٠ا Ù٠اÙرÙ٠اÙÙÙدرÙجÙÙÙ – Ù ÙÙاس اÙأس اÙÙÙدرÙجÙÙÙ
تعتبر ØÙ Ùضة ÙÙÙÙÙØ© اÙÙ ØÙÙÙ Ù ÙÙ Ø© ÙÙغاÙØ© Ù٠٠عاÙجة اÙÙ Ùا٠باÙتÙØ§Ø¶Ø Ø§ÙعÙس٠بسبب عÙا٠٠٠ث٠تدÙÙر اÙغشاء Ø ÙتÙظÙ٠اÙأغشÙØ© Ø Ù٠ا Ø¥ÙÙ Ø°ÙÙ. ÙØ°ÙÙ Ùأ٠بعض اÙتÙاعÙات اÙÙÙÙ ÙائÙØ© ستØدث ÙÙØ· عÙد Ù ÙÙاس أس ÙÙدرÙجÙÙÙ Ù Øددة.
Ùستخد٠اÙ٠صطÙØ Ø§Ùأس اÙÙÙدرÙجÙÙÙ ÙÙص٠٠ا إذا Ùا٠اÙÙ ØÙÙÙ ÙÙÙ٠أ٠Øا٠ضÙ. Ø£Ùض٠Ùص٠ÙÙ ÙÙÙ٠اÙØÙ Ùضة ÙاÙÙÙÙÙØ© Ù٠اÙعÙدة Ø¥Ù٠ثابت اÙتÙÙÙ.
باÙÙظر Ø¥Ù٠اÙأس اÙÙÙدرÙجÙÙÙ ØÙ٠ترÙÙز اÙÙÙدرÙجÙÙ H + ion Ø Ùر٠أÙ٠٠ع ارتÙاع ترÙÙز H + (ÙÙÙ٠ترÙÙز OH) ÙØص٠عÙ٠رÙ٠سÙب٠أصغر. ÙباÙÙ Ø«Ù Ø Ù Ø¹ ارتÙاع ترÙÙز اÙÙÙدرÙÙسÙد (ÙÙÙ٠ترÙÙز H +) ÙØص٠عÙ٠رÙ٠سÙب٠أÙبر.
[H +] x [OH-] = 1.0 x 10 ^ -14
Ù
ع إضاÙØ© اÙØÙ
ض (H +)
1.0 x 10 ^ -5 x 1.0 x 10 ^ -9 = 1.0 x 10 ^ -14
Ù
ع إضاÙØ© اÙÙاعدة (OH-)
1.0 x 10 ^ -9 x 1.0 x 10 ^ -5 = 1.0 x 10 ^ -14
تغÙÙرات اÙأس اÙÙÙدرÙجÙÙ٠٠ع اÙتغÙرات ÙÙ H + ÙترÙÙزات OH
٠ع أخذ Ø°ÙÙ Ù٠اÙاعتبار Ø Ø¹Ù٠اÙعÙ٠اء أ٠طرÙÙØ© Ø£Ùثر Ù Ùاء٠ة ÙÙص٠ترÙÙز Ø£ÙÙ٠اÙÙÙدرÙجÙÙ Ù٠اÙÙ ØÙÙÙ Ù٠أخذ اÙÙÙغارÙت٠اÙساÙب ÙترÙÙز Ø£ÙÙÙات اÙÙÙدرÙجÙÙ. اÙÙÙغارÙØ«Ù Ù٠اÙأس اÙÙÙدرÙجÙÙ٠اÙØ°Ù Ùت٠رÙع رÙ٠أساس Ù ÙÙ ÙØ¥Ùتاج رÙ٠٠عÙÙ. Ù ÙاØظة: سÙستخد٠عادة Ùاعدة Ù Ù 10.
٠ثاÙ: اÙسج٠(اÙÙÙغارÙت٠) Ù Ù 100 ÙÙ 2: عشرة ٠رÙÙع Ø¥ÙÙ ÙÙØ© 2 (102).
٠ثاÙ: سج٠127 ÙÙ 2.1 (عÙ٠اÙØ¢ÙØ© اÙØاسبة اÙعÙÙ ÙØ© Ø Ø£Ø¯Ø®Ù 127 Ø Ø«Ù Ø§Ø¶ØºØ· اÙÙ ÙØªØ§Ø [LOG]).
رÙÙ | ÙÙغارÙت٠| رÙÙ | ÙÙغارÙت٠|
1 = 1 X 10^0 | 0 | 1.0 = 1 X 10^0 | 0 |
10 = 1 X 10^1 | 1 | 0.1 = 1 X 10^-1 | -1 |
100 = 1 X 10^2 | 2 | 0.01 = 1 X 10^-2 | -2 |
1000 = 1 X 10^3 | 3 | 0.001 = 1 X 10^-3 | -3 |
10000 = 1 X 10^4 | 4 | 0.0001 = 1 X 10^-4 | -4 |
100000 = 1 X 10^5 | 5 | 0.00001 = 1 X 10^-5 | -5 |
1000000 = 1 X 10^6 | 6 | 0.000001 = 1 X 10^-6 | -6 |
10000000 = 1 X 10^7 | 7 | 0.0000001 = 1 X 10^-7 | -7 |
ر٠ز اÙسج٠اÙساÙب ÙÙ “p”. ÙØ°ÙÙ Ø Ùإ٠اÙسج٠اÙسÙب٠ÙترÙÙز Ø£ÙÙ٠اÙÙÙدرÙجÙÙ ÙÙ “Ù ÙÙاس اÙأس اÙÙÙدرÙجÙÙÙ”. Ùسرد اÙجدÙ٠أدÙا٠اÙعدÙد ٠٠ترÙÙزات Ø£ÙÙÙات اÙÙÙدرÙجÙÙ ÙترÙÙزات ÙÙدرÙÙسÙد Ùدرجة اÙØÙ Ùضة اÙÙ ÙابÙØ© Ù pOH. ÙاØظ أ٠اÙرÙ٠اÙÙÙدرÙجÙÙÙ 7 Ù ØاÙدة Ùأ٠ترÙÙز Ø£ÙÙ٠اÙÙÙدرÙجÙÙ [H +] ÙترÙÙز اÙÙÙدرÙÙسÙد [OH-] Ù٠ا ÙÙس اÙØ´ÙØ¡. Ù٠ا ÙزÙد [H +] Ø ÙÙÙص اÙأس اÙÙÙدرÙجÙÙÙ.
H+ (mol/L) | OH- (mol/L) | ||||
عدد عشر٠| SN | pH | عدد عشر٠| SN | pOH |
0.00000000000001 | 1 X 10^-14 | 14 | 1.0 | 1 X 10^0 | 0 |
0.0000000000001 | 1 X 10^-13 | 13 | 0.1 | 1 X 10^-1 | 1 |
0.000000000001 | 1 X 10^-12 | 12 | 0.01 | 1 X 10^-2 | 2 |
0.00000000001 | 1 X 10^-11 | 11 | 0.001 | 1 X 10^-3 | 3 |
0.0000000001 | 1 X 10^-10 | 10 | 0.0001 | 1 X 10^-4 | 4 |
0.000000001 | 1 X 10^-9 | 9 | 0.00001 | 1 X 10^-5 | 5 |
0.00000001 | 1 X 10^-8 | 8 | 0.000001 | 1 X 10^-6 | 6 |
0.0000001 | 1 X 10^-7 | 7 | 0.0000001 | 1 X 10^-7 | 7 |
0.000001 | 1 X 10^-6 | 6 | 0.00000001 | 1 X 10^-8 | 8 |
0.00001 | 1 X 10^-5 | 5 | 0.000000001 | 1 X 10^-9 | 9 |
0.0001 | 1 X 10^-4 | 4 | 0.0000000001 | 1 X 10^-10 | 10 |
0.001 | 1 X 10^-3 | 3 | 0.00000000001 | 1 X 10^-11 | 11 |
0.01 | 1 X 10^-2 | 2 | 0.000000000001 | 1 X 10^-12 | 12 |
0.1 | 1 X 10^-1 | 1 | 0.0000000000001 | 1 X 10^-13 | 13 |
1.0 | 1 X 10^-0 | 0 | 0.00000000000001 | 1 X 10^-14 | 14 |
- Published in Water Chemistry, Water Treatment
What is pH – pH Scale Definition
pH refers to the concentration of hydrogen ions in solution. The lower the pH the more hydrogen
ions present. The higher the pH the fewer hydrogen ions present
The acidity and alkalinity of a solution is extremely important in Reverse Osmosis water treatment due to factors such as membrane degradation, membrane cleaning, etc. This is because certain chemical reactions will only take place at specific pH values.
The term pH is used to describe whether a solution is alkaline or acidic. The concept of acidity and alkalinity may best be described by going back to the dissociation constant.
Looking at the exponent on the concentration of Hydrogen H+ ion, we see that as the H+ concentration goes up (and OH- concentration goes down) we get a smaller negative number. Likewise, as Hydroxide OH- concentration goes up (and H+ concentration goes down) we get a larger negative number.
[H+] x [OH-] = 1.0 x 10^-14
With addition of acid (H+)
1.0 x 10^-5 x 1.0 x 10^-9 = 1.0 x 10^-14
With addition of base (OH-)
1.0 x 10^-9 x 1.0 x 10^-5 = 1.0 x 10^-14
Exponent changes with changes in H+ and OH- concentrations
Taking this into consideration, scientists learned that a more convenient way to describe the hydrogen ion concentration of a solution is to take the negative logarithm of the hydrogen ion concentration. A logarithm is the exponent to which a base number is raised to produce a given number. NOTE: We will usually use a base of 10.
EXAMPLE: The log (logarithm) of 100 is 2: Ten raised to the power of 2 (102).
EXAMPLE: The log of 127 is 2.1 (On a scientific calculator, enter 127, then push the [LOG] key).
NUMBER | LOG | NUMBER | LOG |
1 = 1 X 10^0 | 0 | 1.0 = 1 X 10^0 | 0 |
10 = 1 X 10^1 | 1 | 0.1 = 1 X 10^-1 | -1 |
100 = 1 X 10^2 | 2 | 0.01 = 1 X 10^-2 | -2 |
1000 = 1 X 10^3 | 3 | 0.001 = 1 X 10^-3 | -3 |
10000 = 1 X 10^4 | 4 | 0.0001 = 1 X 10^-4 | -4 |
100000 = 1 X 10^5 | 5 | 0.00001 = 1 X 10^-5 | -5 |
1000000 = 1 X 10^6 | 6 | 0.000001 = 1 X 10^-6 | -6 |
10000000 = 1 X 10^7 | 7 | 0.0000001 = 1 X 10^-7 | -7 |
The symbol for the negative log is “p”. Therefore, the negative log of the Hydrogen ion concentration is “pH”. Table below lists several hydrogen ion concentrations, hydroxide concentrations, and the corresponding pH and pOH. Note that a pH of 7 is neutral because the Hydrogen ion concentration [H+] and hydroxide concentration [OH-] are the same. As [H+] increases, pH decreases.
H+ (mol/L) | OH- (mol/L) | ||||
Decimal | SN | pH | Decimal | SN | pOH |
0.00000000000001 | 1 X 10^-14 | 14 | 1.0 | 1 X 10^0 | 0 |
0.0000000000001 | 1 X 10^-13 | 13 | 0.1 | 1 X 10^-1 | 1 |
0.000000000001 | 1 X 10^-12 | 12 | 0.01 | 1 X 10^-2 | 2 |
0.00000000001 | 1 X 10^-11 | 11 | 0.001 | 1 X 10^-3 | 3 |
0.0000000001 | 1 X 10^-10 | 10 | 0.0001 | 1 X 10^-4 | 4 |
0.000000001 | 1 X 10^-9 | 9 | 0.00001 | 1 X 10^-5 | 5 |
0.00000001 | 1 X 10^-8 | 8 | 0.000001 | 1 X 10^-6 | 6 |
0.0000001 | 1 X 10^-7 | 7 | 0.0000001 | 1 X 10^-7 | 7 |
0.000001 | 1 X 10^-6 | 6 | 0.00000001 | 1 X 10^-8 | 8 |
0.00001 | 1 X 10^-5 | 5 | 0.000000001 | 1 X 10^-9 | 9 |
0.0001 | 1 X 10^-4 | 4 | 0.0000000001 | 1 X 10^-10 | 10 |
0.001 | 1 X 10^-3 | 3 | 0.00000000001 | 1 X 10^-11 | 11 |
0.01 | 1 X 10^-2 | 2 | 0.000000000001 | 1 X 10^-12 | 12 |
0.1 | 1 X 10^-1 | 1 | 0.0000000000001 | 1 X 10^-13 | 13 |
1.0 | 1 X 10^-0 | 0 | 0.00000000000001 | 1 X 10^-14 | 14 |
- Published in Water Chemistry, Water Treatment
What is Dissociation Constant Definition
Dissociation Constant demonstrates the maximum range to which an element or substance would dissociate into ions. The Dissociation Constant referred to as “K” is equal to the product of the concentrations of the corresponding ions:
K = [H+] x [OH-]
The dissociation constant for a compound such as sodium chloride is very large since the ions are almost totally dissociated (exist as separate cations and anions). Dissociation constants for compounds which do not readily dissociate (separate) are small.
Highly Soluble Salts <——-> Large Dissociation Constant
Slightly Soluble Salts <——> Small Dissociation Constant
Most ionic compounds will dissociate to some extent. Even water will slightly dissociate as described by the equation below.
H2O —-> (H+) + (OH-)
The dissociation constant for water is found by multiplying the concentrations of the hydrogen ion (H+) and the hydroxide ion (OH-). The brackets in the equation indicate that we are dealing with concentrations expressed in molarity. Scientists found that the product of concentration of the two ions is 1.0 x 10-14 at standard conditions.
K = [H+] x [OH-] = 1.0 x 10^-14
If we are dealing with pure water, we know that the concentration of H+ and OH- must be the same since one of each is required to make a water molecule.
[H+] = [OH-]
Since,
(H+) + (OH-) —–> H2O
Therefore, if the concentrations of the ions multiplied together are equal to 1.0 x 10^-14 and the concentrations of each ion are the same, we know that the concentration of each ion is 1.0 x 10^-7. Remember, when we multiply numbers with exponents, we add the exponents together.
[H+] x [OH-] = 1.0 x 10^-14
1.0 x 10^? x 1.0 x 10^? = 1.0 x 10^-14
[H+] and [OH-] are equal:
[H+] = [OH-] = 1.0 x 10^-14
1.0 x 10^-7 [H+] x 1.0 x 10^-7 [OH-] = 1.0 x 10^-14
If we add some hydrochloric acid (HCl) to the pure water, the concentration of hydrogen ions will increase since HCl is almost completely dissociated.
HCl + H2O —–> H+* + Cl- + H2O
*Concentration of H+ is increased by the addition of HCl
As the concentration of hydrogen ions increases, the concentration of hydroxide ions decreases. This is because the dissociation constant (product of the H+ concentration multiplied by the OH- concentration) for water does not change. It is a basic chemical characteristic just like density, boiling point, freezing point, etc.
[H+] x [OH-] = 1.0 x 10^-14
As the concentration of H+ goes up, the negative exponent on the concentration value goes down. In our example below, it goes from -7 to -5. The hydroxide exponent therefore must go from -7 to -9. Remember, the dissociation constant does not change. The product of the two concentrations (sum of the exponents) must always equal -14.
Example:
Pure Water
1.0 x 10^-7 x 1.0 x 10^-7 = 1.0 x 10^-14
With the addition of acid
1.0 x 10^-5* x 1.0 x 10^-9 = 1.0 x 10^-14**
*This number is larger due to the addition of acid.
**This number must remain the same.
In the same manner, if we add sodium hydroxide (NaOH) to pure water, the OH- concentration will increase. If the OH- concentration increases, the H+ concentration must decrease.
Now we can see that with water we can have one of three conditions. First, we can have a condition in which there are an equal number of H+ and OH- ions. Water in this state is said to be neutral. Second, we can have a condition in which we have more H+ than OH- ions. This condition is called acidic. Third, we can have a condition in which there are more OH- than H+ ions. This condition is called basic or alkaline.
[H+] > [OH-] —–> Acidic
[H+] = [OH-] —–> Neutral
[H+] < [OH-] —–> Alkaline
- Published in Water Chemistry, Water Treatment