Grafting of Polymers with Controlled Molecular Weight onto Carbon Black Surface

Abstract: ABSTRACT:To graft polymers with controlled molecular weight and narrow molecular weight distribution, the grafting of polymers onto carbon black surface by the termination of living polymer cation with nucleophilic groups, such as amino groups and sodium phenolate and sodium carboxylate groups, introduced onto the surface was investigated. The introduction of amino groups onto the carbon black surface was achieved by the reduction of nitro groups introduced by the nitration of surface aromatic rings. Sodium ph… Show more

“…The precipitate obtained was dispersed in ion-exchange water, and the diswith controlled molecular weight and narrow molecular weight distribution onto ultrafine silica 8 persion was allowed to centrifuge at 5.0 1 10 3 rpm. The chitosan precipitated was dispersed and carbon black 9 by the reaction of living polymer cation with amino groups introduced onto the again in ion-exchange water and centrifuged. The procedures were repeated until supernatant solusurfaces.…”

“…The same tendency was observed in the grafting reaction of surface reactive groups on the carbon black with amino-or hydroxyl-terminated functional polymers [19][20][21][22] and in the grafting by the reaction of living polymer cation with nucleophilic groups on silica and carbon black surfaces. 8,9 Furthermore, the effect of molecular weight of living poly(MeOZO) on the grafting reaction with vents was compared with that of untreated chito- ( MeOZO ) -grafted chitosan powder ( grafting Å 24.5%) was soluble in water, and no insoluble san powder decreased with increasing molecular part was observed. weight of living poly(MeOZO) cation.…”

Grafting reaction of living polymer cations with amino groups on chitosan powder

“…The precipitate obtained was dispersed in ion-exchange water, and the diswith controlled molecular weight and narrow molecular weight distribution onto ultrafine silica 8 persion was allowed to centrifuge at 5.0 1 10 3 rpm. The chitosan precipitated was dispersed and carbon black 9 by the reaction of living polymer cation with amino groups introduced onto the again in ion-exchange water and centrifuged. The procedures were repeated until supernatant solusurfaces.…”

“…The same tendency was observed in the grafting reaction of surface reactive groups on the carbon black with amino-or hydroxyl-terminated functional polymers [19][20][21][22] and in the grafting by the reaction of living polymer cation with nucleophilic groups on silica and carbon black surfaces. 8,9 Furthermore, the effect of molecular weight of living poly(MeOZO) on the grafting reaction with vents was compared with that of untreated chito- ( MeOZO ) -grafted chitosan powder ( grafting Å 24.5%) was soluble in water, and no insoluble san powder decreased with increasing molecular part was observed. weight of living poly(MeOZO) cation.…”

Grafting reaction of living polymer cations with amino groups on chitosan powder

“…Further, we have reported the grafting reaction of living poly(IBVE) with nucleophilic groups introduced onto inorganic powders [12,13]. Therefore, the grafting of poly(IBVE) onto inorganic fiber surface by the termination of living poly(IBVE) with surface amino groups introduced onto the surface (GF-NHR, AIF-NHR, or CF-NH2) was investigated (Scheme 1).…”

“…On the other hand, we have also pointed out that various polymers with welldefined molecular weight and structure can be grafted onto inorganic powder surface by the reaction of surface nucleophilic groups, such as amino groups, with living polymer cations [12,13].…”

Grafting of polymers with controlled molecular weight onto inorganic fiber surface by termination of living polymer cation with amino group on the surface

“…In the graft polymerization, the polymers were effectively grafted onto the surface by propagation of the grafted polymers from the surface of carbon black. In addition, Yoshikawa et al [16] grafted polymers with controlled molecular weight and narrow molecular weight distribution onto carbon black surface by termination of living polymer cation with nucleophilic groups, such as amino groups and sodium phenolate and carboxylate groups, introduced onto the surface. The increase of molecular weight of the living polymer decreased the mole number of grafted polymer chains on carbon black surface due to the steric hindrance.…”

Novel amphiphilic carbon black composite nanoparticles from TEMPO-terminated polymer and TEMPO-terminated block copolymer grafted carbon black