UTS 14,NOVEMBER 2012
1. pure substance X is solid at room temperature. if the substance is heated to 230 ℃ is melted gradually. if then cooled to room temperature, the liquid can not be frozen.
a) is it possible X of an element or a compound. explain it!
answer : X is a compound. The compound is a collection of several elements. If a compound in the melt by the heat will melt easier. But it will be difficult molten liquid solidifies at the same temperature setting before him in the melt. If you want to make it freeze then the need is even lower temperatures. It may be a temperature below 0 ℃.
b) does it a chemical change occurred ? if so can it be said to undergo an endotherm changing, based on the information provided?
answer : chemical changes that occur can be called endothermic reactions. Endothermic reaction is a reaction that is accompanied by heat transfer from the environment to the system (heat absorbed by the system from its environment); characterized by a decrease in ambient temperature around the system. Substance X which initially are solid when heated at a temperature of 230 ℃ to melt in the heat in the environment caused due to move to the substance, so that the substance to be melted and the temperature in the substance becomes higher than
the temperature of their environment.
c) Can it be said that the liquid is an element, based on the information provided.
answer : there are elements which are in fluid. For instance mercury. But based on the information that is given me to say that it's open compound elements.
2. When
the wax weight of 10 grams burned in oxygen, carbon dioxide and water
vapor formed by the combustion weigh more than 10 grams. Is this game any case law of mass. Explain.
The answer is:
Including
the law of mass eternity (lavoiser) burned candles will melt and when
cooled again will freeze again, in the process also formed wax
pembekaran Co2 + H2O in the form of gas, it was the cause of the change
in mass before and after the burn bkar, but if the count is its chemical calculations should no striking difference in the mass before and after the fuel is burned.
3. When carbon burns oxygen with kimited number, will form two gas compounds. Suggest a way to differentiate the two compounds with one another?
the answer is:
was about the enthalpy of combustion ...
Her compound is Karb on dioxide and water,
How to distinguish is because each process will generate the combustion gases are CO2 + 2 H2O,
while the incomplete combustion CO + H2O.
more details are to distinguish the two compounds with one another by adding a non-polar compounds or compounds that make the state reached saturation point.
4. After mendeev compiled theperiodic table, he concluded that the atomic weights of some elements was the wrong decision, and this conclusion appears to be true. How Mendeleev able to predict that the atomic weight of some wrong? Why predictions are not always right. Explain!
the Answer is:
conclusions do seem true
Medeleev because taking the average total value of the four elements to determine the elements sought.
According to Mendeleev,
"If there is a particular group of elements, R1, R2, R3, and if some elements of R2 are elements of Q2 and T2, then the properties of R2 is determined by the average properties of the R1, R3, Q2 and T2"
why ramalanya is not always true. because the difference between the masses is not always 2, but the range of 1 and 4
OR
Mendeleyev had predicted the properties of elements and it is a prophecy after the elements were found. Arrangement of the elements of Mendeleev perfected under the law and called Mendeleev periodic system.
Mendeleev periodic system consisting of groups (elements located in a single column) and period (the elements which lie on one line)
5.. When mekuri chloride solution is added to a solution of silver nitrate, a white solid forms. Identification of a white solid and write a balanced equation for the reaction.?
the answer is
Sediment on the results of a white precipitate of silver nitrate ..
her reksih
Hg2CL2 AgNO3 ------ + Hg (No3) 2 + HgCl2
equalization reraksi
HgCl2 + 2AgNo3 = HG (No3) 2 + 2AgCl
White solid: AgCl
Rabu, 14 November 2012
Sabtu, 03 November 2012
Atomic Structure and the Periodic System Elements
At this time have been found over a hundred elements and so many chemical compounds that have been biosynthesized. How can we easily learn the elements of it? The chemists have grouped elements based on the properties of chemical and physical properties that are similar or the same.
To learn grouping elements by their nature can be used periodic table of elements. Elements Periodic Table of classification evolved from simple to complete. The periodic table used today is the modern periodic table are arranged by atomic number increases and the similarity of the properties of the elements. In the modern periodic table, elements are grouped into classes and periods.
Element on the periodic table, the symbol of the element is equipped with atomic mass and atomic number. From these data we can determine the atomic structure of an element ffffseperti protons, neutrons, electrons and electron configuration.
In the periodic table of elements we unsuir DAPT study the properties of metals, metalloids, non-metals, and the periodic nature of the fingers, enenrgi ionization, electron affinity, and electronegativity.
A. Development of the Periodic Table of Elements
Grouping elements initiated by the Antonine Lavovoisier grouping elements into metals and non-metals. Furthermore, grouping elements developed in various forms and is known by Triade Doberiener, Octave Newlands, Lothar Meyer Periodic Table of Elements and Mendeleve and Modern Periodic Table.
1. Periodic Table of Elements Antoine Lavoisier
Antoine Lavoisier in 1789, a French chemist dividing the elements into four groups. To know the classification, consider Table 1.1.
Table 1.1 Classification of the element by Antoine Lavoisier
Listed in Table 1.1 and the heat instead of light elements. In group IV included compounds that can not be decomposed into elements known today.
2. Law Triade Dobereiner
J.W. Dobereiner in 1817 grouping the elements that have similar properties, each group consisting of three elements called triade.
To study these laws do activities follows.
Dobereiner tried grouping elements that have the same properties of increasing atomic mass, was obtained regularity. If the three elements sorted by atomic mass increases, the mass of the second element equal to the average mass of the first and third elements. This statement is known as the Law of Triade Dobereiner.
3. Newlands Law of Octaves
In 1863, J.W. Newlands sort the elements based on atomic mass increases. How to order a discovery? Try grouping discussed through the following activities
From this grouping apparently the eighth element has similar properties to the first element, as well as elements of the ninth character is similar to the second element, and so on. For example, elements similar to the elements of nature H F and Cl, elements like Li Na and K, as well as elements like Mg Be.
Repetition is the so-called Law of Octaves Newlands as he compared the recurrence properties of elements with scales or octaves on track. Newlands pioneered the preparation of the elements that are similar in vertical columns. Weakness law of octaves that repetition every 8 elements fit only for elements that small atomic mass. In addition there are coincident elements in the same order.
4. Periodic Table of Elements Lothar Meyer
In 1870, Lothar Meyer tried to make a list of the elements with respect to the physical properties of atomic volume. He made the atomic volume graph element to the atomic mass.
To learn how to do the following activities.
In curved Meyer, elements Li, Na, K, Rb, and Cs occupies an equivalent position, which is at the top. Be, Mg, Ca, Sr, and Ba is the second point of the peak. It turns out that the location elements have properties similar equivalent.
5. Mendeleev Periodic Table of Elements
Dimitri Ivanovich Mendeleev in 1869 in Russia put forward the relationship between the mass of an element with the properties of elements. In studying the periodikan elements, Mendeleev than using physical properties also use chemical properties. In research such as New-lands, Mendeleev also arrange elements by atomic mass increases relative and he found no change in the nature of a periodic basis.
Excess Mendeleev periodic table of elements is as follows.
a. The first is the periodic table arranged in the form of eight vertical columns or groups, and seven rows of horizontal or period. Hereinafter referred Mendeleev periodic table of elements.
b. There's an empty place for elements predicted to be found and named eka boron, eka aluminum, and eka silicon. Divination is proved by the discovery of Scandium (1879), Gallium (1875), and Germa-nium (1886). Examples forecast for Germanium Mendeleev called eka silicon listed in Table 1.2.
Mendeleev Table 1.2 Predictions of the nature of the element germanium
c. put the elements He, Ne, Ar, Kr, Xe, and Rn in a separate class after class of noble gases found.
Mendeleev periodic table of elements is described as follows.
Besides advantages, Mendeleev periodic table of elements has several disadvantages as follows.
a. There are some elements of the reverse order when viewed from the increasing relative atomic mass, such as Te (128) placed before the I (127).
b. Triade iron (Fe, Co, Ni), platinum triade light (Ru, Rh, Pd), and platinum triade (Os, Ir, Pt) included in class VIII. Among the elements of this group can only Ru and Os that have valence 8.
6. Modern Periodic Table
Periodic table of elements digunakn now the Modern Periodic Table of Elements. After the periodic table of elements Mendeleev, in 1915 Henry Mosley discover and develop atomic number elements in the periodic table by atomic number increases and menyususun preformance elements of the periodic table by atomic number increases increases. several studies, showing the relationship between the atomic number of the element properties, so Mendeleev table peridik need improvement. Modern elements on the periodic table are arranged in groups and periods
There are 2 numbering system used on golomgan the American system and the IUPAC system. The American system using Roman numerals I through VIII, maing each consisting of class A and B. System IUPAC (International Union Pure and Applied Chemistry) using Arabic agka 1 to 18.
Therefore IPAC group numbering system has not been socialized among chemists, the American sisatem pengolongan more widely used so well in Indonesia.
Modern periodic table of elements are described as follows.
Predictions about the nature of the element germanium Mendeleev
c. put the elements He, Ne, Ar, Kr, Xe, and Rn in a separate class after class of noble gases found.
Mendeleev periodic table of elements is described as follows.
Besides advantages, Mendeleev periodic table of elements has several
disadvantages as follows.
To learn grouping elements by their nature can be used periodic table of elements. Elements Periodic Table of classification evolved from simple to complete. The periodic table used today is the modern periodic table are arranged by atomic number increases and the similarity of the properties of the elements. In the modern periodic table, elements are grouped into classes and periods.
Element on the periodic table, the symbol of the element is equipped with atomic mass and atomic number. From these data we can determine the atomic structure of an element ffffseperti protons, neutrons, electrons and electron configuration.
In the periodic table of elements we unsuir DAPT study the properties of metals, metalloids, non-metals, and the periodic nature of the fingers, enenrgi ionization, electron affinity, and electronegativity.
A. Development of the Periodic Table of Elements
Grouping elements initiated by the Antonine Lavovoisier grouping elements into metals and non-metals. Furthermore, grouping elements developed in various forms and is known by Triade Doberiener, Octave Newlands, Lothar Meyer Periodic Table of Elements and Mendeleve and Modern Periodic Table.
1. Periodic Table of Elements Antoine Lavoisier
Antoine Lavoisier in 1789, a French chemist dividing the elements into four groups. To know the classification, consider Table 1.1.
Table 1.1 Classification of the element by Antoine Lavoisier
Listed in Table 1.1 and the heat instead of light elements. In group IV included compounds that can not be decomposed into elements known today.
2. Law Triade Dobereiner
J.W. Dobereiner in 1817 grouping the elements that have similar properties, each group consisting of three elements called triade.
To study these laws do activities follows.
Dobereiner tried grouping elements that have the same properties of increasing atomic mass, was obtained regularity. If the three elements sorted by atomic mass increases, the mass of the second element equal to the average mass of the first and third elements. This statement is known as the Law of Triade Dobereiner.
3. Newlands Law of Octaves
In 1863, J.W. Newlands sort the elements based on atomic mass increases. How to order a discovery? Try grouping discussed through the following activities
From this grouping apparently the eighth element has similar properties to the first element, as well as elements of the ninth character is similar to the second element, and so on. For example, elements similar to the elements of nature H F and Cl, elements like Li Na and K, as well as elements like Mg Be.
Repetition is the so-called Law of Octaves Newlands as he compared the recurrence properties of elements with scales or octaves on track. Newlands pioneered the preparation of the elements that are similar in vertical columns. Weakness law of octaves that repetition every 8 elements fit only for elements that small atomic mass. In addition there are coincident elements in the same order.
4. Periodic Table of Elements Lothar Meyer
In 1870, Lothar Meyer tried to make a list of the elements with respect to the physical properties of atomic volume. He made the atomic volume graph element to the atomic mass.
To learn how to do the following activities.
In curved Meyer, elements Li, Na, K, Rb, and Cs occupies an equivalent position, which is at the top. Be, Mg, Ca, Sr, and Ba is the second point of the peak. It turns out that the location elements have properties similar equivalent.
5. Mendeleev Periodic Table of Elements
Dimitri Ivanovich Mendeleev in 1869 in Russia put forward the relationship between the mass of an element with the properties of elements. In studying the periodikan elements, Mendeleev than using physical properties also use chemical properties. In research such as New-lands, Mendeleev also arrange elements by atomic mass increases relative and he found no change in the nature of a periodic basis.
Excess Mendeleev periodic table of elements is as follows.
a. The first is the periodic table arranged in the form of eight vertical columns or groups, and seven rows of horizontal or period. Hereinafter referred Mendeleev periodic table of elements.
b. There's an empty place for elements predicted to be found and named eka boron, eka aluminum, and eka silicon. Divination is proved by the discovery of Scandium (1879), Gallium (1875), and Germa-nium (1886). Examples forecast for Germanium Mendeleev called eka silicon listed in Table 1.2.
Mendeleev Table 1.2 Predictions of the nature of the element germanium
c. put the elements He, Ne, Ar, Kr, Xe, and Rn in a separate class after class of noble gases found.
Mendeleev periodic table of elements is described as follows.
Besides advantages, Mendeleev periodic table of elements has several disadvantages as follows.
a. There are some elements of the reverse order when viewed from the increasing relative atomic mass, such as Te (128) placed before the I (127).
b. Triade iron (Fe, Co, Ni), platinum triade light (Ru, Rh, Pd), and platinum triade (Os, Ir, Pt) included in class VIII. Among the elements of this group can only Ru and Os that have valence 8.
6. Modern Periodic Table
Periodic table of elements digunakn now the Modern Periodic Table of Elements. After the periodic table of elements Mendeleev, in 1915 Henry Mosley discover and develop atomic number elements in the periodic table by atomic number increases and menyususun preformance elements of the periodic table by atomic number increases increases. several studies, showing the relationship between the atomic number of the element properties, so Mendeleev table peridik need improvement. Modern elements on the periodic table are arranged in groups and periods
There are 2 numbering system used on golomgan the American system and the IUPAC system. The American system using Roman numerals I through VIII, maing each consisting of class A and B. System IUPAC (International Union Pure and Applied Chemistry) using Arabic agka 1 to 18.
Therefore IPAC group numbering system has not been socialized among chemists, the American sisatem pengolongan more widely used so well in Indonesia.
Modern periodic table of elements are described as follows.
Predictions about the nature of the element germanium Mendeleev
c. put the elements He, Ne, Ar, Kr, Xe, and Rn in a separate class after class of noble gases found.
Mendeleev periodic table of elements is described as follows.
Besides advantages, Mendeleev periodic table of elements has several
disadvantages as follows. |
| Add caption |
Senin, 29 Oktober 2012
Atomic Structure Theory - Definition of Atomic Structure
Atomic Structure Theory - Definition of Atomic Structure
Atomic Structure Theory is a basic unit of matter consisting of a nucleus and its negatively charged electron cloud surrounding it. The nucleus contains a mix of positively charged protons and electrically neutral neutrons (except in Hydrogen-1 which has no neutrons). The electrons in an atom bound to the nucleus by the electromagnetic force. Similarly, a collection of atoms can bind to each other to form a molecule. Atoms containing the number of protons and electrons of the same neutral, while containing the number of protons and electrons of different positive or negative and is ion. Atoms are grouped based on the number of protons and neutrons in the atomic nucleus.
The number of protons in an atom determines the chemical element the atom, and the number of neutrons determine the isotope of the element. The term atom comes from the Greek, which means it can not be cut or something that can not be divided again. The concept of the atom as a component that can not be divided again was first proposed by the philosophers of India and Greece. In the 17th century and into the 18th, the chemists laid the foundations of this idea by showing that certain substances can not be broken down further using chemical methods. During the late nineteenth century and early twentieth century, physicists have managed to find the structure and subatomic components inside the atom, to prove that the 'atom' is not never be divided again. The principles of quantum mechanics used by physicists then successfully model the atom.
Relative to daily observations, the atoms are very small objects with masses as minor anyway. Atoms can only be monitored using special equipment such as tunneling microscope Microscopy. More than 99.9% of the mass of the atom is concentrated in the nucleus, the proton and neutron are almost the same mass. Each element has at least one isotope with unstable nuclei that can undergo radioactive decay.
James Chadwick (1891-1974) discovered
the neutron in 1932. Chadwick was a collaborator of
Rutherford's. Interestingly, the discovery of the neutron led directly
to the discovery of fission and ultimately to the atomic bomb.
Atomic Structure Theory is a basic unit of matter consisting of a nucleus and its negatively charged electron cloud surrounding it. The nucleus contains a mix of positively charged protons and electrically neutral neutrons (except in Hydrogen-1 which has no neutrons). The electrons in an atom bound to the nucleus by the electromagnetic force. Similarly, a collection of atoms can bind to each other to form a molecule. Atoms containing the number of protons and electrons of the same neutral, while containing the number of protons and electrons of different positive or negative and is ion. Atoms are grouped based on the number of protons and neutrons in the atomic nucleus.
The number of protons in an atom determines the chemical element the atom, and the number of neutrons determine the isotope of the element. The term atom comes from the Greek, which means it can not be cut or something that can not be divided again. The concept of the atom as a component that can not be divided again was first proposed by the philosophers of India and Greece. In the 17th century and into the 18th, the chemists laid the foundations of this idea by showing that certain substances can not be broken down further using chemical methods. During the late nineteenth century and early twentieth century, physicists have managed to find the structure and subatomic components inside the atom, to prove that the 'atom' is not never be divided again. The principles of quantum mechanics used by physicists then successfully model the atom.
Relative to daily observations, the atoms are very small objects with masses as minor anyway. Atoms can only be monitored using special equipment such as tunneling microscope Microscopy. More than 99.9% of the mass of the atom is concentrated in the nucleus, the proton and neutron are almost the same mass. Each element has at least one isotope with unstable nuclei that can undergo radioactive decay.
HISTORICAL OUTLINE
of the Atomic Theory and the Structure of the Atom
of the Atomic Theory and the Structure of the Atom
Development of the Atomic Theory
-
Democritus (460-370 BC) First proposed the existence of an ultimate particle. Used the word "atomos" to describe this particle.
Democritus
-
Aristotle (384-322 BC) was a proponent of the continuum. He believed in the four elements of air, earth, water and fire. Aristotle felt that regardless of the number of times you cut a form of matter in half, you would always have a smaller piece of that matter. This view held sway for 2000 years primarily because Aristotle was the tutor of Alexander the Great.
Aristotle
-
Johann Becher (1635-1682) and Georg Stahl (1660-1734) developed the Phlogiston theory which dominated chemistry between 1670 and 1790. Basically, when something burned, it lost phlogiston to the air (after all, you could see the phlogiston leaving) A problem with the theory was that burning of metals resulted in an increase in the mass. This problem was solved by assigning negative mass to phlogiston.
-
Joseph Priestly (1733-1804) discovered oxygen (which he called "dephlogisticated air") in 1774. Priestly was an ardent phlogistonist until his dying day. Priestly was also an early anti-war activist who favored both the American and French Revolutions. He was shipped to the U.S. in 1791 where he lived a quiet life in Pennsylvania. His house was used as a starting point for the American Chemical Society in 1876. The Priestly Medal is the highest award given by to an American chemist by the Society.
Joseph Priestly
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Antoine Lavoisier (1743-1794) was the first person to make good use of the balance. He was an excellent experimenter. After a visit with Priestly in 1774, he began careful study of the burning process. He proposed the Combustion Theory which was based on sound mass measurements. He named oxygen. He also proposed the Law of Conversation of Mass which represents the beginning of modern chemistry. To support his work, Lavoisier was associated with a tax-collecting firm and was married to the daughter of the one of the firm's executives. Some people believe that Madame Lavoisier was every bit as good a scientist as her husband. Unfortunately, this relationship with the tax firm led to Lavoisier's beheading at the guillotine in 1794.
Marie and Antoine Lavoisier
-
Joseph Proust (1754-1826) proposed the the Law of Constant Composition in 1799. This law was very radical at the time and was hotly contested by Claude Berthollet (1748-1822).
Joseph Proust
-
John Dalton (1776-1844) proposed the Law of Multiple Proportions. This law led directly to the proposal of the Atomic Theory in 1803. He also developed the concept of the mole and proposed a system of symbols to represent atoms of different elements. (The symbols currently used were developed by J.J. Berzelius(1779-1848)). Dalton recognized the existence of atoms of elements and that compounds formed from the union of these atoms. He therefore assumed that simplest ratios would be used in nature and came up with a formula for water of HO. He then assigned a relative atomic weight of one to hydrogen and developed a relative atomic weight scale from percent composition data and assumed atomic ratios. Today we would refer to these as equivalent masses. John Dalton also discovered color blindness, an affliction from which he suffered. He determined that five percent of the male population and less than one-tenth percent of the female population was color blind.
John Dalton
-
Joseph Gay-Lussac ( 1778-1850) announced the Law of Combining Volumes in 1808. He showed that at the same temperature and pressure, two volumes of hydrogen gas reacted with one volume of oxygen gas to produce two volumes of water (as a gas).
Joseph Gay-Lussac
-
Amadeo Avogadro (1776-1856) proposed what is now known as Avogadro's Hypothesis in 1811. The hypothesis states that at the same temperature and pressure, equal volumes of gases contain the same number of molecules or atoms. When this is combined with Gay-Lussac's Law of Combining Volumes, the only possible formulas for hydrogen, oxygen and water are H2, O2 and H2O, respectively. The solution to the atomic weight problem was at hand in 1811. However, Avogadro's Hypothesis was a radical statement at the time and was not widely accepted until fifty years later.
Amedeo Avogadro
-
Stanislao Cannizzaro (1826-1910), in 1860 at the Karlsruhe Conference, proposed that Avogadro's Hypothesis be accepted and the implications used for a period of five years. At the end of this five year period, a new conference would be called to discuss any problems that might develop; this second conference was never called.
Stanislao Cannizzaro
- Dimitri Mendeleev (1834-1907) proposed the periodic law and developed the first periodic table in 1869. Medeleev's table was arranged according to increasing atomic weight and left holes for elements that were yet to be discovered.
Dimitri Mendeleev
Development of Atomic Structure
- J. J. Thomson (1856-1940) identified the negatively charged electron in the cathode ray tube in 1897. He deduced that the electron was a component of all matter and calculated the charge to mass ratio for the electron.
e/m = -1.76 x 108 coulombs/g
Thomson and others also studied the positive rays in the cathode ray tube and discovered that the charge to mass ratio depended on filling gas in the tube. The largest charge to mass ratio (smallest mass) occurred when hydrogen was the filling gas. This particle was later identified as the proton.
e/m = +9.58 x 104 coulombs/g
Thomson proposed the "plum pudding" model of the atom. In this model, the volume of the atom is composed primarily of the more massive (thus larger) positive portion (the plum pudding). The smaller electrons (actually, raisins in the plum pudding ) are dispersed throughout the positive mass to maintain charge neutrality.
Joseph John Thomson
- Robert Millikan (1868-1953) determined the unit charge of the electron in 1909 with his oil drop experiment at the University of Chicago. Thus allowing for the calculation of the mass of the electron and the positively charged atoms.
e = 1.60 x 10-19 coulombs
Robert Millikan
- Ernst Rutherford (1871-1937) proposed the nuclear atom as the result of the gold-foil experiment in 1911. Rutherford proposed that all of the positive charge and all of the mass of the atom occupied a small volume at the center of the atom and that most of the volume of the atom was empty space occupied by the electrons. This was a very radical proposal that flew in the face of Newtonian Physics. Although positive particles had been discussed for some time, it was Rutherford in 1920 that first referred to the hydrogen nucleus as a proton. Also in 1920, Rutherford proposed the existence of the third atomic particle, the neutron.
Ernst Rutherford
- Henry Moseley (1887-1915) discovered that the energy of x-rays emitted by the elements increased in a linear fashion with each successive element in the periodic table. In 1913, he proposed that the relationship was a function of the positive charge on the nucleus. This rearranged the periodic table by using the atomic number instead of atomic mass to represent the progression of the elements. This new table left additional holes for elements that would soon be discovered. Unfortunately, Moseley was killed at Gallipoli during WWI.
Henry Moseley
- Francis Aston (1877-1945) invented the mass spectrograph in 1920. He was the first person to observe isotopes. For example he observed that there were three different kinds of hydrogen atoms. While most of the atoms had a mass number of 1 he also observed hydrogen atoms with mass numbers of 2 and 3. Modern atomic masses are based on mass spectral analysis. His work led Rutherford to predict the existence of the neutron.
Francis Aston
What is Atomic Number and Atomic Weight?
- Atomic number of an element is the number of protons in the nucleus of an atom. Since atoms are electrically neutral, the number of protons equal the number of electrons in an atom.
- Atomic weight (or relative atomic mass) of an element is the number of times an atom of that element is heavier than an atom of hydrogen. The atomic weight of hydrogen is taken to be unity [1].
- Mass number of an element is the sum of the number of protons and neutrons in the nucleus of an atom.
Kamis, 18 Oktober 2012
Enthalpy and enthalpy changes Enthalpy and enthalpy change (ΔH)
Enthalpy and enthalpy changesEnthalpy and enthalpy change (ΔH)
Enthalpy (H) is the amount of energy that the system at a constant pressure. Enthalpy (H) is defined as the amount of energy contained in the system (E) and work (W).H = E + Wwith:W = P × VE = energy (joules)W = work system (joules)V = volume (liters)P = pressure (atm)The law of conservation of energy explains that energy can not be created and can not be destroyed, but can only be converted from one form of energy into another form of energy. Energy value of the material can not be measured, which can be measured is the change in energy (ΔE). Similarly, enthalpy, enthalpy can not be measured, we can only measure the change in enthalpy (ΔH).ΔH = Hp - Hrwith:ΔH = change in enthalpyHp = enthalpy of productsHr = enthalpy of the reactants or reagentsa. If the product H> H reactants, then ΔH is positive, it means that the absorption of heat from the environment to the system.b. When the reactant H> H products, then ΔH is negative, which means that the release of heat from the system to the environment.
Mathematically, enthalpy change (ΔH) can be derived as follows.H = E + W (1)At constant pressure:ΔH = ΔE + PΔV (2)ΔE = q + W (3)Wsistem =-PV (4)Substitution of equation (3) and (4) in equation (2):H = (q + W) + PΔVH = (q - PΔV) + PΔVH = qThus, at constant pressure, the change in enthalpy (ΔH) is equal to the heat (q) absorbed or released (James E. Brady, 1990).A wide range of chemical reactions based on the heat released / absorbed heat (Martin S. Silberberg, 2000):a. Chemical reactions that require or absorb heat are called endothermic reactions.Example:Termination of the reaction bonding in the molecule H2 elements are:H2 → 2 H + a = ΔH kJEndothermic with ΔH is positive (+).b. The chemical reaction that releases heat is called exothermic reactions.Example:Bond formation reactions in the H2 molecule elements are:2H → H2 kJ ΔH =-aExothermic reaction with ΔH marked (-).Diagram enthalpy (energy level diagram)
Enthalpy change for the combustion of 1 mole of a substance is measured at 298 K, 1 atm is called the standard enthalpy of combustion (standard enthalpy of combustion), expressed by ΔHc0. Enthalpy of combustion is also expressed in kJ mol -1.
Price enthalpy of combustion of various types of materials at 298 K, 1 atm are given in Table 3 below.
Table 3. Enthalpy of combustion of various types of materials at 298 K, 1 atmgb18
Burning gasoline is exothermic process. If the gas thought to be composed of isooctane, C8H18 (gasoline components) to determine the amount of heat released in the combustion of 1 liter of gasoline. Given the enthalpy of combustion of isooctane = -5460 kJ mol-1 and density isooktan = 0.7 kg L -1 (H = 1 and C = 12).
Answer:Enthalpy of combustion of isooctane is - 5460 kJ mol-1. The mass of 1 liter of gasoline = 1 liter x 0.7 kg L-1 = 0.7 kg = 700 grams. Isooctane = 700 g mol gram/114 mol-1 = 6.14 mol. So the heat released in the combustion of 1 liter of gasoline is: 6:14 x 5460 kJ mol = 33524.4 kJ mol -1.Enthalpy of DecompositionDecomposition reaction is the reverse of the formation reaction. Therefore, in accordance with the principle of conservation of energy, equal to the value of the enthalpy of formation enthalpy of decomposition, but opposite in sign.
Determination of Enthalpy Changes and Hess's Law
To determine the enthalpy changes in chemical reactions commonly used tools such as the calorimeter, thermometer and so on that may be more sensitive.
Calculation: DH reaction = S DHfo products - S reactants DHfo
Hess Law
"The amount of heat required or released in a chemical reaction does not depend on the course of the reaction but is determined by the initial state and the end."
Example: C (s) + O2 (g) ® CO2 (g), DH = x kJ ® 1 stageC (s) + 1/2 02 (g) ® CO (g), DH = y kJ ® 2 stagesCO (g) + 1/2 O2 (g) ® CO2 (g) DH = z kJ-------------------------------------------------- ---------- +C (s) + O2 (g) ® CO2 (g) DH = y + z kJ
According to Hess's Law: x = y + z
Reaction enthalpy change in release or absorbed only depends on the initial state and the final state. The higher the reaction temperature the faster the rate of reaction.
Changes in heat on a substance or perubhan system is determined by the temperature, time and substance specific heat, specific heat is the heat required to raise the temperature of 1 gram of a substance as high as 1 k.
Calculating the amount of heat released or absorbed berdsarkan temperature in solution time and turns the heat capacity of materials specified calories.
Enthalpy is a term in thermodynamics that states the amount of internal energy of a thermodynamic system plus the energy used to do work. Enthalpy can not be measured, which can be calculated is the value changes. Mathematically, the enthalpy change can be formulated as follows:
ΔH = ΔU + PΔV
where:
• H = enthalpy of the system (joules)
• U = internal energy (joules)
• P = pressure of the system (Pa)
• V = volume of the system ()
Enthalpy (H) is the amount of energy that the system at a constant pressure. Enthalpy (H) is defined as the amount of energy contained in the system (E) and work (W).H = E + Wwith:W = P × VE = energy (joules)W = work system (joules)V = volume (liters)P = pressure (atm)The law of conservation of energy explains that energy can not be created and can not be destroyed, but can only be converted from one form of energy into another form of energy. Energy value of the material can not be measured, which can be measured is the change in energy (ΔE). Similarly, enthalpy, enthalpy can not be measured, we can only measure the change in enthalpy (ΔH).ΔH = Hp - Hrwith:ΔH = change in enthalpyHp = enthalpy of productsHr = enthalpy of the reactants or reagentsa. If the product H> H reactants, then ΔH is positive, it means that the absorption of heat from the environment to the system.b. When the reactant H> H products, then ΔH is negative, which means that the release of heat from the system to the environment.
Mathematically, enthalpy change (ΔH) can be derived as follows.H = E + W (1)At constant pressure:ΔH = ΔE + PΔV (2)ΔE = q + W (3)Wsistem =-PV (4)Substitution of equation (3) and (4) in equation (2):H = (q + W) + PΔVH = (q - PΔV) + PΔVH = qThus, at constant pressure, the change in enthalpy (ΔH) is equal to the heat (q) absorbed or released (James E. Brady, 1990).A wide range of chemical reactions based on the heat released / absorbed heat (Martin S. Silberberg, 2000):a. Chemical reactions that require or absorb heat are called endothermic reactions.Example:Termination of the reaction bonding in the molecule H2 elements are:H2 → 2 H + a = ΔH kJEndothermic with ΔH is positive (+).b. The chemical reaction that releases heat is called exothermic reactions.Example:Bond formation reactions in the H2 molecule elements are:2H → H2 kJ ΔH =-aExothermic reaction with ΔH marked (-).Diagram enthalpy (energy level diagram)
Enthalpy change for the combustion of 1 mole of a substance is measured at 298 K, 1 atm is called the standard enthalpy of combustion (standard enthalpy of combustion), expressed by ΔHc0. Enthalpy of combustion is also expressed in kJ mol -1.
Price enthalpy of combustion of various types of materials at 298 K, 1 atm are given in Table 3 below.
Table 3. Enthalpy of combustion of various types of materials at 298 K, 1 atmgb18
Burning gasoline is exothermic process. If the gas thought to be composed of isooctane, C8H18 (gasoline components) to determine the amount of heat released in the combustion of 1 liter of gasoline. Given the enthalpy of combustion of isooctane = -5460 kJ mol-1 and density isooktan = 0.7 kg L -1 (H = 1 and C = 12).
Answer:Enthalpy of combustion of isooctane is - 5460 kJ mol-1. The mass of 1 liter of gasoline = 1 liter x 0.7 kg L-1 = 0.7 kg = 700 grams. Isooctane = 700 g mol gram/114 mol-1 = 6.14 mol. So the heat released in the combustion of 1 liter of gasoline is: 6:14 x 5460 kJ mol = 33524.4 kJ mol -1.Enthalpy of DecompositionDecomposition reaction is the reverse of the formation reaction. Therefore, in accordance with the principle of conservation of energy, equal to the value of the enthalpy of formation enthalpy of decomposition, but opposite in sign.
Determination of Enthalpy Changes and Hess's Law
To determine the enthalpy changes in chemical reactions commonly used tools such as the calorimeter, thermometer and so on that may be more sensitive.
Calculation: DH reaction = S DHfo products - S reactants DHfo
Hess Law
"The amount of heat required or released in a chemical reaction does not depend on the course of the reaction but is determined by the initial state and the end."
Example: C (s) + O2 (g) ® CO2 (g), DH = x kJ ® 1 stageC (s) + 1/2 02 (g) ® CO (g), DH = y kJ ® 2 stagesCO (g) + 1/2 O2 (g) ® CO2 (g) DH = z kJ-------------------------------------------------- ---------- +C (s) + O2 (g) ® CO2 (g) DH = y + z kJ
According to Hess's Law: x = y + z
Reaction enthalpy change in release or absorbed only depends on the initial state and the final state. The higher the reaction temperature the faster the rate of reaction.
Changes in heat on a substance or perubhan system is determined by the temperature, time and substance specific heat, specific heat is the heat required to raise the temperature of 1 gram of a substance as high as 1 k.
Calculating the amount of heat released or absorbed berdsarkan temperature in solution time and turns the heat capacity of materials specified calories.
Enthalpy is a term in thermodynamics that states the amount of internal energy of a thermodynamic system plus the energy used to do work. Enthalpy can not be measured, which can be calculated is the value changes. Mathematically, the enthalpy change can be formulated as follows:
ΔH = ΔU + PΔV
where:
• H = enthalpy of the system (joules)
• U = internal energy (joules)
• P = pressure of the system (Pa)
• V = volume of the system ()
Selasa, 16 Oktober 2012
CHEMICAL REACTION IN ELECTROLYTE SOLUTIONS SOLUTIONS STIKIOMETRI
CHEMICAL REACTION IN ELECTROLYTE SOLUTIONS SOLUTIONS STIKIOMETRI
Acid-base reaction (neutralization reaction).Acid-base reaction or neutralization reaction is the reaction between the acid (H +) and a base (OH-) produced a neutral H2O.Adapaun example neutralization reaction is as follows:
1. Reactions: Acid + base -> salt + waterHNO3 (aq) + KOH (aq) -> KNO3 (aq) + H2O (l)H2SO4 (aq) + Ca (OH) 2 (aq) -> CaSO4 (aq) + H2O (l)
2. Reaction: Oxide + Acid Tongue -> Salt + Water2HCl (aq) + CaO (s) -> CaCl2 (aq) + H2O (l)2HNO3 (aq) + Na2O (s) -> Na (NO3) 2 (aq) + H2O (l)
3. Reactions: Ammonia + Acid -> SaltHCl (aq) + NH3 (g) -> NH4Cl (aq)H2SO4 (aq) +2 NH3 (g) -> (NH4) 2SO4 (aq)Ammonia (NH3), including bases that form molecular compounds that are distinguished from the other two types of bases, ie, ionic compounds that can release OH-ions and okisda bases. There are other basic molecular compounds such as methylamine (CH3NH2) but the reaction is not common as ammonia.4. Reaction: Oxides of acid + base -> salt + waterSO3 (g) + 2NaOH (aq) -> Na2SO4 (aq) + H2O (l)CO2 (g) + Mg (OH) 2 (aq) -> MgCO3 (aq) + H2O (l)Reaction crowding-MetalCrowding-metal reaction is a reaction in which the metal pressing of other metal cations or hydrogen in a compound. This reaction can take place if the metals are on the left of the metal / H which urged the Volta series. In this reaction, the reaction product in the form of metal deposition, gas, and water.Volta Series is a sequence of elements whose reduction potential is based on the data. The following are some elements that can be memorized by a potential reduction sequence:Li - K - Ba - Ca - Na - Mg - Al - Mn - Zn - Fe - Ni - Sn - Pb - (H) - Cu - Hg - Ag - Pt - AuAs an example of crowding-metal reactions are as follows:1. Reactions: 1 + Metal Salt 1 -> 2 + Metal Salt 2Zn (s) + CuSO4 (aq) -> ZnSO4 (aq) + Cu (s)2AL (s) + 3FeSO4 (aq) -> Al2 (SO4) 3 (aq) + 3Fe (s)Cu (s) + Na2SO4 (aq) -> no reaction because Cu is on the right row voltaic2. Reaction: Metal + Acid -> Salt + Hydrogen GasMg (s) + HCl (aq) -> MgCl2 (aq) + H2 (g)Zn (s) + H2SO4 (aq) -> ZnSO4 (aq) + H2 (g)Ag (s) + HCl (aq) -> Ag does not react due to the right of the voltaic series3. Reaction: Metal + Acid -> Salt + Water + Gas2Fe (s) + 6 H2SO4 (aq) -> Fe2 (SO4) 3 (aq) + 6 H2O (l) + 3SO2 (g)Cu (s) + 4HNO3 (aq) -> Cu (NO3) 2 (aq) + 2H2O (l) + 2NO2 (g)Metathesis reactions (Exchange Pair)Metathesis reaction is the reaction of the ion pair exchange two electrolytes.AB + CD -> AC + BDIn this reaction is at least one reaction product will form a precipitate, a gas, or a weak electrolyte. Gas can be derived from the decomposition of hypothetical substances (acids and bases hypothetical break down into gas and water) that are not as stable as the following:H2CO3 -> CO2 (g) + H2O (l)H2SO3 -> SO2 (g) + H2O (l)NH4OH -> NH3 (g) + H2O (l)
As an example of metathesis reactions (exchange partner) are as follows:1. Reaction: Acid salt 1 + 1 -> 2 + Acid Salt 2AgNO3 (aq) + HBr (aq) -> AgBr (aq) + HNO3 (aq)ZnS (s) + 2HCl (aq) -> ZnCl2 (aq) + H2S (aq)
2. Reaction: Salt 1 + Bases 1 -> Salt 2 + 2 BasesCuSO4 (aq) + 2NaOH (aq) -> Na2SO4 (aq) + Cu (OH) 2 (aq)NH4Cl (aq) + KOH (aq) -> KCl (aq) + NH4OH (aq)
3. Reaction: Salt Salt 1 + 2 -> 3 + Garam Garam 4AgNO3 (aq) + NaCl (aq) -> AgCl (aq) + NaNO3 (aq)2KNO3 (aq) + MgCl2 (aq) -> 2KCl (aq) + Mg (NO3) 2 (aq)
Acid-base reaction (neutralization reaction).Acid-base reaction or neutralization reaction is the reaction between the acid (H +) and a base (OH-) produced a neutral H2O.Adapaun example neutralization reaction is as follows:
1. Reactions: Acid + base -> salt + waterHNO3 (aq) + KOH (aq) -> KNO3 (aq) + H2O (l)H2SO4 (aq) + Ca (OH) 2 (aq) -> CaSO4 (aq) + H2O (l)
2. Reaction: Oxide + Acid Tongue -> Salt + Water2HCl (aq) + CaO (s) -> CaCl2 (aq) + H2O (l)2HNO3 (aq) + Na2O (s) -> Na (NO3) 2 (aq) + H2O (l)
3. Reactions: Ammonia + Acid -> SaltHCl (aq) + NH3 (g) -> NH4Cl (aq)H2SO4 (aq) +2 NH3 (g) -> (NH4) 2SO4 (aq)Ammonia (NH3), including bases that form molecular compounds that are distinguished from the other two types of bases, ie, ionic compounds that can release OH-ions and okisda bases. There are other basic molecular compounds such as methylamine (CH3NH2) but the reaction is not common as ammonia.4. Reaction: Oxides of acid + base -> salt + waterSO3 (g) + 2NaOH (aq) -> Na2SO4 (aq) + H2O (l)CO2 (g) + Mg (OH) 2 (aq) -> MgCO3 (aq) + H2O (l)Reaction crowding-MetalCrowding-metal reaction is a reaction in which the metal pressing of other metal cations or hydrogen in a compound. This reaction can take place if the metals are on the left of the metal / H which urged the Volta series. In this reaction, the reaction product in the form of metal deposition, gas, and water.Volta Series is a sequence of elements whose reduction potential is based on the data. The following are some elements that can be memorized by a potential reduction sequence:Li - K - Ba - Ca - Na - Mg - Al - Mn - Zn - Fe - Ni - Sn - Pb - (H) - Cu - Hg - Ag - Pt - AuAs an example of crowding-metal reactions are as follows:1. Reactions: 1 + Metal Salt 1 -> 2 + Metal Salt 2Zn (s) + CuSO4 (aq) -> ZnSO4 (aq) + Cu (s)2AL (s) + 3FeSO4 (aq) -> Al2 (SO4) 3 (aq) + 3Fe (s)Cu (s) + Na2SO4 (aq) -> no reaction because Cu is on the right row voltaic2. Reaction: Metal + Acid -> Salt + Hydrogen GasMg (s) + HCl (aq) -> MgCl2 (aq) + H2 (g)Zn (s) + H2SO4 (aq) -> ZnSO4 (aq) + H2 (g)Ag (s) + HCl (aq) -> Ag does not react due to the right of the voltaic series3. Reaction: Metal + Acid -> Salt + Water + Gas2Fe (s) + 6 H2SO4 (aq) -> Fe2 (SO4) 3 (aq) + 6 H2O (l) + 3SO2 (g)Cu (s) + 4HNO3 (aq) -> Cu (NO3) 2 (aq) + 2H2O (l) + 2NO2 (g)Metathesis reactions (Exchange Pair)Metathesis reaction is the reaction of the ion pair exchange two electrolytes.AB + CD -> AC + BDIn this reaction is at least one reaction product will form a precipitate, a gas, or a weak electrolyte. Gas can be derived from the decomposition of hypothetical substances (acids and bases hypothetical break down into gas and water) that are not as stable as the following:H2CO3 -> CO2 (g) + H2O (l)H2SO3 -> SO2 (g) + H2O (l)NH4OH -> NH3 (g) + H2O (l)
As an example of metathesis reactions (exchange partner) are as follows:1. Reaction: Acid salt 1 + 1 -> 2 + Acid Salt 2AgNO3 (aq) + HBr (aq) -> AgBr (aq) + HNO3 (aq)ZnS (s) + 2HCl (aq) -> ZnCl2 (aq) + H2S (aq)
2. Reaction: Salt 1 + Bases 1 -> Salt 2 + 2 BasesCuSO4 (aq) + 2NaOH (aq) -> Na2SO4 (aq) + Cu (OH) 2 (aq)NH4Cl (aq) + KOH (aq) -> KCl (aq) + NH4OH (aq)
3. Reaction: Salt Salt 1 + 2 -> 3 + Garam Garam 4AgNO3 (aq) + NaCl (aq) -> AgCl (aq) + NaNO3 (aq)2KNO3 (aq) + MgCl2 (aq) -> 2KCl (aq) + Mg (NO3) 2 (aq)
Senin, 15 Oktober 2012
Stoichiometric
Stoichiometric
is the study of quantitative relationships of substances in a reaction
stoichiometric kimia.Dari literature means measuring elements. This
term is generally used more widely, which includes an assortment
pengukurab broader and includes calculations of chemical substances and
mixtures.Directors
stoichiometric reaction is perfect, can be calculated and measured, and
does not leave the rest of the reaction (reaction low), when reacted
not produce residual mole. Examples of stoichiometric reaction mixture systems NaOH - HCl is 4 ml NaOH and 4 ml HCl, 5 ml and 2.5 ml H2SO4 NaOH.Non-stoichiometric
reactions are corrections that leave the rest of the overall reaction
or no reaction react exhausted (no limiting reagent).The
maximum point is a stoichiometric point shows the highest number of a
graph between the measured properties of the quantity pereaksinya.Contoh
of the maximum point on the stoichiometric system experiment was
conducted 3 times with different volumes are 2ml H2SO4, 4 ml, 6ml and HCl
as 6ml, 4ml, 2ml from the mixing of the two compounds produced the same
temperature of the mixture that is 32 so it can not be determined
maximum temperature and minimum temperature.Point or minimum point is the lowest temperature in a reaction and a point that shows the number pereaksinya quantity.Limiting
reagent is the reaction of (a substance) are depleted react after
experiencing a reaction process because it limits the possibility of
continued reaction. Limiting
reagent is determined by comparing the number of moles of each reagent
according to the coefficient of the reaction and then select the value
of the reagent for the number of moles of reactants and reagents
terkecil.Contoh coefficient of limiting reactant in the stoichiometric
system NaOH - HCl is 2 ml NaOH + 6 ml of HCl that a reagent limiting
NaOH, 6 ml 2 ml HCl + NaOH the limiting reagent HCl, 2 ml NaOH + 6 ml
H2SO4 is the limiting reagent 2NaOH, 6 ml NaOH + 2 ml H2SO4 is the
limiting reagent H2SO4.At the stoichiometric NaOH and HCl systems, some use stoichiometric reactions and non-stoichiometric reactions. The reaction is stoichiometric reaction experiments showed 4 ml 1 M NaOH and 4 mL of 1 M HCl for pereaksinya no trace. While
the reaction that shows the reaction is non-stoichiometric experiments 2
ml 1 M NaOH and 6 ml of HCl 1 M, 6 mL of NaOH and 2 ml of HCl, because
pereaksinya still leave the rest.Stoichiometric chemical calculations it!
Is essentially the concept of the mole and its relationship with:
mass = moles x atomic mass or relative molecular
volume (STP) = moles x 22.4 liters / mol
pressure = (moles x 0082 L.atm / mol.K x temperature) / volume
number of particles = mol x 6:02 x 10 ^ 23
concentration = moles / volume of solution
etc..
Stochiometric is fundamental in the study of chemistry, particularly concerning the quantity of the substance involved both before and after reaksi.Stokiometri is a comparison of the relative reaction to the formation of compounds or substances and elements. The fundamental concept is the concept of stoichiometric mole. From the concept of the mole, Stokiomeri can be used for molecular weight measurement, weight and weight of equivalent elements. Of moles can be known how many atoms or molecules are present in a solution or some volume of a gas at a certain temperature. From the concept of the mole can also be written chemical equation that occurs between two objects element or compound.A chemical equation is clearly summarize the information about the substances involved in the corrections. This equation is not simply a qualitative statement describing how much of the reactants and reaction products involved.There is one very easy way to learn some stoichiometric reactions, namely the continuous method. By varying the molar quantities, pereaksinya be changed while kuantias molar fixed, then observed his physical one. One of the particular physical properties dipikih to be examined, such as Mass, time, volume, temperature, or absorption. Therefore kuntitas pereaksinya different, then the price perubaha physical properties of this system can be used to menghitun stoichiometric system.The experiment itself is done in order to understand the concept of stoichiometric practitioner in that practitioner langsung.Selain can also determine the reaction is stoichiometric or non stokioketri and can also determine the maximum and minimum points on a stoichiometric system.
Stoichiometric or count the ways chemistry is calculation oriented fundamental laws of chemistry. Be aware with the size of the material being studied in chemistry is so very small, so there is a special unit for the amount or concentration of a substance. Besides, an element has a period of relative atomic (Ar) nor typical relative molecular mass (Mr) of a compound and all of this related to the concept of the mole.
Is essentially the concept of the mole and its relationship with:
mass = moles x atomic mass or relative molecular
volume (STP) = moles x 22.4 liters / mol
pressure = (moles x 0082 L.atm / mol.K x temperature) / volume
number of particles = mol x 6:02 x 10 ^ 23
concentration = moles / volume of solution
etc..
Stochiometric is fundamental in the study of chemistry, particularly concerning the quantity of the substance involved both before and after reaksi.Stokiometri is a comparison of the relative reaction to the formation of compounds or substances and elements. The fundamental concept is the concept of stoichiometric mole. From the concept of the mole, Stokiomeri can be used for molecular weight measurement, weight and weight of equivalent elements. Of moles can be known how many atoms or molecules are present in a solution or some volume of a gas at a certain temperature. From the concept of the mole can also be written chemical equation that occurs between two objects element or compound.A chemical equation is clearly summarize the information about the substances involved in the corrections. This equation is not simply a qualitative statement describing how much of the reactants and reaction products involved.There is one very easy way to learn some stoichiometric reactions, namely the continuous method. By varying the molar quantities, pereaksinya be changed while kuantias molar fixed, then observed his physical one. One of the particular physical properties dipikih to be examined, such as Mass, time, volume, temperature, or absorption. Therefore kuntitas pereaksinya different, then the price perubaha physical properties of this system can be used to menghitun stoichiometric system.The experiment itself is done in order to understand the concept of stoichiometric practitioner in that practitioner langsung.Selain can also determine the reaction is stoichiometric or non stokioketri and can also determine the maximum and minimum points on a stoichiometric system.
Stoichiometric or count the ways chemistry is calculation oriented fundamental laws of chemistry. Be aware with the size of the material being studied in chemistry is so very small, so there is a special unit for the amount or concentration of a substance. Besides, an element has a period of relative atomic (Ar) nor typical relative molecular mass (Mr) of a compound and all of this related to the concept of the mole.
| Examples of questions:1. What percentage of the levels of calcium (Ca) in calcium carbonate? (Ar: C = 12; O = 16; Ca = 40)Answer:1 mol CaCO, containing 1 mol Ca + 1 + 3 mol C mol OMr CaCO3 = 40 + 12 + 48 = 100So the level of calcium in CaCO3 = 40/100 x 100% = 40% 2. A total of 5.4 grams of aluminum metal (Ar = 27) was treated with excess dilute hydrochloric acid according to the reaction:2 Al (s) + 6 HCl (aq) 2 AlCl3 (aq) + 3 H2 (g)How many grams of aluminum chloride and how many liters of hydrogen gas produced at standard conditions? Answer:Of the equation can be expressed2 mol Al x 2 mol AlCl3 3 mol H25.4 grams of Al = 05/04/27 = 0.2 molSo:AlCl3 formed = 0.2 x Mr AlCl3 = 0.2 x 133.5 = 26.7 gramsThe volume of H2 gas produced (0o C, 1 atm) = 3/2 x 0.2 x 4.22 = 6.72 liters 3. An iron ore contains 80% Fe2O3 (Ar: Fe = 56, O = 16). Oxide is reduced with CO gas to produce iron.How many tons of iron ore required to make 224 tons of iron?Answer:1 mol Fe2O3 contains 2 mol Fethen: mass Fe2O3 = (Mr Fe2O3 / 2 Ar Fe) Fe = mass x (160/112) x 224 = 320 tonsSo the iron ore required = (100/80) x 320 tons = 400 tons 4. To determine the crystal water 24.95 grams of copper sulfate salt crystal is heated until all the water evaporates. After heating the salt mass to be 15.95 grams. How much water is contained in the crystal salt?Answer:suppose formula is CuSO4 salt. xH2OCuSO4. xH2O CuSO4 + xH2O24.95 grams of CuSO4. xH2O + 18x = 159.5 moles15.95 grams CuSO4 = 159.5 mol = 0.1 molaccording to the above equation can be stated that:number of moles of CuS04. CuSO4 xH2O = mol; thus equation24.95 / (159.5 + 18x) = 0.1 x = 5So the formula is CuS04 salt. 5H2O Empirical Formula and Molecular Formula The empirical formula is the simplest formula of a compound.This formula simply states ratio of the number of atoms contained in the molecule.The empirical formula of a compound can be determined if known one:- Ar mass and each element-% Ar mass and each element- Ar mass ratio and each element Molecular formula: if the empirical formula is known and it is also known to Mr formulas can be determined.Example: A compound C den H contains 6 grams of C and 1 gram H.Determine the empirical formula and the molecular formula of the compound where it is known Mr = 28!Answer: moles C: moles H = 6/12: 1/1 = 1/2: 1 = 1: 2So the empirical formula: (CH2) nWhen Mr compound = 28 then: 12n + 2n = 28 14N = 28 n = 2So the molecular formula: (CH 2) 2 = C2H4Example: For a 20 ml oxidize hydrocarbons (CxHy) required oxygen in a gaseous state as much as 100 ml and 60 ml of CO2 produced. Determine the molecular formula of the hydrocarbon?Answer: hydrocarbon combustion equation in generalCxHy (g) + (x + 1/4 y) O2 (g) x CO2 (g) + 1/2 y H2O (l)The coefficient indicates the reaction mole ratio of the substances involved in the reaction.According to Gay Lussac gases on p, t the same time, the number of moles is proportional to the volumeThen:CxHy mol: mol O2: mol CO2 = 1: (x + 1/4y): x20: 100: 60 = 1: (x + 1/4y): x1: 5: 3 = 1: (x + 1/4y): xor:1: 3 = 1: x x = 31: 5 = 1: (x + 1/4y) y = 8So hydrocarbon formula is: C3H8 | |||
Senin, 08 Oktober 2012
CHEMICAL REACTION
Chemical Reactions
H2O
H2O
2H2O
CO2 + H2O
CO2 + 2H2O
CO2 + 2H2O1) Na + Cl2
NaCl
2) N2 + H2
NH3
3) Fe + O2
Fe2O3
4) Cu + AgNO3
Ag
+ Cu(NO3)2
(a Cu atom bonded to 2 NO3 groups)
5) H2SO4 + NaCN
HCN+ Na2SO4
But even a dozen molecules is a tiny amount. What we need is a big
number - a huge number! That number is the mole. The
mole is the scientific community's baker's dozen. One mole equals
6.02 x 1023 (also known as Avogadro's number). A 6 followed
by 23 zeros. Now that's a pretty big number. But that's all
it is, a number. You can't just have a mole, you have to have a mole
of something. A mole of atoms. A mole of water molecules.
A mole of pennies (which would make you richer than you can imagine).
Why the mole? As it turns out, the mole has some interesting properties.
One mole of hydrogen atoms (6.02 x 1023 H atoms) weighs 1 g.
From the periodic table we know that an
He atoms weighs 4 times as much as an H atom, so go figure, 1 mole of He
atoms weighs 4 g. In fact, one mole of any element is equal to the
atomic mass of that element (in grams).
Let's think about that for a second. If we know the molar mass of an element, and we know how many elements make up a specific molecule, then you can calculate the molar mass of a compound by adding up the atomic weights. Huh? Take water for example. How much does a mole of water weigh? Well, one mole of water contains one mole of oxygen atoms and two moles of hydrogen atoms. A mole of hydrogen weighs 1 g and a mole of oxygen weighs 16 g (look at the atomic mass in the periodic table). So to calculate the weight of one mole of water:
The mole is also useful in chemical reactions. Though you can't measure out an atom of hydrogen, you can measure out a mole. Since the mole is just a constant number, the coefficients in a balanced chemical reaction give you the molar proportions of reactants and products. In other words:
2H2O
There are many different types of
chemical reactions. Chemists have
classified the many different reactions into general categories. The chemical reactions we will explore are a
representation of the types of reactions found in each group. There is a general description of the main
reaction types and specific examples provided in the selection boxes.
Synthesis Reaction (Combination Reaction)
In a synthesis
reaction, two or more substances combine to form a new compound. This type of
reaction is represented by the following equation.
A + B AB
A and B
represent the reacting elements or compounds while AB represents a compound as
the product.
The following examples are representative of synthesis
reactions.
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Formation of Aluminum Bromide:
When Al is
placed on the surface of liquid Br2 an exothermic reaction occurs.
The Al is oxidized to Al3+ by the Br2, which is reduced to Br - ions. The ionic product, AlBr3, can be observed on the watch
glass after the reaction.
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Formation of Sodium Chloride: Molten sodium burns when it is
put into a container of chlorine gas. In the reaction a sodium ion loses an
electron to form a sodium cation and a chlorine atom simultaneously gains an
electron to form a chloride anion. The product of the reaction is the ionic
compound sodium chloride, which is the white solid observed.
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Formation of Zinc Oxide: Oxidation is a loss of electrons
and reduction is a gain of electrons. The oxidation of metallic Zn by O2 to form ZnO(s) is illustrated at the molecular
level. The transfer of electrons from Zn to O2 is shown. Atoms can be observed
to change as they are oxidized or reduced, respectively to their ionic forms.
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Formation of Sodium Hydroxide and Potassium
Hydroxide: When a small piece of Na is added
to a solution containing an indicator, evidence of the reaction can be
observed by the change in the color of the solution as NaOH is formed, by the
melting of the Na and by the movement of the Na caused by formation of hydrogen
gas. K is more reactive than Na as demonstrated by its reaction with water.
This reaction produces enough heat to ignite the H2 produced.
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Single-Replacement Reaction
In a single-replacement
reaction (displacement reaction) one element replaces a similar element
in the compound. Single-replacement
reactions can be represented by the following equations.
AB + C AC + B|
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Thermite Reaction: In the thermite reaction, Al
reduces Fe2O3 to Fe in an extremely exothermic reaction in which Al is oxidized to
Al2O3. The reaction produces enough heat to melt the iron. Because of the
extreme heat produced in the thermite reaction, it is used industrially to
weld iron.
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Reduction of CuO: When black carbon
and black copper oxide are heated together the Cu2+
ions are reduced to metallic Cu and a gas is evolved. When the gas is collected in Ca(OH)2 a white precipitate of CaCO3 is formed. The reaction which
occurs involves the reduction of Cu2+ ions by carbon which is oxidized
to CO2.
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Formation of Silver Crystals:
When a
copper wire is placed in a solution of AgNO3, the Cu reduces Ag+ to metallic Ag. At the same time,
Cu is oxidized to Cu2+. As the reaction progresses Ag crystals can be seen to
form on the Cu wire and the solution becomes blue as a result of the
formation of Cu2+ ions.
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Formation of Tin Crystals:
Oxidation-reduction
chemistry of Sn and Zn. When acidified Sn(II)Cl2 is added to a beaker containing a
piece of Zn, some of the Sn2+ reacts with H+ in the solution to produce H2 gas. Immediate changes can also
be observed on the surface of the Zn as it quickly becomes coated with Sn
crystals. After the reaction has progressed for a time needles of Sn can be
observed on the surface of the Zn.
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Double-Replacement
Reaction
In a
double-replacement reaction, the ions of two compounds exchange places in an
aqueous solution
to form two new compounds.
A double-replacement reaction can be represented by the following
equation.
AB + CD AC + BD|
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This marble statue has been eroded by acid rain. Marble is a
material having CaCO3 as its primary component. Acids react
with and dissolve the marble. The
acid comes from sulfur dioxide in the atmosphere combining with water to form
sulfurous acid.
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An aqueous solution of Potassium Iodide is added to an aqueous
solution of Lead (II) Nitrate forming lead (II) iodide. The formation of a precipitate occurs when
the cations of one reactant combines with the anions of the other reactant to
form an insoluble or slightly insoluble compound.
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An aqueous solution of Sodium Chloride is added to an aqueous
solution of Silver Nitrate forming silver chloride.
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Decomposition
Reaction
In a decomposition reaction, single compound undergoes a
reaction that produces two or more simpler
substances. A decomposition
reaction can be represented by the following equation.
AB A + B|
Electrolysis of Water: When a
direct current is passed through water it decomposes to form oxygen and
hydrogen. The volume of hydrogen gas produced at the negative electrode is
twice the volume of the oxygen gas formed at the positive electrode. This
indicates that water contains twice as many hydrogen atoms as oxygen atoms,
which is an illustration of the law of constant composition.
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Decomposition of
Nitrogen Triiodide: Nitrogen triiodide is
extremely unstable when it is dry. Touching it with a feather causes it to
decompose explosively. The explosion occurs as chemical energy is released by
the decomposition of nitrogen triiodide to N2 and I2.
Violet iodine vapor can be observed after the explosion.
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Combustion
Reaction
In a
combustion reaction, a substance combines with oxygen, releasing a large amount
of energy in the form
of light and heat.
For organic compounds, such as hydrocarbons, the products of the
combustion reaction are carbon dioxide and water.
CH4 + 2
O2 CO2 + 2
H2O|
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The
combustion of hydrogen yields water vapor as a reaction product. Three balloons of hydrogen and one balloon
mixed with hydrogen and oxygen form an explosive mixture
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Reactions
with Oxygen. Magnesium, steel wool, white phosphorous, and sulfur are burned
in oxygen. The resulting reactions are combination reactions in which two
substances react to form one product. The products formed in these reactions
are MgO, Fe2O3, P4O10 and SO2.
All of these combustion reactions are very exothermic.
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The
combustion of yellow phosphorus occurs in an oxygen atmosphere. The
main product of this reaction is phosphorus pentoxide.
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