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ACS Publications Division Home Page, http //pubs.acs.org/ (accessed Jan 9, 2008). [Pg.563]

The first two points are discussed at the beginning of this chapter. The second two points will be considered next in a general way applicable to requesting permission from any scientific or scholarly publisher. For information on how to reproduce materials from books, journals, or magazines published by the ACS Publications Division, see Box 7-2. [Pg.83]

Permission requests to reproduce materials from the books, journals, and magazines of the ACS Publications Division should be directed to the ACS Copyright Office. All permission requests must be in writing. The ACS Copyright Office accepts permission requests via e-mail, mail, and fax. Permission is granted only by fax or by mail, so it is important to include a fax number. [Pg.84]

Often, articles are ready for publication in advance of a full issue of a periodical. Several publishers offer these articles online up to weeks in advance of the print issue. They are identical to the corresponding print articles except that page numbers are often not yet available. Publishers market this service under different names the ACS Publications Division labels them As Soon As Publishable (ASAP). For citation purposes, use the designation Online early access in brackets after the journal abbreviation in place of the publisher-specific term. [Pg.318]

ACS Publications Division Home Page, http //pubs.acs.org (accessed Nov 7, 2004). Chemical Abstracts Service. STN on the Web. http //stnweb.cas.org (accessed Nov 7, 2004). [Pg.320]

Sarah C. Blendermann ACS Publications Division, Office of Journal Support Services American Chemical Society... [Pg.444]

SOURCE Analysis of data provided by ACS Publications Division. [Pg.27]

If an author has already submitted or intends to submit a paper to an ACS journal, magazine, or book, and you want to reprint material from that paper, direct your permission requests to the Copyright Office of the ACS Publications Division. Such requests should also mention the title of the publication in which the work will appear. [Pg.185]

PERMISSIONS REQUEST GUIDELINES To Use Materia] from the ACS PUBLICATIONS DIVISION... [Pg.418]

The ACS Publications Division has registered its titles with the Copyright Clearance Center (CCC) to provide immediate ability for users to make authorized photocopies. Registered users of the CCC can report their photocopying activities and pay the appropriate royalty fees either on a transactional basis or through one of the CCC s annual license agreements. For additional information, contact the CCC at 222 Rosewood Drive, Danvers, MA 01923 the telephone number is (S08) 7S0—8400, and the CCC Web site is at http //www.copyright.com. [Pg.419]

You may address questions to the ACS Publications Division copyright staff in several ways ... [Pg.421]

Fig. 6. Phase diagrams with shape transition boundaries for block copolymers as a function of (a) hydrophilic fraction f (from Ref 46, with permission from ACS Publication Division) and (b) water content in dioxane/water solutions (from Ref 39, with permission from ACS Publication Division). B bilayers/vesicles C cylindrical micelles S spherical micelles. Fig. 6. Phase diagrams with shape transition boundaries for block copolymers as a function of (a) hydrophilic fraction f (from Ref 46, with permission from ACS Publication Division) and (b) water content in dioxane/water solutions (from Ref 39, with permission from ACS Publication Division). B bilayers/vesicles C cylindrical micelles S spherical micelles.
Fig. 8. Block copolymer vesicles budding-off from a swollen lamellar phase. After separation, there is no further exchange of block copolymers between vesicles, from Ref 50, with permission from ACS Publications Division. Fig. 8. Block copolymer vesicles budding-off from a swollen lamellar phase. After separation, there is no further exchange of block copolymers between vesicles, from Ref 50, with permission from ACS Publications Division.
Pig. 9. Small, narrow disperse block copolymer vesicles prepared using organic cosolvents. From Ref. 115, with permission from ACS Publications Division. [Pg.6339]

Fig. 13. Experiments showing preferential quenching of long, fluorescently labeled chains due to their accumulation in the outer monolayer of vesicles. In case of spherical micelles, preferential quenching is neither expected nor observed. From Ref 41, with permission from the ACS Publications Division. Fig. 13. Experiments showing preferential quenching of long, fluorescently labeled chains due to their accumulation in the outer monolayer of vesicles. In case of spherical micelles, preferential quenching is neither expected nor observed. From Ref 41, with permission from the ACS Publications Division.
Fig. 15. Different stages of the pearling transition for a tubular PB-PEO block copolymer vesicle after a thermal quench from 38 to 25°C. Compared to lipid vesicles, the transition is extremely slow. The necks close one by one with effective velocities of a few tens of narometers per minute. From Ref 52, with permission from ACS Publications Division. Fig. 15. Different stages of the pearling transition for a tubular PB-PEO block copolymer vesicle after a thermal quench from 38 to 25°C. Compared to lipid vesicles, the transition is extremely slow. The necks close one by one with effective velocities of a few tens of narometers per minute. From Ref 52, with permission from ACS Publications Division.
Fig. 16. Reconstruction of different stages of the fusion (a) and fission process (b) of block copolymer vesicles. From Ref 42, with permission from the ACS Publications Division. Fig. 16. Reconstruction of different stages of the fusion (a) and fission process (b) of block copolymer vesicles. From Ref 42, with permission from the ACS Publications Division.
Fig. 19. (a) Area elasticity modulus and (b) bending modulus /c as a function of the bilayer thickness d. The experiments are in agreement with equations 17 and 18. From Refs. 151 and 154, with permission from the ACS Publications Division. [Pg.6351]

Fig. 21. Fluorescence recovery after photobleaching for a polymersome tip pulled into a glass micropipette. The recovery of the tip intensity can be monitored by fluorescence imaging showing the lateral diffusivity in the bilayer. From Ref. 47, with permission from the ACS Publications Division). Fig. 21. Fluorescence recovery after photobleaching for a polymersome tip pulled into a glass micropipette. The recovery of the tip intensity can be monitored by fluorescence imaging showing the lateral diffusivity in the bilayer. From Ref. 47, with permission from the ACS Publications Division).
Fig. 23. Deflation of a non-cross-linked (left) and a cross-linked polymersome (right). The latter deflates with dents and wrinkles, characteristic of a solid-like membrane. From Ref 168, with permission from the ACS Publications Division. Fig. 23. Deflation of a non-cross-linked (left) and a cross-linked polymersome (right). The latter deflates with dents and wrinkles, characteristic of a solid-like membrane. From Ref 168, with permission from the ACS Publications Division.
FIG. 2 The double glass transition, T g(L) and Tg(JJ), and the Ty amorphous relaxation in linear polyethylene. The size of the circles indicate the intensity of the two Tg. Intensity of the Ty transition increases continuously with decreasing crystallinity. (Reproduced from the review paper of Boyer [2] with the permission of ACS Publication Division.)... [Pg.213]

See other pages where ACS Publications Division is mentioned: [Pg.79]    [Pg.79]    [Pg.84]    [Pg.86]    [Pg.444]    [Pg.183]    [Pg.185]    [Pg.418]   


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