語系:
繁體中文
English
說明(常見問題)
回圖書館首頁
手機版館藏查詢
登入
回首頁
切換:
標籤
|
MARC模式
|
ISBD
Photochemical Crosslinking Reactions...
~
Carbone, Nicholas.
FindBook
Google Book
Amazon
博客來
Photochemical Crosslinking Reactions in Polymers.
紀錄類型:
書目-語言資料,印刷品 : Monograph/item
正題名/作者:
Photochemical Crosslinking Reactions in Polymers./
作者:
Carbone, Nicholas.
面頁冊數:
248 p.
附註:
Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: 2351.
Contained By:
Dissertation Abstracts International73-04B.
標題:
Engineering, Chemical. -
電子資源:
http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=3489665
ISBN:
9781267090645
Photochemical Crosslinking Reactions in Polymers.
Carbone, Nicholas.
Photochemical Crosslinking Reactions in Polymers.
- 248 p.
Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: 2351.
Thesis (Ph.D.)--Columbia University, 2012.
The post-synthesis modification of polymer properties has very broad applications in industry. It is employed to produce products that are impossible to directly synthesize, modify biomolecules for medical use, and provide compounds for industrial and academic research. Modifying the polymer molecular weight distribution through crosslinking is one of the simplest methods of achieving the desired properties. The crosslinking of polymers to form gels has been used for decades in the automotive industry to produces tires. More recently, polymer crosslinking has been applied to environmental cleanup, wound healing materials, consumer products, artificial organs, self-healing coatings, and the micro-patterning of surfaces. Photocrosslinking using additives is one of the safest and most robust methods as it allows precise control of the reaction in space and time.
ISBN: 9781267090645Subjects--Topical Terms:
1018531
Engineering, Chemical.
Photochemical Crosslinking Reactions in Polymers.
LDR
:05915nam a2200361 4500
001
1963975
005
20141009090705.5
008
150210s2012 ||||||||||||||||| ||eng d
020
$a
9781267090645
035
$a
(MiAaPQ)AAI3489665
035
$a
AAI3489665
040
$a
MiAaPQ
$c
MiAaPQ
100
1
$a
Carbone, Nicholas.
$3
2100334
245
1 0
$a
Photochemical Crosslinking Reactions in Polymers.
300
$a
248 p.
500
$a
Source: Dissertation Abstracts International, Volume: 73-04, Section: B, page: 2351.
500
$a
Adviser: Jeffrey T. Koberstein.
502
$a
Thesis (Ph.D.)--Columbia University, 2012.
520
$a
The post-synthesis modification of polymer properties has very broad applications in industry. It is employed to produce products that are impossible to directly synthesize, modify biomolecules for medical use, and provide compounds for industrial and academic research. Modifying the polymer molecular weight distribution through crosslinking is one of the simplest methods of achieving the desired properties. The crosslinking of polymers to form gels has been used for decades in the automotive industry to produces tires. More recently, polymer crosslinking has been applied to environmental cleanup, wound healing materials, consumer products, artificial organs, self-healing coatings, and the micro-patterning of surfaces. Photocrosslinking using additives is one of the safest and most robust methods as it allows precise control of the reaction in space and time.
520
$a
This thesis explores the photocrosslinking of polymers and relates it to structure and mechanism: the properties and intermiscibilities of four crosslinker chemistries and five polymers are rationally designed in Chapter 3. The influence of additive functionality on the reaction is explored in depth with a single additive chemistry in Chapter 4. The mechanism and reaction location is examined in Chapter 5, and a survey of the efficacy of additional crosslinking chemistries is performed in Chapter 6.
520
$a
Multiple polymers and additives are examined in Chapter 3 and their reactions and mechanisms are examined to predict efficacy and utility. It is shown that multiple reaction chemistries allow crosslinking, and that the manipulation of functionality and polymer allows the exploration of specific reaction mechanisms. The differential refractive indices of the polymers are measured by experiment, and the intermiscibility of polymer-additive systems are calculated using group contribution techniques.
520
$a
A hydrogen abstraction induced radical crosslinking mechanism is explored in depth in Chapter 4. Benzophenone-derived additives are used to study photocrosslinking in thin films while varying multiple parameters: the irradiation time, additive to polymer molar ratio, additive functionality, and polymer mobility. Bi-functionality is found to increase the density of radicals in glassy and rubbery systems. The macroradical recombination and scission reactions are modeled and shown to conform to experiment. Analysis of the model results shows that the functionality of the additive is only important above a molar ratio threshold. Below the threshold combination reactions are binary and there are no macroradical bridging reactions in the bi-functional system. Above the threshold the density of radicals is so high that the combination reactions are pseudo first order and macroradical bridging causes differences in the behavior of mono- and bi-functional additive systems. The changes in the molecular weight distributions with reaction extent are tracked using size exclusion chromatography (SEC) with multiple detectors.
520
$a
Chapter 5 studies the hydrogen abstraction reaction of Chapter 4 using electron paramagnetic resonance (EPR) to confirm the predicted reaction location. Spin-trap experiments demonstrate that radicals primarily form on the expected tertiary carbon, confirming the hydrogen abstraction mechanism employed in Chapter 4. Unexpected peaks in the EPR spectra point towards a potentially new reaction between benzophenone and the spin-trap. The EPR experiments are also used to verify that no other radical reactions are occurring in the systems of Chapter 4.
520
$a
The experimental space is expanded in Chapter 6 to other polymers and other crosslinking chemistries. Full characterization of all the potential reactions was impossible, but many polymer-additive combinations are shown to react in the predicted ways. Certain crosslinker chemistries and functionalities combine to allow the study of macromolecule combination without scission and these chemistries are suggested for further use in the experimental study of the early stages of crosslinking and gelation.
520
$a
This thesis finds that at low molar ratios, the additive functionality does not matter; functionality is only important at high molar ratios of additive to polymer due to high radical density and a transition to pseudo-first order kinetics. The expectations in Chapter 3 are shown to be accurate and the choice of additive chemistry and polymer allows the preferential selection of desired reactions. Hydrogen abstraction can be forced to occur either from the pendant group or the chain backbone, leading to systems in which chain scission is not possible and combination can be exclusively selected. Non-radical based crosslinking chemistries can also be used to produce crosslinks without risk of chain scission. These findings have a wide applicability in many fields and implications for the improved design of radical-based crosslinking systems.
590
$a
School code: 0054.
650
4
$a
Engineering, Chemical.
$3
1018531
650
4
$a
Plastics Technology.
$3
1023683
650
4
$a
Chemistry, Polymer.
$3
1018428
690
$a
0542
690
$a
0795
690
$a
0495
710
2
$a
Columbia University.
$b
Chemical Engineering.
$3
2094738
773
0
$t
Dissertation Abstracts International
$g
73-04B.
790
$a
0054
791
$a
Ph.D.
792
$a
2012
793
$a
English
856
4 0
$u
http://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=3489665
筆 0 讀者評論
館藏地:
全部
電子資源
出版年:
卷號:
館藏
1 筆 • 頁數 1 •
1
條碼號
典藏地名稱
館藏流通類別
資料類型
索書號
使用類型
借閱狀態
預約狀態
備註欄
附件
W9258974
電子資源
11.線上閱覽_V
電子書
EB
一般使用(Normal)
在架
0
1 筆 • 頁數 1 •
1
多媒體
評論
新增評論
分享你的心得
Export
取書館
處理中
...
變更密碼
登入