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polymer

Polymer is the product made of the polymerization reaction of monomer. Molecule should have repetitive structural units. Polymer of low molecular weight is called as low polymer (or oligomer) such as trioxymethylene. Polymer of high-molecular weight, up to thousands or even millions is called as high polymer or high-molecule compound. There are two types of high polymers including natural products and artificially synthetic product. Natural polymer such as protein is the polymers of amino acids while the starch and cellulose are the polymers (polysaccharides) of cyclic polyhydroxy, also known as biopolymers. Most of them are biodegradable and may cause short-term water BOD increment. It can also cause decomposition to generate pollutants such as ammonia, hydrogen sulfide and methane under anaerobic conditions, but will not cause long-term environmental impact. There are many types of synthetic polymers with their products having wide application. Related products include polyvinyl chloride and polystyrene plastics, resins, polyester and rubber. They are non-biodegradable substance. Long-term existence in the environment can cause a huge amount of garbage waste, among which the plasticizer will be evaporated out to pollute the environment, affecting human health at the same time. The monomers of polymer are mostly derived from petroleum, many of which are toxic and harmful substances, such as vinyl chloride which is a carcinogen. Nowadays, people are developing various polymer-containing oxide, peroxide-containing compounds and carbonyl-containing compounds. The polymer, under the sunlight photolysis, will be converted to low molecular weight organic compounds and further become harmless bio-degradable substance without contaminating the environment.

High molecular polymer is a compound consisting of one or several major structural units connecting with each other by covalent bond, also known polymers, high-molecule compound, macromolecular compounds and the like. E.g., polyethylene [-CH2-CH2-] n, Nylon 6 [-NH (CH2) 5CO-] n, whose structural units are respectively-CH2-CH2-, -NH (CH2) 5CO- with the polymerization degree being n.

Because of the high molecular weight (usually 104 to 106), it displays a number of special properties, such as relatively refractory soluble, or insoluble; swelling before being dissolved; much higher solution viscosity than a solution of equal concentration of small molecules; it has great intermolecular forces with usually exhibiting as only viscous liquid or solid form, not able to subject to gasification; the solid has a certain mechanical strength and can be subject to snagging and drawing.

The polymer is consists of a lot of macromolecular polymer chains of varying lengths, this feature is called the polydispersity of the molecular weight. We can use the distribution of the molecule weight to describe its polydispersity. The commonly referred molecular weight of the polymer is the average molecular weight of the polymer. Depending on the different statistical averaging method, there is number average molecular weight [equal to the total mass of the polymer (in g unit) divided by the total amount of the contained molecules of various molecule weights to represent Mm], weight average molecular weight (equal to the sum of the multiply of the molecules of various molecule weight and their corresponding molecular weight, expressed in Mm) and so on. Mm / Mm is called as polydispersity index, used to measure the width of the molecular weight distribution. The greater, the polydispersity index, the wider the molecular weight distribution will be and the greater the degree of dispersion.

The properties of polymers are still largely determined by the shape of the molecular chain. Depending on the shape of the molecular chain, it can be divided into linear, ball-type, network type and body-type, several structures.

The atoms of the main chain in the linear-structure polymer are often arranged in the shape of a long chain and the main chain is connected with in more or less amount of branches of varying lengths. When the polymer of such structure is heated, they tend to be melted, but also be soluble in certain organic solvents, having the probability of forming a crystal and can be oriented artificially. As some small amounts of branched-chain contained in increases the molecular spacing, the structure becomes loose, thereby reducing mechanical strength but increasing the solubility and plasticity. Common polymers belonging to this type include polyethylene, polyvinyl chloride and rubber.

The main chain of the ball-shape-structure polymer is also in long chain shape but with a large number of branches surrounding the main chain, making the molecule become globular. Its strength and elasticity is as high as that of the linear structure with no significant melting point but with excellent solubility. Phenolic resins, urea-formaldehyde resin which are the intermediate of reactions both belong to such structures.

The main chain of the high polymer of network structure is also in long chain shape, but has the bonds cross-linked, forming mesh-shape. It does not undergo melting at high temperatures but can be softened to have plasticity; it is not dissolved in an organic solvent but can swell, i.e. vulcanized rubber belongs to such type of polymer.

The high polymer of body structure has the long-chain as the main chain, being formed through the crosslink with many other molecules in three-dimensional space. However, during the process of polymerization of monomers, it can also be gradually formed through stepwise cross-linking.

The polymer of body structure is hard and brittle and can neither be melted in the high temperature nor do have plasticity. It can’t be dissolved in an organic solvent. The final products of phenol, aldehyde amine, epoxy and polyester, etc. all belong to this structure.
We can make classification for the polymer from different perspectives. According to the property and purpose, it can be divided into chemical fiber, plastics, rubber, paint and adhesives; According to the name of the synthetic reaction, it can be divided into addition polymer (such as polyethylene, polypropylene, etc.), condensation polymers (such as polyesters, polyamides etc.), ring-opening polymer (e.g., polyether, etc.); according to the source, it can be divided into natural polymers (e.g. starch, cellulose, etc.), synthetic polymers (e.g. vinyl polymers, etc.), semi-synthetic polymers (e.g. acetic acid cellulose and so on); according to the elements of the main chain, it can be divide into carbon-chain polymer (the main chain is mainly composed of carbon atoms), hetero chain polymer (the main chain contains, in addition to carbon atoms, oxygen, nitrogen, sulfur and other hetero atoms as well), element-organic polymer (main chain mainly composed of boron, silicon, aluminum, oxygen, nitrogen, sulfur and phosphorus atoms, but side-chain consists of organic groups such as methyl, ethyl, etc.); according to the application functions, it can be divided into general polymer, functional polymer and so on.

The major index of the polymers include strength, hardness, heat resistance, corrosion resistance, abrasion resistance, solvent resistance, light transmittance, and air tightness as well as electrically insulating properties. Density of the polymer is small, being much smaller than that of steel of the same volume; some of them are conductive, magnetic, and some are high temperature resistant, low temperature resistant and radiation resistant; some have excellent air tightness, transparency and so on. It has been widely used in medical, electrical conductivity, heat resistance, construction, packaging materials, plastic and some other fields.
The method of producing a polymer include bulk polymerization (including melt polymerization, referring to that monomer undergoes polymerization upon the action of light, heat and radiation without other media), solution polymerization (polymerization of monomer, initiator dissolved in an appropriate solution), emulsion (under the action of emulsifier and agitation, have the monomer be dispersed in water to form emulsion liquid to have polymerization), suspended polymerization (under the action of stirring and a dispersing agent, a monomer is dispersed into monomer droplets for being suspended in water for polymerization), etc., according to different requirements, we can apply different polymerization methods.

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Structure Chemical Name CAS MF
CHO-PEG-SS CHO-PEG-SS
COOH-PEG-SS COOH-PEG-SS
DBCO-PEG-COOH DBCO-PEG-COOH
PCL(5K)-PEG-Mal PCL(5K)-PEG-Mal
C18H37-PEG-FA C18H37-PEG-FA
COCl-PEG-NH-Mal COCl-PEG-NH-Mal
N3-PEG-SVA N3-PEG-SVA
NH2-PEG-Progestrone NH2-PEG-Progestrone
DSPE-PEG-CLS DSPE-PEG-CLS
Polyurethane Polyurethane 9009-54-5 C3H8N2O
DSPE-PEG1000-NH2 DSPE-PEG1000-NH2
alpha-Biotin-omega-carboxy succinimidyl ester poly(ethylene glycol) (PEG-MW 10.000 Dalton) alpha-Biotin-omega-carboxy succinimidyl ester poly(ethylene glycol) (PEG-MW 10.000 Dalton) C22H34N4O8S
E type epoxy resin E type epoxy resin
Binder Binder
CHOLESTEROL, WATER SOLUBLE CHOLESTEROL, WATER SOLUBLE 69068-97-9
Polyethylene glycol-G-maleimide Polyethylene glycol-G-maleimide
PEG-g-NH2 PEG-g-NH2
FITC-PEG-FITC FITC-PEG-FITC
mPEG-GAA(mPEG-Glutaramide acid) mPEG-GAA(mPEG-Glutaramide acid)
GAA-PEG-GAA(Glutaramide Acid-PEG-Glutaramide Acid) GAA-PEG-GAA(Glutaramide Acid-PEG-Glutaramide Acid)
N3-PEG-Biotin N3-PEG-Biotin
IA-PEG-COOH IA-PEG-COOH
Thiol-PEG4-azide Thiol-PEG4-azide
Retinoic acid PEG NHS Retinoic acid PEG NHS
Niacin PEG FITC Niacin PEG FITC
Cholic acid PEG NHS Cholic acid PEG NHS
CHO-PEG12-MAL CHO-PEG12-MAL
TAMRA-PEG4-Tetrazine TAMRA-PEG4-Tetrazine
ASPHALTUM ASPHALTUM 8052-42-4
MW:350 MW:350
8-ArmPEG-(1Arm-N3,7Arm-carboxylic acid) 8-ArmPEG-(1Arm-N3,7Arm-carboxylic acid)
ACA-PEG-N3 ACA-PEG-N3
Benzyl-PEG11-CH2CH2COOH Benzyl-PEG11-CH2CH2COOH
Benzyl-PEG32-OH Benzyl-PEG32-OH
COOH-PEG24-NH2.HCl COOH-PEG24-NH2.HCl
DMPE-PEG-NH2 DMPE-PEG-NH2
DPPE-PEG-NH2 DPPE-PEG-NH2
FA-PEG3-NH2 FA-PEG3-NH2
FA-PEG-LA FA-PEG-LA
IA-PEG-FITC IA-PEG-FITC
mPEG-LNA mPEG-LNA
N3-PEG-Alkene N3-PEG-Alkene
PLGA(1.8K)-PEG-COOH PLGA(1.8K)-PEG-COOH
STA-PEG-NH2 STA-PEG-NH2
Pomalidomide-PEG1-azide Pomalidomide-PEG1-azide 2133360-04-8 C17H16N6O6
Biotin-PEG-SAS Biotin-PEG-SAS
PLGA(10K)-PEG-OH PLGA(10K)-PEG-OH
PLGA(12K)-PEG-Mal PLGA(12K)-PEG-Mal
LRA-PEG-Mal LRA-PEG-Mal
ACA-PEG-SVA ACA-PEG-SVA
DLPE-PEG-Mal DLPE-PEG-Mal
Cy3-PEG-SH Cy3-PEG-SH
mPEG-SS-NH2 mPEG-SS-NH2
PLGA(10K)-PEG-NH2 PLGA(10K)-PEG-NH2
BocNH-PEG11-CH2CH2N3
BocNH-PEG11-CH2CH2N3 2395004-21-2 C29H58N4O13
Thalidomide-linker 14 Thalidomide-linker 14 2376990-30-4 C21H27ClN4O8
Au-PEG-NH2(Au:15nm) Au-PEG-NH2(Au:15nm)
SH-PEG5-NH2.HCl SH-PEG5-NH2.HCl
Thiol-C10-amide-PEG8 Thiol-C10-amide-PEG8 1353948-95-4 C27H55NO9S
Teflon emulsion JF-4DCF Teflon emulsion JF-4DCF
Turpentine Turpentine 9005-90-7
α-Allyl-ω-MaleiMidyl poly(ethylene glycol) α-Allyl-ω-MaleiMidyl poly(ethylene glycol)
Polyethylene glycol-G-hydroxyl Polyethylene glycol-G-hydroxyl
Biotin-PEG7-Azide Biotin-PEG7-Azide 1334172-75-6 C26H48N6O9S
mPEG-ACA (mPEG-Acrylamide) mPEG-ACA (mPEG-Acrylamide)
mPEG-GAS(mPEG-Glutaramide Succinimidyl ester) mPEG-GAS(mPEG-Glutaramide Succinimidyl ester)
mPEG-Biotin mPEG-Biotin
OPSS-PEG-Silane OPSS-PEG-Silane
Br-PEG-Mal Br-PEG-Mal
Silane-PEG-Biotin Silane-PEG-Biotin
PI  fiber PI fiber
Biotin-PEG-PFP Biotin-PEG-PFP
OPSS-PEG-OPSS OPSS-PEG-OPSS C16H20N2O2S4
TCO PEG NHS TCO PEG NHS
Glutathione PEG Glutathione Glutathione PEG Glutathione
Polylysine PEG Conjugate Polylysine PEG Conjugate
Cy3 PEG Biotin Cy3 PEG Biotin
TCO PEG Maleimide TCO PEG Maleimide
N3-PEG9-CH2CH2NH2 N3-PEG9-CH2CH2NH2 1207714-69-9 C20H42N4O9
Iodo-PEG3-Azide Iodo-PEG3-Azide 936917-36-1 C8H16IN3O3
IA-PEG8-Biotin IA-PEG8-Biotin
SS-PEG-SS SS-PEG-SS
Alkyne-PEG-PLA(3K) Alkyne-PEG-PLA(3K)
DMPE-PEG-COOH DMPE-PEG-COOH
FITC-PEG-Azithromycin FITC-PEG-Azithromycin
Fmoc-NH-PEG-SC Fmoc-NH-PEG-SC
mPEG10-COOH mPEG10-COOH
mPEG-DOPE mPEG-DOPE 610767-18-5
mPEG-RB mPEG-RB
PAMBA-PEG-PAMBA PAMBA-PEG-PAMBA
PLGA(15K)-PEG-COOH PLGA(15K)-PEG-COOH
SC-PEG-Alkene SC-PEG-Alkene
STA-PEG-CHO STA-PEG-CHO
STA-PEG-SH STA-PEG-SH
mPEG6-Silane mPEG6-Silane
2-(2,6-Dioxo-3-piperidinyl)-4-[2-[2-(2-propyn-1-yloxy)oxy]ethoxy]-1H-isoindole-1,3(2H)dione 2-(2,6-Dioxo-3-piperidinyl)-4-[2-[2-(2-propyn-1-yloxy)oxy]ethoxy]-1H-isoindole-1,3(2H)dione 2098487-52-4 C20H20N2O7
Boron trifluoride acetonitrile complex Boron trifluoride acetonitrile complex 420-16-6 C2H3BF3N
HEXAFLUOROPROPYLENE OXIDE DIMER HEXAFLUOROPROPYLENE OXIDE DIMER C6F12O2
PEG derivatives PEG derivatives
Pyralene Pyralene
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