合作客戶/
拜耳公司 |
同濟大學 |
聯合大學 |
美國保潔 |
美國強生 |
瑞士羅氏 |
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水和乙二醇-水混合體系中的離子液體-陽離子表面活性劑混合膠束自聚焦-電導法 表面張立法和光譜研究法—
來源:上海謂載 瀏覽 1039 次 發布時間:2021-12-16
4.結論
觀察到,十六烷基-3-甲基咪唑氯化銨(CET+[C10min][Cl])和純[C10min][Cl]的混合體系中,西三胺的cmc值介于純[C10min][Cl]和CET之間。在混合體系中,cmc值隨著[C10min][Cl]摩爾分數的增加而增加,證實其形成膠束的趨勢小于純表面活性劑分子。cmc值也隨著溶液中DEG體積百分比的增加而增加,這是由于隨著溶劑極性的降低,表面活性劑的疏溶劑性降低。cmc b cmc*、βb 0和(f1和f2)b 1的觀察值清楚地表明了混合物的非理想行為,并且還表明混合膠束中CET和[C10min][Cl]分子之間存在比純組分更強的相互作用。純組分和混合物的ΔGm值均為負值,表明膠束形成是熱力學自發的。ΔGad 0的負值大于ΔGm0的負值表明,在空氣-溶液界面的吸附比在本體溶液中形成膠束更有利。由表面張力法計算的Γmax和Amin值對于確定表面活性劑分子在氣液界面的排列非常有用。Γmax值為我們提供了關于液/氣界面吸附效率的信息,該值隨著溶液中DEG體積百分比的增加而降低。DEG實際上在界面上與混合表面活性劑系統競爭,因此減少了其數量,從而降低了吸附效率。此外,P的值為b0。33,表明形成的膠束/混合膠束本質上是球形的。從紫外-可見光譜可以得出結論,[C10min][Cl]與CET形成混合膠束,這從存在和不存在[C10min][Cl]時的cmc值可以清楚地看出。在cmc以下,大部分離子對形成,但一旦達到cmc,這些離子對就會轉變為[C10min][Cl]/CET混合膠束和可溶性染料分子。
致謝
U.Farooq感謝UGC以BSR(基礎科學研究)的形式提供獎學金,N.A.Malik感謝化學系主任、伊斯蘭教理工大學(IIST)、Awantipora、普拉瑪、J&K等提供必要的設施。
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