acidic • Blue = basic
Acids: Form H+ ions • pH is <7 • Ex: HCl (stomach acid), lemon juice
Bases: Produces OH- (hydroxide ions) • Also called “alkaline” • pH >7 • Ex: Lye (NaOH) used as drain cleaner
Buffers: • Maintain pH at a certain level • Usually between 6.5 – 7.5 (close to neutral) • Helps to maintain homeostasis in organism
Major Types of Chemical Reactions • Dehydration Synthesis: (Condensation) • Chemically combine two smaller molecules • Water is removed • “Dehydrate” = remove water • “Synthesis” = to make
Hydrolysis: • Break apart large molecule into smaller pieces • Water is added • “Hydro” = water “Lysis” = to break
Polymerization: • Create a large molecule (polymer) • Join up smaller “monomer” units • Often a dehydration synthesis reaction Ex: Join amino acids (monomer) to make protein (polymer) Join glucose (monosaccharide) to make starch (polysaccharide)
Carbohydrates • Sugars and starches • FUNCTION: • Used as an energy source • Energy released during cellular respiration • Made of carbon, hydrogen and oxygen Ex: C6H12O6, C12H22O11 • Ratio of H of O is always 2:1
Basic Structure: • “Ring” made of 5 carbons and 1 oxygen • Rings can join up by dehydration synthesis
3 Types of Carbohydrates • Monosaccharide's: 1 sugar ring • Disaccharides: 2 sugar rings • Polysaccharides: many sugar rings
Monosaccharide's: (Simple sugars) • All have formula C6H12O6 • Single ring structure • End in “-ose” • Ex: glucose, fructose, galactose
Disaccharides: double sugars • All have formula C12H22O11 • End in “-ose” • Ex: sucrose, lactose, maltose
Polysaccharides: 3 or more sugar units • Ex: • Starch (energy storage in plants) • Glycogen (how animals store sugar in liver) • Cellulose (plant cell walls) • Chitin (insect exoskeletons)
Simple sugars form into complex sugars by dehydration synthesis (condensation). • Combining molecules by removing water Monosac. + Monosac. Disac. + Water C6H12O6 +C6H12O6 C12H22O11 + H2O
Complex sugars are broken down into simple sugars by hydrolysis. • Breaking down molecules by adding water • Also called chemical digestion Disac.+ Water Monosac. + Monosac. C12H22O11 + H2O C6H12O6 +C6H12O6
