Compositions – Light transmission modifying compositions
Reexamination Certificate
2000-05-24
2002-06-11
Tucker, Philip (Department: 1712)
Compositions
Light transmission modifying compositions
C252S587000, C252S585000, C359S484010
Reexamination Certificate
active
06402994
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to fused ring bridge, ring-locked molecules featuring various donor and acceptor groups or donor- and acceptor-like heterocycles and a stable benzene-, naphthalene- or anthracene-derived polyene bridge, i.e., fused ring bridge, ring-locked compounds, as exemplified below, and methods of their use.
2. Description of the Related Art
The basic elements of photorefractivity include photosensitivity, photoconductivity and electrooptical activity. As an example, the photorefractive (PR) effect enables the recording of optical information in three-dimensional solids through the optical generation of an internal space-charge field and refractive index changes in the solid, as described in P. Günter and J.P. Huignard,
Photorefractive Materials and Their Applications
, Vol. 1 and 2 (Springer, Berlin, 1988 and 1989), incorporated herein by reference. Due to high optical sensitivity and the ability to erase and rewrite information optically in real-time, photorefractive materials are expected to play a major role in photonic technologies. One special aspect of the PR recording mechanism is the non-zero phase shift that can exist between the optical intensity pattern and the stored phase replica. This so-called nonlocal response can be used to transfer energy between two interacting beams. For some applications, such as image amplification, a strong energy transfer is desired, as described in A. Grunnet-Jepsen, C. L. Thomson, W. E. Moerner,
Science
277, 549 (1997). However, for other applications based on the recording and retrieval of stored holograms, the important material parameter is the dynamic range or index modulation An, and one of the current challenges is to increase it.
The photorefractive effect in inorganic crystals has been studied. The mechanism of the refractive index modulation by the internal space-charge field was based on the linear electro-optic effect (i.e., the Pockels effect), as described in A. Ashkin, G. D. Boyd, J. M. Dziedic, R. G. Smith, A. A. Ballmann, and K. Nassau,
Appl. Phys. Lett.
9, 72 (1966). More recently, polymers have emerged as new photorefractive materials as described in S. Ducharme, J. C. Scott, R. J. Twieg, and W. E. Moerner,
Phys. Rev. Lett.
66, 1846 (1991), W. E. Moerner and S. M. Silence,
Chem. Rev.
94, 127 (1994), Y. Zhang, R. Burzynski, S. Ghosal and M. K. Casstevens,
Adv. Mater.
8, 111 (1996), B. Kippelen, K. Meerholz, and N. Peyghambarian in
Nonlinear Optics of Organic Molecules and Polymers
, edited by H. S. Nalwa and S. Miyata (CRC, Boca, Raton, 1997), p. 465, all of which are incorporated herein by reference.
Active organic polymers are emerging as key materials for advanced information and telecommunication technology. Owing to their outstanding performance, structural flexibility, and lightweight, polymers are expected to play a major role in optical technology, especially when large-scale manufacturing of devices at low cost is crucial. Other important characteristics,, that may be desirable depending on the application include sufficiently long shelf life, optical quality, thermal stability and processing ease. Multifunctional nonlinear optical polymers and molecular assemblies are intensively investigated for electrooptic and photorefractive applications.
In addition, with the rapid improvement of the performance of guest/host PR polymer composites, as described in M. C. J. M. Donckers, S. M. Silence, C. A. Walsh, F. Hache, D. M. Burland, and W. E. Moerner,
Opt. Lett.
18, 1044 (1993), M. Liphard, A. Goonesekera, B. E. Jones, S. Ducharme, J. M. Takacs., and L. Zhang,
Science
263, 367 (1994) and the report of near 100% diffraction efficiency in 105 &mgr;m thick samples containing a photoconducting sensitizer by K. Meerholz, B. L. Volodin, Sandalphon, B. Kippelen, and N. Peyghambarian,
Nature
371, 497 (1994), it became apparent that the Pockels effect alone could not account for the origin of the high refractive index changes. A detailed explanation of this effect was provided with the orientational enhancement model proposed by W. E. Moerner, S. M. Silence, F. Hache, and G. C. Bjorklund,
J. Opt. Soc. Am. B
11, 320 (1994) in which both the birefringence induced by the orientation of the dopant molecules [M. G. Kuzyk, J. E. Sohn, C. W. Dirk,
J. Opt. Soc. Am. B
7, 842 (1990), J. W. Wu,
J. Opt. Soc. Am. B
8, 142 (1991)] an the molecules' electrooptic properties were reported to contribute to the refractive index modulation changes.
Thus, on a molecular level, according to the oriented gas model [D. J. Williams in
Nonlinear Optical Properties of Organic Molecules and Crystals;
Vol. 1, edited by D. S. Chemla and J. Zyss (Academic Press, Inc., Orlando, 1987), K. D. Singer, M. G. Kuzyk, and J. E. Sohn,
J. Opt. Soc. Am. B
4, 968 (1987), molecular figure of merit F may be defined for the optimization of the PR effect:
F=A
(
T
)&mgr;
2
&Dgr;&agr;+&mgr;&bgr; (1)
where &Dgr;&agr; is the polarizability anisotropy of the chromophore, &mgr; is its dipole moment, &bgr; is its first hyperpolarizability, and A(T)=2/(9kT) is a scaling factor (kT is thermal energy).
Early PR polymeric compositions were based on dopant molecules (i.e., chromophores) such as 3-fluoro-4-N,N-diethylamino-nitrostyrene (FDEANST) and 2,5-dimethyl-4-p-nitrophenylazoanisole (DMNPAA) because of these dopants' electro-optic properties. More recent PR polymeric compositions, described in P. M. Lundquist, R. Wortmann, C. Geletneky, R. J. Twieg, M. Jurich, V. Y. Lee, C. R. Moylan, D. M. Burland,
Science
274, 1182 (1996) (In this reference, the value for refractive index 0 reported in the Table 2 for a sample with composition 2BNCM:PMMA:TNF 90:10:0.3 wt. % for which four-wave mixing results are presented in
FIG. 1
, should read 1.5×10
−3
instead of 10×10
−3
) were based on dopants such as N-2-butyl-2,6-dimethyl-4H-pyridone-4-ylidenecyanomethylacetate (2BNCM) with large polarizability anisotropy, improving the dynamic range by a factor of 1.5 over the best previous PR polymeric compositions doped with DMNPAA.
Using model calculations and bond order alternation theory, we have shown recently in B. Kippelen, F. Meyers, N. Peyghambarian, and S. R. Marder,
J. Am. Chem. Soc.
119, 4559 (1997) that the orientational birefringence contribution is enhanced for chromophores that are polarized beyond the cyanine limit, i.e., for chromophores that feature both high &Dgr;&agr; and high &mgr;.
In order to explore this molecular design rationale, the present invention focuses on linear molecules such as polyenes, as opposed to chromophores that contain benzene rings in the bridge. These polyenes exhibit a considerable charge transfer that is confined along the quasi one-dimensional &pgr;-conjugated bridge providing a large &Dgr;&agr; and can lead to an important charge separation in the ground-state that provides large molecular dipole moment and polarizability anisotropy, as predicted in B. Kippelen, F. Meyers, N. Peyghambarian, and S. R. Marder,
J. Am. Chem. Soc.
119, 4559 (1997). Furthermore, given the known thermal instability of donor-acceptor substituted polymethine bridged chromophore dyes (where the polymethine bridge is formed from CH groups joined by single or double bonds) at elevated temperatures, described below, we discovered the importance of the structure of fused ring bridge, ring-locked dyes according to the invention described herein and exemplified below where the donors and the acceptors induce a large molecular dipole moment and also increase polarizability anisotropy.
Preliminary work in synthesis of charged fused ring bridge, ring-locked ionic cyanine-like compounds was reported in Y. L. Slominskii, L. M. Shulezho,
Ukr. Khim. Zhu.
, 40, 625-629 (1974); F. S. Babichev, N. N. Romanov, Y. L. Slominskii, A. I. Tolmachev,
Ukr. Khim. Zhu.
,40, 1165-1170 (1975); Y. L. Slominskii, A. V. Kuleshin, A. I. Tolmachev,
Zhu. Org. Khim.
, 6, 1936-1940 (1970); Y. L. Slominskii, A. L. Skul′biden
Hendrickx Eric
Kippelen Bernard
Marder Seth R.
Peyghambarian Nasser
Volodin Boris
California Institute of Technology
McCutchen Doyle Brown & Enersen LLP
Tucker Philip
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