Axisymmetric Drop Shape Analysis−Constrained Sessile Drop (ADSA-CSD): A Film Balance Technique for High Collapse Pressures

详细信息    查看全文

• 作者：Sameh M. I. Saad ; Zdenka Policova ; Edgar J. Acosta ; A. Wilhelm Neumann
• 刊名：Langmuir
• 出版年：2008
• 出版时间：October 7, 2008
• 年：2008
• 卷：24
• 期：19
• 页码：10843-10850
• 全文大小：239K
• 年卷期：v.24,no.19(October 7, 2008)
• ISSN：1520-5827

文摘

Collapse pressure of insoluble monolayers is a property determined from surface pressure/area isotherms. Such isotherms are commonly measured by a Langmuir film balance or a drop shape technique using a pendant drop constellation (ADSA-PD). Here, a different embodiment of a drop shape analysis, called axisymmetric drop shape analysis−constrained sessile drop (ADSA-CSD) is used as a film balance. It is shown that ADSA-CSD has certain advantages over conventional methods. The ability to measure very low surface tension values (e.g., <2 mJ/m²), an easier deposition procedure than in a pendant drop setup, and leak-proof design make the constrained sessile drop constellation a better choice than the pendant drop constellation in many situations. Results of compression isotherms are obtained on three different monolayers: octadecanol, dipalmitoyl-phosphatidyl-choline (DPPC), and dipalmitoyl-phosphatidyl-glycerol (DPPG). The collapse pressures are found to be reproducible and in agreement with previous methods. For example, the collapse pressure of DPPC is found to be 70.2 mJ/m². Such values are not achievable with a pendant drop. The collapse pressure of octadecanol is found to be 61.3 mJ/m², while that of DPPG is 59.0 mJ/m². The physical reasons for these differences are discussed. The results also show a distinctive difference between the onset of collapse and the ultimate collapse pressure (ultimate strength) of these films. ADSA-CSD allows detailed study of this collapse region.