Λεπτομέρειες για το προϊόν
Τόπος καταγωγής: Ezhou, Κίνα
Μάρκα: DESHENG
Πιστοποίηση: ISO9001:2008
Όροι πληρωμής και αποστολής
Ποσότητα παραγγελίας min: 10 γρ
Τιμή: διαπραγματεύσιμα
Συσκευασία λεπτομέρειες: Πλαστικό μπουκάλι ή φιλμ αλουμινίου
Χρόνος παράδοσης: 1 ~ 3 ημέρες μετά τη λήψη πληρωμής
Όροι πληρωμής: Τ/Τ, L/C, D/A, D/P, Western Union, MoneyGram, paypal
Δυνατότητα προσφοράς: 100kg/μήνα
Εμφάνιση: |
Λευκή Κρυσταλλική Σκόνη |
Καθαρότητα: |
>99.0% |
MW: |
221.32 |
Τύπος: |
C9H19NO3S |
CAS: |
1135-40-6 |
Ονομα: |
Καπέλα |
Εμφάνιση: |
Λευκή Κρυσταλλική Σκόνη |
Καθαρότητα: |
>99.0% |
MW: |
221.32 |
Τύπος: |
C9H19NO3S |
CAS: |
1135-40-6 |
Ονομα: |
Καπέλα |
In the use of biological buffer CAPS, temperature compensation is a commonly mentioned but easily misunderstood concept. Many operators simply understand it as the automatic temperature compensation function on the pH meter, believing that as long as this function is turned on, the pH values measured at different temperatures can be directly compared. In fact, the true meaning of temperature compensation goes far beyond this, involving changes in the chemical equilibrium of the buffer system itself, temperature response of the measuring electrode, and temperature management strategies for experimental design. Clarifying this concept is of great significance for the correct use of CAPS buffer.
|
Product Name |
3- (cyclohexylamine) -1-propanesulfonic acid |
Chemical Abbreviation |
CAPS buffer |
|
CAS Number |
1135-40-6 |
Product Appearance |
White crystalline powder |
|
Molecular Weight |
221.32 |
Molecular Formula |
C9H19NO3S |
|
Density |
1.19g/cm3 |
Melting Point |
324℃ |
|
Storage Conditions |
Room temperature, away from light and moisture |
Standard Packaging |
25KG/Cardboard bucket |
|
Water-soluble |
9 g/100 mL (20℃) |
Manufacturer |
Hubei New Desheng |
The essence of temperature compensation in pH measurement
The response of the pH electrode is based on the Nernst equation, and its slope varies with temperature. The automatic temperature compensation function corrects the slope of the electrode response, ensuring that the potential measured by the electrode at different temperatures can be correctly converted into pH readings. But it should be clarified that this compensation does not change the actual pH value of the sample itself. When the CAPS buffer is moved from room temperature to a low-temperature environment, its true hydrogen ion concentration has already changed, and the electrode only faithfully reports this change. Therefore, automatic temperature compensation solves the problem of measurement accuracy rather than sample pH stability. Confusing the two is the most common misconception in temperature compensation cognition.
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CAPS powder
Temperature response of CAPS buffer system itself
The acid-base dissociation constant of CAPS has a clear temperature dependence. When the temperature increases, the dissociation equilibrium shifts and the actual pH of the buffer solution changes accordingly. This change is a reflection of the inherent chemical properties of CAPS molecules and is a real change, without the concept of compensation. Understanding this is crucial as it means that any experimental design must clearly specify the operating temperature and perform pH adjustment and measurement at that temperature. Attempting to mask or eliminate this chemical change through instrument compensation is neither possible nor scientific. The correct approach is to accept and record the pH shift caused by temperature changes, and consider it in the experimental plan.
The true meaning of temperature consistency between calibration and measurement
The most direct application of temperature compensation at the operational level is to require calibration and measurement to be performed at the same temperature. If there is a temperature difference between the standard buffer used for calibration and the CAPS sample to be tested, even if the instrument is turned on for automatic compensation, it cannot eliminate the system bias introduced by the different dissociation behaviors of the standard solution and the sample. The solution is to place all liquids in the same constant temperature environment for sufficient equilibrium, and then perform calibration and measurement. For experiments that require the use of CAPS at different temperatures, it is recommended to calibrate and measure separately at the target temperature, rather than relying on the instrument to automatically convert to the target temperature after calibration at room temperature.
Temperature management strategy in workflow
Since the actual pH of CAPS varies with temperature, a reasonable temperature management strategy needs to be established during experimental design. For a constant temperature experimental platform, the problem is relatively simple, just complete calibration and adjustment at that temperature. For experiments that require variable temperature operation, such as low-temperature storage followed by temperature rise reaction, the pH value of CAPS at each key temperature point needs to be measured in advance as the basis for operation. Some experimental schemes choose to adjust the pH of CAPS at a higher temperature because the buffer capacity is more stable at this temperature. After cooling to the working temperature, it will be judged whether fine-tuning is needed based on pre experimental data. This strategy requires sufficient data support and is not a universal method.
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Product packaging
Summary
The true meaning of CAPS buffer temperature compensation is to distinguish between measurement calibration and chemical changes, and to clarify the boundary between instrument function and operation strategy. Correct temperature management is not about eliminating changes, but about understanding the patterns of change and incorporating them into experimental design. In practical work, maintaining consistency between calibration and temperature measurement, accepting and recording the true pH shift caused by temperature in CAPS, and establishing a temperature response database for specific processes are more practical measures than relying on instrument compensation.