共聚合方程 (英語:copolymerization equation 共聚物组成方程 ,在英文文献中也被称作Mayo–Lewis equation ),该方程表示了共聚合反应 中某时刻单体的反应速率比或共聚物组成与对应时刻的单体组成之间的关系[ 1] 弗兰克·R·马约 和弗里德里克·M·路易斯 研究苯乙烯 与甲基丙烯酸甲酯 的共聚反应时提出[ 2]
该方程考虑两种单体
M
1
{\displaystyle M_{1}\,}
M
2
{\displaystyle M_{2}\,}
M
1
∗
{\displaystyle M_{1}^{*}\,}
M
2
∗
{\displaystyle M_{2}^{*}\,}
M
1
{\displaystyle M_{1}\,}
M
2
{\displaystyle M_{2}\,}
反应速率常数
k
{\displaystyle k\,}
M
1
∗
+
M
1
→
k
11
M
1
M
1
∗
{\displaystyle M_{1}^{*}+M_{1}{\xrightarrow {k_{11}}}M_{1}M_{1}^{*}\,}
M
1
∗
+
M
2
→
k
12
M
1
M
2
∗
{\displaystyle M_{1}^{*}+M_{2}{\xrightarrow {k_{12}}}M_{1}M_{2}^{*}\,}
M
2
∗
+
M
2
→
k
22
M
2
M
2
∗
{\displaystyle M_{2}^{*}+M_{2}{\xrightarrow {k_{22}}}M_{2}M_{2}^{*}\,}
M
2
∗
+
M
1
→
k
21
M
2
M
1
∗
{\displaystyle M_{2}^{*}+M_{1}{\xrightarrow {k_{21}}}M_{2}M_{1}^{*}\,}
定义链增长阶段的竞聚率 为端基为某单体的链继续与相同单体反应的速率常数和该链与另一种单体反应的速率常数的比值。[ 3]
r
1
=
k
11
k
12
{\displaystyle r_{1}={\frac {k_{11}}{k_{12}}}\,}
r
2
=
k
22
k
21
{\displaystyle r_{2}={\frac {k_{22}}{k_{21}}}\,}
可推导出共聚方程为[ 4] [ 5] [ 3]
d
[
M
1
]
d
[
M
2
]
=
[
M
1
]
(
r
1
[
M
1
]
+
[
M
2
]
)
[
M
2
]
(
[
M
1
]
+
r
2
[
M
2
]
)
{\displaystyle {\frac {d\left[M_{1}\right]}{d\left[M_{2}\right]}}={\frac {\left[M_{1}\right]\left(r_{1}\left[M_{1}\right]+\left[M_{2}\right]\right)}{\left[M_{2}\right]\left(\left[M_{1}\right]+r_{2}\left[M_{2}\right]\right)}}}
此处用中括号表示某物质的浓度,这一方程给出了两种单体在某时刻反应速率的比和混合物中单体浓度的关系。[ 5]
为了更好得表达共聚物组成和单体组成的关系,可以将上述方程改写成摩尔分数的形式。定义单体
M
1
{\displaystyle M_{1}\,}
M
2
{\displaystyle M_{2}\,}
f
1
{\displaystyle f_{1}\,}
f
2
{\displaystyle f_{2}\,}
f
1
=
1
−
f
2
=
M
1
(
M
1
+
M
2
)
{\displaystyle f_{1}=1-f_{2}={\frac {M_{1}}{(M_{1}+M_{2})}}\,}
定义两种单体在共聚物中所占的摩尔分数为
F
1
{\displaystyle F_{1}\,}
F
2
{\displaystyle F_{2}\,}
F
1
=
1
−
F
2
=
d
M
1
d
(
M
1
+
M
2
)
{\displaystyle F_{1}=1-F_{2}={\frac {dM_{1}}{d(M_{1}+M_{2})}}\,}
将该定义与上节所列方程联用,可以得到:[ 6] [ 5]
F
1
=
1
−
F
2
=
r
1
f
1
2
+
f
1
f
2
r
1
f
1
2
+
2
f
1
f
2
+
r
2
f
2
2
{\displaystyle F_{1}=1-F_{2}={\frac {r_{1}f_{1}^{2}+f_{1}f_{2}}{r_{1}f_{1}^{2}+2f_{1}f_{2}+r_{2}f_{2}^{2}}}\,}
^ 共聚合方程 . 术语在线. ^ Copolymerization. I. A Basis for Comparing the Behavior of Monomers in Copolymerization; The Copolymerization of Styrene and Methyl Methacrylate Frank R. Mayo and Frederick M. Lewis J. Am. Chem. Soc. ; 1944 ; 66(9) pp 1594 - 1601; doi :10.1021/ja01237a052 ^ 3.0 3.1 Cowie, J.M.G. Polymers: Chemistry & Physics of Modern Materials (2nd ed., Chapman & Hall 1991) p.106 ISBN 0-412-03121-3
^ Fried, Joel R. Polymer Science & Technology (2nd ed., Prentice-Hall 2003) p.42 ISBN 0-13-018168-4
^ 5.0 5.1 5.2 Rudin, Alfred The Elements of Polymer Science and Engineering (Academic Press 1982) p.265 ISBN 0-12-601680-1
^ Fried, Joel R. Polymer Science & Technology (2nd ed., Prentice-Hall 2003) p.44 ISBN 0-13-018168-4
![{\displaystyle {\frac {d\left[M_{1}\right]}{d\left[M_{2}\right]}}={\frac {\left[M_{1}\right]\left(r_{1}\left[M_{1}\right]+\left[M_{2}\right]\right)}{\left[M_{2}\right]\left(\left[M_{1}\right]+r_{2}\left[M_{2}\right]\right)}}}](https://wikimedia.org/api/rest_v1/media/math/render/svg/885a5c41d70a3248f1694d97f6956cff59a8462f)
