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Pulps. Nordic Pulp Paper Res.

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J., 2003; 18(4): 436–440.

29 Gellerstedt, G., W.W. Al-Dajani, Bleachability

of alkaline pulps. Part 1. The

importance of b-aryl ether linkages in

lignin. Holzforschung, 2000; 54(6):

609–617.

30 Gellerstedt, G., W.W. Al-Dajani, Some

factors affecting the brightness and

TCF-bleachability of kraft pulp. Nordic

Pulp Paper Res. J., 2003; 18(1): 56–62.

31 Klevinska, V., T. Bykova, A. Treimanis,

Multistage kraft cooking as a way of producing

bleachable grade alder pulp. Cellulose

Chem. Technol., 2000; 34(5–6):

581–593.

32 Rawat, N., T.I. McDonough, Effects of

pulping conditions on the bleachability

of hardwood kraft pulps: 1. Effects of

effective alkali charge in the pulping of

birch and maple. Pulping Conference,

Proceedings of the Technical Association

of the Pulp and Paper Industry,

1998: 883–891.

33 Sixta, H., Comparative evaluation of different

concepts of sulfite pulping technology.

Papier, 1998; 52(5): 239–249.

34 Sun, Y., D.S. Argyropoulos, R.M. Berry,

M. Fenster, A. Yu, The effect of metal

ions on the reaction of hydrogen peroxide

with Kraft lignin model compounds.

Can. J. Chem., 1999: 667–675.

35 Lucia, L.A., A.J. Ragauskas, F.S. Chakar,

Comparative evaluation of oxygen

delignification processes for low- and

high-lignin-content softwood kraft

pulps. Ind. Eng. Chem. Res., 2002;

41(21): 5171–5180.

36 Friman, L., L. Logenius, R. Agnemo,

H.E. Hogberg, Comparison of metal

profiles in thermomechanical pulping

processes in which either hydrogen peroxide

or dithionite bleaching is used –

Content of metals in process waters and

in chips and pulp samples before and

after extraction with acid or a chelating

agent. Pap. Puu, 2003; 85(6): 334–339.

37 Baptista, C., N. Belgacem, A.P. Duarte,

The effect of surfactants on kraft pulping

of Pinus pinaster. Appita J., 2004;

57(1): 35–39.

38 Pisuttipiched, S., E. Retulainen,

R. Malinen, H. Kolehmainen,

M. Ruhanen, S. Siripattanadilok, Effect

898 7Pulp Bleaching

of harvesting age on the quality of Eucalyptus

camaldulensis bleached kraft pulp.

Appita J., 2003; 56(5): 385–390.

39 Svedman, M., P. Tikka, M. Luhtanen,

Effects of softwood morphology and

chip thickness on pulping with a displacement

kraft batch process. Tappi J.,

1998; 81(7): 157–168.

40 Persson, E., J. Bergquist, T. Elowson,

J. Jakara, B. Lonnberg, Brightness,

bleachability and colour reversion of

groundwood made of wet- and drystored

Norway spruce (Picea abies) pulpwood.

Pap. Puu, 2002; 84(6): 411–415.

41 Furtado, F.P., D.V. Evtuguin,

T.M. Gomes, Effect of the acid stage in

ECF bleaching on Eucalyptus globulus

kraft pulp bleachability and strength.

Pulp Paper Can., 2001; 102(12): 89–92.

42 Ju, Y., M. Kishino, H. Ohi, Preparation

of high-yielded softwood chemical pulp

and its bleachability. Sen-I Gakkaishi,

2000; 56(4): 199–204.

43 Zhan, H., B. Yue, W. Hu, W. Huang,

Kraft reed pulp TCF bleaching with

enzyme pretreatment. Cellulose Chem.

Technol., 1999; 33(1): 53–60.

44 Springer, E.L., J.D. McSweeny, Treatment

of softwood kraft pulps with peroxymonosulfate

before oxygen delignification.

Tappi J., 1993: 194–199.

45 Lachenal, D., L. Bourson, M. Muguet,

A. Chauvet, Lignin activation improves

oxygen and peroxide delignification. Cellulose

Chem. Technol., 1990; 24: 593–601.

46 Jiang, Z.H., B. Van Lierop, A. Nolin,

R. Berry, A new insight into the bleachability

of kraft pulps. J. Pulp Paper Sci.,

2003. 29(2): 54–58.

47 Gellerstedt, G., K. Gustafsson, A. Labidi,

F. Pla, Alkaline delignification of hardwoods

in a flow-through reactor working

at a low residence time. 4. Characterization

of lignins by oxidative-degradation

and aminolysis. Holzforschung,

1992; 46(3): 199–204.

48 Gellerstedt, G., D. Robert, Structuralchanges

in lignin during kraft cooking.

7. Quantitative C-13 NMR analysis of

kraft lignins. Acta Chim. Scand. Series B.

Org. Chem. Biochem., 1987; 41(7):

541–546.

49 Gellerstedt, G., K. Gustafsson, Structural-

changes in lignin during kraft

cooking. 5. Analysis of dissolved lignin

by oxidative-degradation. J. Wood Chem.

Technol., 1987; 7(1): 65–80.

50 Gellerstedt, G., E. Lindfors, Structuralchanges

in lignin during kraft cooking.

4. Phenolic hydroxyl-groups in wood

and kraft pulps. Svensk. Papperstidn. –

Nordisk Cellulosa, 1984; 87(15):

R115–R118.

51 Robert, D.R., M. Bardet, G. Gellerstedt,

E.L. Lindfors, Structural-changes in lignin

during kraft cooking. 3. On the

structure of dissolved lignins. J. Wood

Chem. Technol., 1984; 4(3): 239–263.

52 Gellerstedt, G., E.L. Lindfors, C.

Lapierre, B. Monties, Structural-changes

in lignin during kraft cooking. 2. Characterization

by acidolysis. Svensk. Papperstidn.

– Nordisk Cellulosa, 1984; 87(9):

R61–R67.

53 Gellerstedt, G., J. Gierer, Reactions of

lignin during neutral sulphite cooking.

1. Behaviour of beta-arylether structures.

Acta Chim. Scand., 1968; 22(8):

2510.

54 Gierer, J., Reactions of lignin during

sulfite and sulfate cooking. Papier, 1973;

27(12): 629–633.

55 Gellerstedt, G., J. Gierer, Reaction of lignin

during neutral sulphite cooking.

2. Behaviour of phenylcoumaran structures.

Acta Chim. Scand., 1968; 22(6):

2029.

56 Gierer, J., L.A. Smedman, Reactions of

lignin during sulphate cooking. 10. Synthesis

and alkaline treatment of model

compounds representing intermediary

episulphide structures. Acta Chim.

Scand., 1966; 20(7): 1769.

57 Gierer, J., N.H. Wallin, Reactions of lignin

during sulphate cooking. 9. Interaction

between thiol groups and intermediary

epoxide structures. Acta Chim.

Scand., 1965; 19(6): 1502.

58 Gierer, J., L.A. Smedman, Reactions of

lignin during sulphate cooking. 8.

Mechanism of splitting of beta-arylether

bonds in phenolic units by white liquor.

Acta Chim. Scand., 1965; 19(5): 1103.

59 Gierer, J., N.H. Wallin, B. Lenz, Reactions

of lignin during sulphate cooking.

V. Model experiments on splitting of

aryl-alkyl ether linkages by 2 N sodium

References 899

hydroxide + by white liquor. Acta Chim.

Scand., 1964; 18(6): 1469.

60 Gellerstedt, G., E.L. Lindfors, Structural-

changes in lignin during kraft

pulping. Holzforschung, 1984; 38(3):

151–158.

61 Gellerstedt, G., L. Zhang, Chemistry of

TCF-bleaching with oxygen and hydrogen

peroxide. In Oxidative Delignification

Chemistry, D.S. Argyropoulos, Ed.

American Chemical Society, Oxford

University Press:Washington, DC,

2001: 61–72.

62 Tamminen, T.L., B.R. Hortling, Lignin

reactions during oxygen delignification

of various alkaline pulps. In Oxidative

Delignification Chemistry, D.S. Argyropoulos,

Ed. American Chemical Society,

Oxford University Press:Washington,

DC, 2001: 73–91.

63 Lawoko, M., R. Berggren, F. Berthold,

G. Henriksson, G. Gellerstedt, Changes

in the lignin-carbohydrate complex in

softwood kraft pulp during kraft and

oxygen delignification. Holzforschung,

2004; 58(6): 603–610.

64 Olkkonen, C., H. Tylli, I. Forsskahl,

A. Fuhrmann, T.Hausalo, T. Tamminen,

B. Hortling, J. Janson, Degradation of

model compounds for cellulose and

ligno-cellulosic pulp during ozonation

in aqueous solution. Holzforschung,

2000; 54(4): 397–406.

65 Laine, C., T. Tamminen, B. Hortling,

Carbohydrate structures in residual lignin-

carbohydrate complexes of spruce

and pine pulp. Holzforschung, 2004;

58(6): 611–621.

66 Antonsson, S., M.E. Lindstrom,

M. Ragnar, A comparative study of the

impact of the cooking process on oxygen

delignification. Nordic Pulp Paper

Res. J., 2003; 18(4): 388–394.

67 Roost, C., M. Lawoko, G. Gellerstedt,

Structural changes in residual kraft

pulp lignins. Effects of kappa number

and degree of oxygen delignification.

Nordic Pulp Paper Res. J., 2003; 18(4):

395–399.

68 Bourbonnais, R., M. Paice, Voltammetric

measurement of lignin in pulp

and paper samples – An electron transfer

catalytic approach with mediators.

J. Electrochem. Soc., 2004; 151(7):

E246–E249.

69 Bourbonnais, R., L. Valeanu, M.G. Paice,

Voltammetric analysis of the bleachability

of softwood kraft pulps. Holzforschung,

2004; 58(6): 581–587.

70 Lundquist, K., On the degradation of

lignin during pulping conditions. In


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