JPWO2011111607A1 - Circularly polarized light-emitting rare earth complex - Google Patents
Circularly polarized light-emitting rare earth complex Download PDFInfo
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- JPWO2011111607A1 JPWO2011111607A1 JP2012504424A JP2012504424A JPWO2011111607A1 JP WO2011111607 A1 JPWO2011111607 A1 JP WO2011111607A1 JP 2012504424 A JP2012504424 A JP 2012504424A JP 2012504424 A JP2012504424 A JP 2012504424A JP WO2011111607 A1 JPWO2011111607 A1 JP WO2011111607A1
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- Prior art keywords
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- rare earth
- circularly polarized
- polarized light
- complex
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Classifications
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- C07C49/00—Ketones; Ketenes; Dimeric ketenes; Ketonic chelates
- C07C49/04—Saturated compounds containing keto groups bound to acyclic carbon atoms
- C07C49/10—Methyl-ethyl ketone
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07C—ACYCLIC OR CARBOCYCLIC COMPOUNDS
- C07C49/00—Ketones; Ketenes; Dimeric ketenes; Ketonic chelates
- C07C49/92—Ketonic chelates
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07D—HETEROCYCLIC COMPOUNDS
- C07D413/00—Heterocyclic compounds containing two or more hetero rings, at least one ring having nitrogen and oxygen atoms as the only ring hetero atoms
- C07D413/14—Heterocyclic compounds containing two or more hetero rings, at least one ring having nitrogen and oxygen atoms as the only ring hetero atoms containing three or more hetero rings
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07D—HETEROCYCLIC COMPOUNDS
- C07D471/00—Heterocyclic compounds containing nitrogen atoms as the only ring hetero atoms in the condensed system, at least one ring being a six-membered ring with one nitrogen atom, not provided for by groups C07D451/00 - C07D463/00
- C07D471/02—Heterocyclic compounds containing nitrogen atoms as the only ring hetero atoms in the condensed system, at least one ring being a six-membered ring with one nitrogen atom, not provided for by groups C07D451/00 - C07D463/00 in which the condensed system contains two hetero rings
- C07D471/04—Ortho-condensed systems
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Abstract
本発明に係る円偏光発光性希土類錯体は、不斉ビスオキサゾリンピリジン骨格を有する配位子とアセチルアセトン誘導体から成る配位子が希土類イオンに配位して成ることを特徴とし、例えば一般式(5)(式中、Ln(III)は3価の希土類イオンを、Xは同一又は異なる水素原子、重水素原子、ハロゲン原子、C1〜C20の基、水酸基、ニトロ基、アミノ基、スルホニル基、シアノ基、ホスホン酸基、ジアゾ基、メルカプト基のいずれかを、Y及びZは5員の芳香族複素環を形成するのに必要な原子群を、R1及びR2はそれぞれ同一又は異なるC1〜C20の基、水酸基、ニトロ基、アミノ基、スルホニル基、シアノ基、ホスホン酸基、ジアゾ基、メルカプト基のいずれかを表す。)で表される。The circularly polarized light-emitting rare earth complex according to the present invention is characterized in that a ligand having an asymmetric bisoxazolinepyridine skeleton and a ligand composed of an acetylacetone derivative are coordinated to a rare earth ion. (Wherein Ln (III) is a trivalent rare earth ion, X is the same or different hydrogen atom, deuterium atom, halogen atom, C1 to C20 group, hydroxyl group, nitro group, amino group, sulfonyl group, cyano group) Any one of a group, a phosphonic acid group, a diazo group, and a mercapto group, Y and Z are atomic groups necessary to form a 5-membered aromatic heterocyclic ring, and R1 and R2 are the same or different C1-C20 Group, a hydroxyl group, a nitro group, an amino group, a sulfonyl group, a cyano group, a phosphonic acid group, a diazo group, or a mercapto group.
Description
本発明は、円偏光発光を示す希土類錯体及びそれを利用した光機能材料及びセキュリティー技術に関する。 The present invention relates to a rare earth complex exhibiting circularly polarized light emission, an optical functional material using the same, and a security technique.
近年、光通信技術、光記録をはじめとするIT技術、光を用いた材料の作製・計測・評価技術、光の医療への応用、更には光エネルギーの他のエネルギーへの変換など、光を利用した技術が重要になっている。そこで、光をより有効に活用するために、より高性能な光学機能材料の開発が求められている。このような光学機能材料の一つに希土類錯体がある。希土類錯体は、非線形光学素子、光記録材料、発光材料、イムノアッセイなどの分析・測定用に用いられる標識剤(ラベリング剤)、センシング材料及びセキュリティー材料など種々の分野において、光機能材料として利用可能な化合物である。 In recent years, optical communication technology, IT technology including optical recording, production / measurement / evaluation technology of materials using light, application of light to medical treatment, and further conversion of light energy into other energy The technology used is important. Therefore, in order to utilize light more effectively, development of a higher performance optical functional material is required. One such optical functional material is a rare earth complex. Rare earth complexes can be used as optical functional materials in various fields such as non-linear optical elements, optical recording materials, luminescent materials, labeling agents (labeling agents) used for analysis and measurement such as immunoassays, sensing materials and security materials. A compound.
例えば、BINAPOをはじめとするビナフチル構造配位子とfacam誘導体の両方が希土類イオンに配位した希土類錯体、TPPOをはじめとするホスフィンオキシド誘導体とfacam誘導体の両方が希土類イオンに配位した希土類錯体が報告されている(特許文献1〜3)。この希土類錯体は、ビナフチル構造配位子やホスフィンオキシド誘導体のジアステレオマー構造に由来する不斉配位子場により、右回りと左回りの円偏光を選択的に吸収することが円偏光二色性スペクトル(CDスペクトル)から示されている。一方、不斉配位子場環境下における希土類錯体は円偏光発光スペクトル(CPLスペクトル)を示すことが報告されている(非特許文献1)。 For example, rare earth complexes in which both binaphthyl ligands such as BINAPO and facam derivatives are coordinated to rare earth ions, and rare earth complexes in which both phosphine oxide derivatives such as TPPO and facam derivatives are coordinated to rare earth ions are available. It has been reported (Patent Documents 1 to 3). This rare earth complex selectively absorbs clockwise and counterclockwise circularly polarized light by the asymmetric ligand field derived from the diastereomeric structure of binaphthyl structure ligands and phosphine oxide derivatives. It is shown from the sex spectrum (CD spectrum). On the other hand, rare earth complexes in an asymmetric ligand field environment have been reported to exhibit a circularly polarized light emission spectrum (CPL spectrum) (Non-patent Document 1).
分子の円偏光発光特性はg値(異方性因子)で示すことができる。g値は次のように定義される値である。
CDスペクトルからのg値=Δε/ε=2(εL−εR)/(εL+εR)
(式中、εLは左回りの円偏光における吸収係数、εRは右回りの円偏光における吸収係数を表す。)
CPLスペクトルからのg値=ΔI/I=2(IL−IR)/(IL+IR)
(式中、ILは左回りの円偏光発光強度、IRは右回りの円偏光発光強度を表す。)The circularly polarized light emission characteristic of a molecule can be shown by g value (anisotropy factor). The g value is a value defined as follows.
G value from CD spectrum = Δε / ε = 2 (ε L −ε R ) / (ε L + ε R )
(In the formula, ε L represents an absorption coefficient in counterclockwise circularly polarized light, and ε R represents an absorption coefficient in clockwise circularly polarized light.)
G value from the CPL spectrum = ΔI / I = 2 (I L -I R) / (I L + I R)
(Wherein, I L is circularly polarized luminescence intensity counterclockwise, I R represents a circularly polarized luminescence intensity of clockwise.)
従来の有機化合物のCPLスペクトルにおけるg値は0.001(0.1%)である。これに対して、ビナフチル構造配位子とfacam誘導体の両方が配位した希土類錯体のg値は0.01(1%)程度であり、ホスフィンオキシド誘導体とfacam誘導体の両方が配位した希土類錯体のg値は0.44(44%)であることが報告されている。従って、これら希土類錯体のg値は従来の有機化合物のg値に比較すると格段に高く、円偏光発光特性に優れているといえる。 The g value in the CPL spectrum of a conventional organic compound is 0.001 (0.1%). In contrast, the g value of the rare earth complex coordinated by both the binaphthyl structure ligand and the facam derivative is about 0.01 (1%), and the g value of the rare earth complex coordinated by both the phosphine oxide derivative and the facam derivative. The value is reported to be 0.44 (44%). Therefore, the g value of these rare earth complexes is much higher than the g value of conventional organic compounds, and it can be said that they are excellent in circularly polarized light emission characteristics.
しかし、上述した希土類錯体は円偏光発光性に優れるものの、励起光(紫外光)を照射したときの発光強度が低い。希土類錯体を光機能材料として用いるためには、円偏光発光性だけでなく、発光強度が大きいことが求められる。特に、大きなg値を示し、且つ発光強度が大きい希土類錯体は、円偏光発光を利用したセキュリティー材料、センサー、円偏光光源など様々な応用への展開が期待される。 However, although the rare earth complex described above is excellent in circularly polarized light emission, the emission intensity when irradiated with excitation light (ultraviolet light) is low. In order to use a rare earth complex as an optical functional material, not only circularly polarized light emission property but also high emission intensity is required. In particular, a rare earth complex having a large g value and a high emission intensity is expected to be developed into various applications such as security materials, sensors, and circularly polarized light sources using circularly polarized light emission.
本発明が解決しようとする課題は、円偏光発光性を有し、且つ発光強度が大きい希土類錯体を提供することである。 The problem to be solved by the present invention is to provide a rare earth complex having circularly polarized light emission and high emission intensity.
上記課題を解決するために成された本発明に係る円偏光発光性希土類錯体は、不斉ビスオキサゾリンピリジン骨格を有する配位子とアセチルアセトン誘導体から成る配位子が希土類イオンに配位して成ることを特徴とする。 The circularly polarized light-emitting rare earth complex according to the present invention, which has been made to solve the above problems, comprises a ligand having an asymmetric bisoxazolinepyridine skeleton and a ligand composed of an acetylacetone derivative coordinated to a rare earth ion. It is characterized by that.
アセチルアセトン誘導体は光増感機能を有する配位子として知られている。「光増感機能」とは、照射されたエネルギーを効率よく希土類イオンに移動させて当該希土類イオンを増感発光させることができる機能をいう。アセチルアセトン誘導体には種々のものが知られており、例えば一般式(1)
で表されるものや、一般式(2)
で表されるものが挙げられる。上記の一般式(2)で表されるアセチルアセトン誘導体はカンファー誘導体としても知られている。An acetylacetone derivative is known as a ligand having a photosensitizing function. The “photosensitizing function” refers to a function capable of efficiently transferring emitted energy to rare earth ions to cause the rare earth ions to sensitize light. Various acetylacetone derivatives are known. For example, the general formula (1)
Or the general formula (2)
The thing represented by is mentioned. The acetylacetone derivative represented by the above general formula (2) is also known as a camphor derivative.
また、アセチルアセトン誘導体の具体例として、化学式(3)
また、本発明の円偏光発光性希土類錯体は、一般式(4)
で表される希土類錯体を用いることができる。The circularly polarized light-emitting rare earth complex of the present invention has the general formula (4)
The rare earth complex represented by these can be used.
上記希土類イオンはNd、Sm、Eu、Tb、Ybのいずれかのイオンであることが好ましく、特に好ましくはEu又はTbである。 The rare earth ions are preferably any of Nd, Sm, Eu, Tb, and Yb, and particularly preferably Eu or Tb.
本発明によれば、円偏光発光性を有し、且つ高い発光特性を有する希土類錯体を提供することができる。 According to the present invention, it is possible to provide a rare earth complex having circularly polarized light emission properties and high light emission characteristics.
希土類錯体とは、希土類元素の2価、3価又は4価のイオンを中心イオンとして、1ないし複数の各種配位子が配位した有機錯体である。このような錯体としては、希土類イオンが他の化学種に取り囲まれてホスト−ゲスト構造をとった包接化合物や、単に中心の希土類イオンに配位子が配位したのみ(希土類イオンが他の化学種に包接されていない)のものがある。包接化合物構造は、一般的に不斉部位が希土類イオンから離れているため、希土類イオンのキラリティの影響が少ない。また、錯体がデルタ体及びデルタ体の光学異性体混合物になる可能性が高く、キラリティの低下が考えられる。このことから、本発明に係る希土類錯体においては、他の化学種に包接されていない錯体構造を採用した。 The rare earth complex is an organic complex in which one or more various ligands are coordinated with a divalent, trivalent or tetravalent ion of a rare earth element as a central ion. Such complexes include clathrate compounds in which the rare earth ions are surrounded by other chemical species and have a host-guest structure, or simply a ligand coordinated to the central rare earth ions (the rare earth ions are Not included in chemical species). The clathrate structure is generally less affected by the chirality of the rare earth ions because the asymmetric sites are separated from the rare earth ions. In addition, there is a high possibility that the complex becomes a delta form and a mixture of optical isomers of the delta form, and a reduction in chirality is considered. For this reason, the rare earth complex according to the present invention employs a complex structure that is not included in other chemical species.
具体的には、本発明に係る希土類錯体は、希土類元素のうち特に3価のイオンを中心イオンとして、不斉ビスオキサゾリンピリジン骨格を有する配位子と、光増感機能を有する配位子が配位した錯体構造を有する。
不斉配位子が希土類錯体に組み込まれることによって、円偏光発光が生じる。円偏光発光は、中心イオンである希土類イオンの4f軌道内での遷移により放射される円偏光成分を有する発光である。希土類イオンの4f軌道は7つある。1つの軌道に最大2個の電子が入るため、4f軌道全体で最大14個の電子が入る。入る電子の個数は希土類イオンの種類によって異なる。Eu3+イオンの場合、4f軌道全体で6個の電子が存在する。上記4f軌道の準位は、通常、結晶場の存在などにより縮退しない。その準位間のエネルギー差に対応した光を照射すれば、4f軌道の準位間における電子の遷移により発光が生じ、尖鋭な発光スペクトルが得られる。上記のような4f軌道の準位間における電子の遷移を、以後f−f遷移と呼ぶ。Specifically, in the rare earth complex according to the present invention, a ligand having an asymmetric bisoxazoline pyridine skeleton with a trivalent ion as a central ion among rare earth elements and a ligand having a photosensitizing function are included. It has a coordinated complex structure.
By incorporating the asymmetric ligand into the rare earth complex, circularly polarized light emission occurs. Circularly polarized light emission is light emission having a circularly polarized light component emitted by a transition in the 4f orbit of a rare earth ion that is a central ion. There are seven 4f orbits of rare earth ions. Since a maximum of two electrons enter one orbit, a maximum of 14 electrons enter the entire 4f orbit. The number of electrons entering depends on the type of rare earth ions. In the case of Eu 3+ ions, there are 6 electrons in the entire 4f orbit. The level of the 4f orbit is not usually degenerated due to the presence of a crystal field. When light corresponding to the energy difference between the levels is irradiated, light emission occurs due to the transition of electrons between the levels of the 4f orbit, and a sharp emission spectrum is obtained. The transition of electrons between the levels of the 4f orbit as described above is hereinafter referred to as ff transition.
一般に希土類元素の特性(イオン半径、配位形態等)は非常に類似しており、従って本発明の円偏光発光性希土類錯体の中心イオンとして、Ce、Pr、Nd、Pm、Sm、Eu、Tb、Dy、Ho、Er、Tm、Ybのいずれかの3価の希土類イオンを用いれば、同様の円偏光発光が得られる。特に、本発明に係る希土類錯体では、中心イオンとしてNd、Sm、Eu、Tb、Ybのいずれかの3価のイオンが好ましく、さらに好ましくはEu又はTbである。なお、中心イオンとしてNd、Ybなどを用いることにより、本発明に係る希土類錯体は近赤外領域での発光を生じる。 In general, the characteristics (ion radius, coordination configuration, etc.) of rare earth elements are very similar. Therefore, Ce, Pr, Nd, Pm, Sm, Eu, Tb are the central ions of the circularly polarized light-emitting rare earth complex of the present invention. If a trivalent rare earth ion of any one of Dy, Ho, Er, Tm, and Yb is used, the same circularly polarized light emission can be obtained. In particular, in the rare earth complex according to the present invention, the trivalent ion of Nd, Sm, Eu, Tb, or Yb is preferable as the central ion, and Eu or Tb is more preferable. By using Nd, Yb or the like as the central ion, the rare earth complex according to the present invention emits light in the near infrared region.
本発明に係る光学機能材料に使用し得る希土類錯体には種々のものが考えられる。前段落に記したように、中心となる希土類イオンだけでも十数種類存在し、それらと不斉配位子との組み合わせは多数存在する。上記の希土類イオンにおける4f軌道の準位間のエネルギー差が周囲の配位子の種類にも依存するため、上記希土類イオンの変化のみならず、配位子の組み合わせを変化させることによっても、様々な波長域の円偏光発光を得ることができる。 Various rare earth complexes that can be used in the optical functional material according to the present invention can be considered. As described in the previous paragraph, there are more than a dozen types of central rare earth ions alone, and there are many combinations of these with asymmetric ligands. Since the energy difference between the levels of the 4f orbitals in the rare earth ions described above also depends on the type of the surrounding ligand, not only changes in the rare earth ions but also changes in the combination of the ligands Circularly polarized light emission in a wide wavelength range can be obtained.
光増感機能を有する配位子には様々なものがあるが、本発明ではアセチルアセトン誘導体を用いた。上記アセチルアセトン誘導体としては、一般式(1)
で表されるものや、以下の一般式(2)
で表されるカンファー誘導体が挙げられる。光増感機能を有する配位子としては上記カンファー誘導体のように、不斉炭素を持つものも選択することができる。Although there are various ligands having a photosensitizing function, an acetylacetone derivative is used in the present invention. As said acetylacetone derivative, general formula (1)
Or the following general formula (2)
The camphor derivative represented by these is mentioned. As a ligand having a photosensitizing function, a ligand having an asymmetric carbon such as the camphor derivative can be selected.
特に、一般式(5)
で表される不斉ビスオキサゾリンピリジン(Bis (oxazolinyl) pyridine)骨格を有する配位子(以下、「ビスオキサゾリンピリジン配位子」、又は略語「pybox」と表記する)とヘキサフルオロアセチルアセトン(hfa)が希土類イオンに配位した希土類錯体は優れた円偏光発光性を有し、且つ高い発光特性を有する。これは、pyboxの2箇所のオキサゾリン環と各hfaのフッ化炭素基(-CF3)の間で化学的なインターラクション(π-π相互作用)が働き、希土類錯体の結晶構造に不斉を誘起するようなゆがみを与えることによると思われる。In particular, the general formula (5)
A ligand having an asymmetric bisoxazolinepyridine (Bis (oxazolinyl) pyridine) skeleton represented by the formula (hereinafter referred to as “bisoxazolinepyridine ligand” or abbreviation “pybox”) and hexafluoroacetylacetone (hfa) Rare earth complexes coordinated to rare earth ions have excellent circularly polarized light emission properties and high emission characteristics. This is because chemical interaction (π-π interaction) works between the two oxazoline rings of pybox and the fluorocarbon group (-CF 3 ) of each hfa, and the crystal structure of the rare earth complex is asymmetric. It seems to be due to the inducing distortion.
上記のような相互作用を得るためには、ビスオキサゾリンピリジン配位子について、一般式(5)中、R2がイソプロピル基、フェニル基などの比較的かさ高いものを選択することが好ましい。この場合、ビスオキサゾリンピリジン配位子の2箇所のオキサゾリン環に結合するそれぞれのR2が異なる官能基であってもよい。
以下、本発明に係る希土類錯体(Ln(III)錯体)の具体的な実施例について述べる。In order to obtain the interaction as described above, it is preferable to select a bisoxazoline pyridine ligand in which R 2 is relatively bulky such as isopropyl group and phenyl group in the general formula (5). In this case, each R 2 bonded to the two oxazoline rings of the bisoxazoline pyridine ligand may be a different functional group.
Specific examples of the rare earth complex (Ln (III) complex) according to the present invention will be described below.
1.Ln(III)錯体の合成
図1に示す合成手順に従いLn(III)錯体を合成した。図1及び以下の説明では、LnはEu(ユーロピウム)又はTb(テルビウム)を示し、Meはメチル基を示す。また、Phはフェニル基、iPrはイソプロピル基を示す。
まず、pybox系配位子を1等量、及びLn(hfa)3(H2O2)2 1.2等量をMeOHに溶かし、80℃で8時間加熱還流を行った。減圧下でMeOHを留去した後、得られた固体をクロロホルムで洗い、不純物(未反応のLn(hfa)3(H2O2)2 )をろ過により取り除いた。ろ液中の溶媒を留去し、黄白色の粉末を得た。メタノールで再結晶を行うことで無色の結晶を得た。1. Synthesis of Ln (III) Complex An Ln (III) complex was synthesized according to the synthesis procedure shown in FIG. In FIG. 1 and the following description, Ln represents Eu (europium) or Tb (terbium), and Me represents a methyl group. Ph represents a phenyl group, and iPr represents an isopropyl group.
First, 1 equivalent of the pybox ligand and 1.2 equivalent of Ln (hfa) 3 (H 2 O 2 ) 2 were dissolved in MeOH, and the mixture was heated to reflux at 80 ° C. for 8 hours. After evaporating MeOH under reduced pressure, the obtained solid was washed with chloroform, and impurities (unreacted Ln (hfa) 3 (H 2 O 2 ) 2 ) were removed by filtration. The solvent in the filtrate was distilled off to obtain a yellowish white powder. Colorless crystals were obtained by recrystallization from methanol.
2.Ln(III)錯体の同定
得られた無色の結晶をESI-Mass(エレクトロスプレー質量分析)及びX線結晶構造解析で同定した。ESI-MASSは日本電子株式会社(JEOL)製のJMS-700、MStationを用いた。また、X線結晶構造解析は株式会社リガク製の有機低分子X線構造解析装置(Rapid)を用いた。
ESI-MASSの結果を以下に示す。2. Identification of Ln (III) Complex The colorless crystals obtained were identified by ESI-Mass (electrospray mass spectrometry) and X-ray crystal structure analysis. ESI-MASS used JMS-700 and MStation manufactured by JEOL Ltd. (JEOL). The X-ray crystal structure analysis was performed using an organic low-molecular X-ray structure analyzer (Rapid) manufactured by Rigaku Corporation.
The results of ESI-MASS are shown below.
(1) [(R,R)-Ph-pybox]Eu(hfa-H)3錯体及び[(S,S)-Ph-pybox]Eu(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C33H21EuF12N3O6 +, 936.04542、found, 936.04466
(2) [(R,R)-iPr-pybox]Eu(hfa-H)3錯体及び[(S,S)-iPr-pybox]Eu(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C27H25EuF12N3O6 +, 868.07663、found, 868.07707
(3) [(R,R)-Me-Ph-pybox]Eu(hfa-H)3錯体及び[(S,S)-Me-Ph-pybox]Eu(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C35H25EuF12N3O6 +, 964.07675、found, 964.07681
(4) [(R,R)-Ph-pybox]Tb(hfa-H)3錯体及び[(S,S)-Ph-pybox]Tb(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C33H21F12N3O6Tb+, 942.04922、found, 942.04901
(5) [(R,R)-iPr-pybox]Tb(hfa-H)3錯体及び[(S,S)-iPr-pybox]Tb(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C27H25F12N3O6Tb+, 874.08052、found, 874.08060
(6) [(R,R)-Me-Ph-pybox]Tb(hfa-H)3錯体及び[(S,S)-Me-Ph-pybox]Tb(hfa-H)3錯体
ESI-MASS(m/z):[M-(hfa)]+ calcd. for C35H25F12N3O6Tb+, 970.08052、found, 970.08062(1) [(R, R) -Ph-pybox] Eu (hfa-H) 3 complex and [(S, S) -Ph-pybox] Eu (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 33 H 21 EuF 12 N 3 O 6 + , 936.04542, found, 936.04466
(2) [(R, R) -iPr-pybox] Eu (hfa-H) 3 complex and [(S, S) -iPr-pybox] Eu (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 27 H 25 EuF 12 N 3 O 6 + , 868.07663, found, 868.07707
(3) [(R, R) -Me-Ph-pybox] Eu (hfa-H) 3 complex and [(S, S) -Me-Ph-pybox] Eu (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 35 H 25 EuF 12 N 3 O 6 + , 964.07675, found, 964.07681
(4) [(R, R) -Ph-pybox] Tb (hfa-H) 3 complex and [(S, S) -Ph-pybox] Tb (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 33 H 21 F 12 N 3 O 6 Tb + , 942.04922, found, 942.04901
(5) [(R, R) -iPr-pybox] Tb (hfa-H) 3 complex and [(S, S) -iPr-pybox] Tb (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 27 H 25 F 12 N 3 O 6 Tb + , 874.08052, found, 874.08060
(6) [(R, R) -Me-Ph-pybox] Tb (hfa-H) 3 complex and [(S, S) -Me-Ph-pybox] Tb (hfa-H) 3 complex
ESI-MASS (m / z): [M- (hfa)] + calcd. For C 35 H 25 F 12 N 3 O 6 Tb + , 970.08052, found, 970.08062
また、12種類のLn(III)錯体のX線結晶構造解析の結果を図3A及び図3Bに示す。
ESI-MASSの結果及びX線結晶構造解析の結果から、得られた結晶はそれぞれ図2A及び図2Bに示す12種類のLn(III)錯体であるといえる。The results of X-ray crystal structure analysis of 12 types of Ln (III) complexes are shown in FIGS. 3A and 3B.
From the results of ESI-MASS and the results of X-ray crystal structure analysis, it can be said that the obtained crystals are 12 types of Ln (III) complexes shown in FIGS. 2A and 2B, respectively.
3.各Ln(III)錯体の発光量子収率
各Ln(III)錯体の発光量子収率を求めるために、吸収スペクトル及び発光スペクトルを測定した。吸収スペクトルの測定には日本分光株式会社製の紫外可視分光光度計(JASCO-V660)、発光スペクトルの測定には日立製作所製の分光蛍光光度計(HITACHI F-4500)を用いた。吸収スペクトル及び発光スペクトルの測定は、各Ln(III)錯体の重アセトニトリル溶液(1.0×10-2M)を調製し、溶存酸素による消光を防ぐためにArバブリングを10分間行った後、測定した。励起波長は465nm(Eu(III)錯体),487nm(Tb(III)錯体)に設定した。各Ln(III)錯体の吸収スペクトル及び発光スペクトルをそれぞれ図4及び図5に示す。3. Luminescence quantum yield of each Ln (III) complex In order to obtain the luminescence quantum yield of each Ln (III) complex, an absorption spectrum and an emission spectrum were measured. An ultraviolet-visible spectrophotometer (JASCO-V660) manufactured by JASCO Corporation was used for the measurement of the absorption spectrum, and a spectrofluorophotometer (HITACHI F-4500) manufactured by Hitachi, Ltd. was used for the measurement of the emission spectrum. The absorption spectrum and emission spectrum were measured after preparing a deuterated acetonitrile solution (1.0 × 10 −2 M) of each Ln (III) complex and carrying out Ar bubbling for 10 minutes to prevent quenching by dissolved oxygen. The excitation wavelength was set to 465 nm (Eu (III) complex) and 487 nm (Tb (III) complex). The absorption spectrum and emission spectrum of each Ln (III) complex are shown in FIGS. 4 and 5, respectively.
得られた吸収スペクトル及び発光スペクトルから各Ln(III)錯体の発光量子収率(Φ%)を求めた。発光量子収率はJASCO V-660を用い、絶対法により求めた。各Ln(III)錯体の発光量子収率を図6及び図7に示す。図6及び図7から本実施例に係るLn(III)錯体はいずれも優れた発光量子収率を示し、特にEu(III)錯体については非常に高い発光量子収率を示した。 The emission quantum yield (Φ%) of each Ln (III) complex was determined from the obtained absorption spectrum and emission spectrum. The emission quantum yield was determined by the absolute method using JASCO V-660. The luminescence quantum yield of each Ln (III) complex is shown in FIGS. 6 and 7, all of the Ln (III) complexes according to this example showed excellent luminescence quantum yields, and particularly the Eu (III) complex showed very high luminescence quantum yields.
4.Ln(III)錯体の円偏光性
各Ln(III)錯体の円偏光性を調べるために、円偏光二色性スペクトル(CDスペクトル)及び円偏光発光スペクトル(CPLスペクトル)を測定した。CDスペクトル及びCPLスペクトルは、各Ln(III)錯体の重アセトニトリル溶液(1.0×10-2M)を調製し、Arバブリングを10分間行った後、測定した。
各Ln(III)錯体のCDスペクトル及びCPLスペクトルを図8及び図9に示す。4). Circular polarization of Ln (III) complex In order to examine the circular polarization of each Ln (III) complex, a circular dichroism spectrum (CD spectrum) and a circular polarization emission spectrum (CPL spectrum) were measured. CD spectra and CPL spectra were measured after preparing a heavy acetonitrile solution (1.0 × 10 −2 M) of each Ln (III) complex and carrying out Ar bubbling for 10 minutes.
The CD spectrum and CPL spectrum of each Ln (III) complex are shown in FIGS.
図9に示すCPLスペクトルの結果を基に、以下の式を用いてg値を計算した。なお、発光バンドの存在しない波長域での値は無視した。
g値=ΔI/I=2(IL−IR)/(IL+IR)
(式中、ILは左回りの円偏光発光強度、IRは右回りの円偏光発光強度を表す。)
g値の計算結果を図10及び図11に示す。
図10及び図11から明らかなように、本実施例のLn(III)錯体は円偏光発光を示す。特に、Eu(III)錯体については発光波長が594nmにおけるg値(絶対値)は0.13〜0.5(13%〜50%)であり、いずれも高かった。なお、発光波長が615nmにおけるg値(絶対値)は0.019〜0.035(1.9%〜3.5%)であった。Based on the result of the CPL spectrum shown in FIG. 9, the g value was calculated using the following formula. Note that the value in the wavelength region where no emission band exists was ignored.
g value = ΔI / I = 2 (I L -I R) / (I L + I R)
(Wherein, I L is circularly polarized luminescence intensity counterclockwise, I R represents a circularly polarized luminescence intensity of clockwise.)
The calculation results of the g value are shown in FIGS.
As is clear from FIGS. 10 and 11, the Ln (III) complex of this example exhibits circularly polarized light emission. In particular, the Eu (III) complex had a g value (absolute value) at an emission wavelength of 594 nm of 0.13 to 0.5 (13% to 50%), both of which were high. The g value (absolute value) at an emission wavelength of 615 nm was 0.019 to 0.035 (1.9% to 3.5%).
テルビウムは緑色の波長領域に発光を示し、ユーロピウムは赤色の波長領域に発光を示す。そこで、実施例1で得られたEu(III)錯体とTb(III)錯体の混合溶液を調製し、その発光を確認した。
混合溶液は、アセトニトリル2mLに、1mMのEu(III)錯体アセトニトリル溶液約20μL、10mMのTb(III)錯体アセトニトリル溶液200μLを加えて作製した。Terbium emits light in the green wavelength region, and europium emits light in the red wavelength region. Therefore, a mixed solution of the Eu (III) complex and Tb (III) complex obtained in Example 1 was prepared, and the luminescence was confirmed.
The mixed solution was prepared by adding about 20 μL of a 1 mM Eu (III) complex acetonitrile solution and 200 μL of a 10 mM Tb (III) complex acetonitrile solution to 2 mL of acetonitrile.
図12に、Eu(III)錯体及びTb(III)錯体の各溶液の添加量、混合溶液を波長365nmで励起したときの発光の色度座標(x,y)(計算値)を示す。以下では、これら混合溶液を図12の左端に示した白抜き数字の番号を付して混合溶液1〜9と称する。図13に混合溶液1〜9の蛍光発光スペクトルを、図14〜図16に各混合溶液1〜9のCDスペクトル及びCPLスペクトルを示す。 FIG. 12 shows the addition amount of each solution of Eu (III) complex and Tb (III) complex, and chromaticity coordinates (x, y) (calculated values) of light emission when the mixed solution is excited at a wavelength of 365 nm. Hereinafter, these mixed solutions are referred to as mixed solutions 1 to 9 with the white numbers shown at the left end of FIG. FIG. 13 shows fluorescence emission spectra of the mixed solutions 1 to 9, and FIGS. 14 to 16 show CD spectra and CPL spectra of the mixed solutions 1 to 9, respectively.
各混合溶液1〜9は、波長365nmで励起すると黄色の発光を示した。また、その色度座標(計算値)は、図17の色度図において丸(○)で印を付けた領域内に位置する。従って、色度座標からも、混合溶液1〜9が黄色の発光を示すことがわかる。
また、図14〜図16から、混合溶液1〜9はいずれもの円偏光特性を示すことが分かる。Each of the mixed solutions 1 to 9 emitted yellow light when excited at a wavelength of 365 nm. Further, the chromaticity coordinates (calculated values) are located in the region marked with a circle (◯) in the chromaticity diagram of FIG. Therefore, it can be seen from the chromaticity coordinates that the mixed solutions 1 to 9 emit yellow light.
Moreover, from FIGS. 14-16, it turns out that the mixed solutions 1-9 show all the circular polarization characteristics.
上述したように実施例2で得られた混合溶液1〜9はいずれも紫外光で励起したとき黄色の発光を示す。そこで、紫外光を照射したときに青色の発光を示す有機化合物であるアントラセンを前記混合溶液1〜9に添加し、白色の発光を示す溶液を調製した。溶液の調製は、混合溶液1〜9を約2070μLにアントラセン溶液(0.05mM)を約10μL添加することで行った。 As described above, the mixed solutions 1 to 9 obtained in Example 2 all emit yellow light when excited with ultraviolet light. Accordingly, anthracene, which is an organic compound that emits blue light when irradiated with ultraviolet light, was added to the mixed solutions 1 to 9 to prepare a solution that emitted white light. The solution was prepared by adding about 10 μL of the anthracene solution (0.05 mM) to about 2070 μL of the mixed solutions 1-9.
図18に各混合溶液1〜9に添加したアントラセンの量、アントラセン添加後の混合溶液(以下、混合溶液11〜19と呼ぶ)を波長360nmで励起したときの発光の色度座標(x,y)(計算値)を示す。また、図19に混合溶液11〜19の発光スペクトルを示す。 FIG. 18 shows the amount of anthracene added to each of the mixed solutions 1 to 9, and the chromaticity coordinates (x, y) of light emitted when the mixed solution after the addition of anthracene (hereinafter referred to as mixed solutions 11 to 19) is excited at a wavelength of 360 nm. ) (Calculated value). FIG. 19 shows emission spectra of the mixed solutions 11-19.
各混合溶液11〜19を波長360nmで励起すると、白色の発光を示した。また、図18に示す色度座標の値から明らかなように、本実施例に係る混合溶液11〜19は白色の発光を示すことが分かる。 When each of the mixed solutions 11 to 19 was excited at a wavelength of 360 nm, white light was emitted. Further, as is apparent from the values of the chromaticity coordinates shown in FIG. 18, it can be seen that the mixed solutions 11 to 19 according to the present example emit white light.
実施例2で得られた混合溶液をシクロオレフィンポリマー樹脂(商品名「ゼオネックス(ZEONEX)」(登録商標)、日本ゼオン株式会社)に均一に分散させ、樹脂成形体を作製した。この樹脂成形体を加熱、或いは冷却して紫外光を照射し、そのときの発光色を調べた。図20に、-20℃に冷却したとき、室温、60℃に加熱したときの発光の様子を示す。 The mixed solution obtained in Example 2 was uniformly dispersed in a cycloolefin polymer resin (trade name “ZEONEX” (registered trademark), Nippon Zeon Co., Ltd.) to prepare a resin molded body. The resin molding was heated or cooled and irradiated with ultraviolet light, and the emission color at that time was examined. FIG. 20 shows the state of light emission when cooled to −20 ° C. and heated to room temperature and 60 ° C.
図20に示すように、室温では黄色の発光を示したのに対して、-20℃に冷却したときは緑色の発光を示し、60℃に加熱したときは赤色の発光を示した。このことから、温度が低いときは、テルビウムの発光色が強く表れ、温度が高いときはユーロピウムの発光色が強く表れるものと思われる。なお、加熱による温度変化には可逆性があり、60℃に加熱後あるいは-20℃に冷却後、室温に戻った樹脂形成体は黄色の発光を示した。
このように、Eu(III)錯体とTb(III)錯体の混合溶液を用いて作製した樹脂成形体は、温度を変化させることにより、紫外光を照射したときに発光する色調を変化させることができる。また、Eu(III)錯体とTb(III)錯体の混合比を変化させることによって、発光する色調が変化する温度が異なることも確認した。As shown in FIG. 20, yellow light was emitted at room temperature, while green light was emitted when cooled to −20 ° C., and red light was emitted when heated to 60 ° C. From this, it is considered that when the temperature is low, the emission color of terbium appears strongly, and when the temperature is high, the emission color of europium appears strongly. The temperature change due to heating was reversible, and the resin formed body that returned to room temperature after heating to 60 ° C. or cooling to −20 ° C. showed yellow light emission.
As described above, the resin molded body produced using the mixed solution of the Eu (III) complex and the Tb (III) complex can change the color tone emitted when irradiated with ultraviolet light by changing the temperature. it can. In addition, it was also confirmed that the temperature at which the color tone of light emission changes varies by changing the mixing ratio of the Eu (III) complex and the Tb (III) complex.
本発明に係る希土類錯体のうち、光増感機能を有する配位子としてカンファー誘導体を採用した実施例について、以下詳細に述べる。 Among the rare earth complexes according to the present invention, examples in which camphor derivatives are employed as ligands having a photosensitizing function will be described in detail below.
本実施例における希土類錯体は、Euに不斉ビスオキサゾリンピリジン骨格又はフェナントロリン骨格を有する配位子を採用し、さらに光増感機能を有する配位子として、一般式(2)
1.Eu(facam)3錯体の合成
図21(a)、(b)、(c)及び(d)に示す計4種の合成手順に従い、Eu(facam)3錯体の結晶(1)、(2)、(3)及び(4)を得た。
まず図21(a)に示す[Eu(D-facam)3](0.43g、0.46mmol)及びR-iPr-Pybox(0.14g、0.46mmol)をメタノール(50mL)に溶解させ、還流条件下、12時間撹拌した。反応溶液をろ過した後数日静置し、黄色の菱形結晶(1)を得た。収率は46%であった。
図21(b)においては上記と同じ手法を用いた。R-iPr-Pyboxの替わりにS-iPr-Pybox(0.14g、0.46mmol)を用い、黄色の菱形結晶(2)を得た。収率は34%であった。
さらに図21(c)に示す[Eu(D-facam)3](0.26g、0.29mmol)及びR,R-Me-Ph-Pybox(0.12g、0.29mmol)を予め攪拌子を入れたナス型フラスコに加え、アセトニトリル(20mL)、MeOH(20mL)の順に溶媒を加え溶解させた。この溶液を還流条件下、12時間撹拌させた。反応溶液をろ過し数日静置し、黄色の板状結晶(3)を得た。収率は73%であった。
最後に図21(d)においては図21(a)と同じ手法を用いた。R-iPr-Pyboxの替わりに1,10-Phenanthroline・一水和物(0.045g、0.26mmol)を用い、[Eu(D-facam)3](0.21g、0.23mmol)と反応させ黄色の菱形結晶(4)を得た。収率は72%であった。
なお、いずれの合成手順においても、試薬はナカライテスク、和光純薬工業、東京化成工業、Aldrich、CILより購入した。溶媒は適宜蒸留したものを用いた。1. Eu (facam) 3 complexes synthesized Figure 21 (a), (b), (c) and in accordance with a total of 4 kinds of synthetic procedures shown in (d), Eu (facam) 3 complexes of the crystal (1), (2) , (3) and (4) were obtained.
First, [Eu (D-facam) 3 ] (0.43 g, 0.46 mmol) and R-iPr-Pybox (0.14 g, 0.46 mmol) shown in FIG. 21 (a) were dissolved in methanol (50 mL). Stir for 12 hours. The reaction solution was filtered and allowed to stand for several days to obtain yellow rhomboid crystals (1). The yield was 46%.
In FIG. 21 (b), the same method as described above was used. S-iPr-Pybox (0.14 g, 0.46 mmol) was used instead of R-iPr-Pybox to obtain yellow rhombus crystals (2). The yield was 34%.
Furthermore, [Eu (D-facam) 3 ] (0.26 g, 0.29 mmol) and R, R-Me-Ph-Pybox (0.12 g, 0.29 mmol) shown in FIG. To the flask, a solvent was added and dissolved in the order of acetonitrile (20 mL) and MeOH (20 mL). The solution was allowed to stir for 12 hours under reflux conditions. The reaction solution was filtered and allowed to stand for several days to obtain yellow plate crystals (3). The yield was 73%.
Finally, in FIG. 21 (d), the same technique as in FIG. 21 (a) was used. Use 1,10-Phenanthroline monohydrate (0.045g, 0.26mmol) instead of R-iPr-Pybox and react with [Eu (D-facam) 3 ] (0.21g, 0.23mmol) to form a yellow diamond Crystal (4) was obtained. The yield was 72%.
In each synthesis procedure, reagents were purchased from Nacalai Tesque, Wako Pure Chemical Industries, Tokyo Chemical Industry, Aldrich, and CIL. The solvent used was appropriately distilled.
2.Eu(facam)3錯体の同定
上記計4種の合成手順によって得られた黄色の結晶(1)、(2)、(3)及び(4)をESI-Mass(エレクトロスプレー質量分析)、NMR分析、FT-IR分析、元素分析及び単結晶X線結晶構造解析で同定した。ESI-MASSは日本電子株式会社(JEOL)製のJMS-700を、NMRは同じく日本電子株式会社(JEOL)製のAL-300(1H-NMR、300MHz)を、FT-IR分析は日本分光株式会社製のFT/IR-4200を、元素分析はPerkin Elmer社の2400IIを、単結晶X線結晶構造解析は株式会社リガク製のRigaku Valimax RAPID RA-Macro7HFMを用いた。2. Identification of Eu (facam) 3 complex ESI-Mass (electrospray mass spectrometry) and NMR analysis of yellow crystals (1), (2), (3) and (4) obtained by the above four synthetic procedures , FT-IR analysis, elemental analysis and single crystal X-ray crystal structure analysis. ESI-MASS the JMS-700 manufactured by JEOL Ltd. (JEOL) is, NMR is also JEOL Ltd. of (JEOL) AL-300 (1 H-NMR, 300MHz) a, FT-IR analysis JASCO FT / IR-4200 manufactured by Co., Ltd., 2400II manufactured by Perkin Elmer were used for elemental analysis, and Rigaku Valimax RAPID RA-Macro7HFM manufactured by Rigaku Co., Ltd. was used for single crystal X-ray crystal structure analysis.
ESI-MASSの結果を以下に示す。
結晶(1) ESI-MS(ESI+): 946.288([M-(D-facam)]+) m/z.
結晶(2) ESI-MS(ESI+): 946.288([M-(D-facam)]+) m/z.
結晶(3) ESI-MS(ESI+): 1042.288([M-(D-facam)]+) m/z.
結晶(4) ESI-MS(ESI+): 825.177([M-(D-facam)]+) m/z.The results of ESI-MASS are shown below.
Crystal (1) ESI-MS (ESI + ): 946.288 ([M- (D-facam)] + ) m / z.
Crystal (2) ESI-MS (ESI + ): 946.288 ([M- (D-facam)] + ) m / z.
Crystal (3) ESI-MS (ESI + ): 1042.288 ([M- (D-facam)] + ) m / z.
Crystal (4) ESI-MS (ESI + ): 825.177 ([M- (D-facam)] + ) m / z.
NMR分析(1H-NMR)の結果を以下に示す。なお、測定試料調製用の溶媒として重水素化クロロホルムを使用した。括弧の前の数字はケミカルシフト(ppm)を、括弧内のアルファベットはスペクトルの多重線形状を示す。
結晶(1) 1H-NMR(CDCl3, 300MHz, 298K) δ: 12.6-11.0(br), 9.0-7.6(br), 6.8-5.8(br), 1.89(br), -1.0 - -2.2(br), -2.8 - -3.4(br), -3.8 - -5.0(br)
結晶(2) 1H-NMR(CDCl3, 300MHz, 298K) δ: 9.2-7.8(br), 6.6-5.6(br), 2.04(s, br), -0.4 - -2.0(br), -3.0 - -4.0(br)
結晶(3) 1H-NMR(CDCl3, 300MHz, 298K) δ: 12.0-11.2(s, br), 9.03(s, br), 8.5-7.8(br), 7.7-7.4(d, br), 2.6-2.0(br), 1.5-0.5(br), -1.39(br), -1.78(br), -2.61(br), -3.36(br), -4.64(br)
結晶(4)(括弧内のアルファベットはスペクトルの多重線形状並びに対応するプロトン数を示す)1H-NMR(CDCl3, 300MHz, 298K) δ: 10.49(d, Aromatic, 2H), 10.23(s, Ar, 2H), 7.97(d, Ar, 2H), 4.92(s, Ar, 2H), 2.56(s, 3H), 2.06(s, 9H), 1.23(t, 3H), 0.52(t, 3H), -0.09(s, 9H), -0.71(s, 3H), -0.83(s, 9H), -1.62(t, 3H)The results of NMR analysis ( 1 H-NMR) are shown below. In addition, deuterated chloroform was used as a solvent for measurement sample preparation. The number before the parenthesis indicates chemical shift (ppm), and the alphabet in the parenthesis indicates the multi-line shape of the spectrum.
Crystal (1) 1 H-NMR (CDCl 3 , 300MHz, 298K) δ: 12.6-11.0 (br), 9.0-7.6 (br), 6.8-5.8 (br), 1.89 (br), -1.0--2.2 ( br), -2.8--3.4 (br), -3.8--5.0 (br)
Crystal (2) 1 H-NMR (CDCl 3 , 300MHz, 298K) δ: 9.2-7.8 (br), 6.6-5.6 (br), 2.04 (s, br), -0.4--2.0 (br), -3.0 --4.0 (br)
Crystal (3) 1 H-NMR (CDCl 3 , 300MHz, 298K) δ: 12.0-11.2 (s, br), 9.03 (s, br), 8.5-7.8 (br), 7.7-7.4 (d, br), 2.6-2.0 (br), 1.5-0.5 (br), -1.39 (br), -1.78 (br), -2.61 (br), -3.36 (br), -4.64 (br)
Crystal (4) (alphabet in parenthesis indicates multi-line shape of spectrum and corresponding proton number) 1 H-NMR (CDCl 3 , 300MHz, 298K) δ: 10.49 (d, Aromatic, 2H), 10.23 (s, Ar, 2H), 7.97 (d, Ar, 2H), 4.92 (s, Ar, 2H), 2.56 (s, 3H), 2.06 (s, 9H), 1.23 (t, 3H), 0.52 (t, 3H) , -0.09 (s, 9H), -0.71 (s, 3H), -0.83 (s, 9H), -1.62 (t, 3H)
FT-IR分析の結果を以下に示す。なお、括弧の前の数値は赤外線の波数(cm-1)を、括弧内のアルファベットは吸収スペクトルの形状、大きさ並びに前記吸収スペクトルに対応する特定基を示す。
結晶(1) FT-IR(ATR): 3010-2810(w, br, C-H), 1651(s, sh, C=O), 1585(w), 1522(s), 1483(w), 1441(w), 1371(m), 1329(m, CF3), 1294(w, CF3), 1267(s, CF3), 1225(s, CF3), 1200(m, CF3), 1182(s, CF3), 1122(s, CF3), 1111(m), 1082(m), 1051(m), 1009(s), 972(m), 922(w), 891(w), 850(w), 829(w), 802(m), 746(m), 714(w), 683(m), 644(w)
結晶(2) FT-IR(ATR): 3010-2810(w, br, C-H), 1651(s, sh, C=O), 1585(w), 1522(s), 1481(w), 1439(w), 1369(m), 1327(m, CF3), 1294(w, CF3), 1267(s, CF3), 1225(s, CF3), 1200(m, CF3), 1182(s, CF3), 1109(s, CF3), 1080(w), 1049(w), 1005(s), 970(m), 922(w), 891(w), 850(w), 829(w), 802(m), 746(m), 714(w), 683(m), 644(w)
結晶(3) FT-IR(ATR): 3050-2800(br, w, C-H), 1658(sh, s, C=O), 1581(w), 1527(s), 1427(m), 1377(w), 1331(w), 1265(s, CF3), 1223(s, CF3), 1184(s, CF3), 1126(s, CF3), 1080(w), 1049(w), 1011(w), 949(m), 837(w), 802(m), 748(m), 690(m), 644(w)
結晶(4) FT-IR(ATR): 3025-2800(br, w, C-H), 1647(sh, s, C=O), 1535(m), 1423(m), 1327(m), 1294(w), 1265(s, CF3), 1222(s, CF3), 1198(s, CF3), 1180(s, CF3), 1124(s, CF3), 1107(m), 1078(m), 1049(m), 920(w), 847(m), 802(m), 729(m), 681(w), 642(w)The results of FT-IR analysis are shown below. The numerical value before the parenthesis indicates the wave number of infrared rays (cm −1 ), and the alphabet in the parenthesis indicates the shape and size of the absorption spectrum and the specific group corresponding to the absorption spectrum.
Crystal (1) FT-IR (ATR): 3010-2810 (w, br, CH), 1651 (s, sh, C = O), 1585 (w), 1522 (s), 1483 (w), 1441 ( w), 1371 (m), 1329 (m, CF3), 1294 (w, CF3), 1267 (s, CF3), 1225 (s, CF3), 1200 (m, CF3), 1182 (s, CF3), 1122 (s, CF3), 1111 (m), 1082 (m), 1051 (m), 1009 (s), 972 (m), 922 (w), 891 (w), 850 (w), 829 (w ), 802 (m), 746 (m), 714 (w), 683 (m), 644 (w)
Crystal (2) FT-IR (ATR): 3010-2810 (w, br, CH), 1651 (s, sh, C = O), 1585 (w), 1522 (s), 1481 (w), 1439 ( w), 1369 (m), 1327 (m, CF3), 1294 (w, CF3), 1267 (s, CF3), 1225 (s, CF3), 1200 (m, CF3), 1182 (s, CF3), 1109 (s, CF3), 1080 (w), 1049 (w), 1005 (s), 970 (m), 922 (w), 891 (w), 850 (w), 829 (w), 802 (m ), 746 (m), 714 (w), 683 (m), 644 (w)
Crystal (3) FT-IR (ATR): 3050-2800 (br, w, CH), 1658 (sh, s, C = O), 1581 (w), 1527 (s), 1427 (m), 1377 ( w), 1331 (w), 1265 (s, CF3), 1223 (s, CF3), 1184 (s, CF3), 1126 (s, CF3), 1080 (w), 1049 (w), 1011 (w) , 949 (m), 837 (w), 802 (m), 748 (m), 690 (m), 644 (w)
Crystal (4) FT-IR (ATR): 3025-2800 (br, w, CH), 1647 (sh, s, C = O), 1535 (m), 1423 (m), 1327 (m), 1294 ( w), 1265 (s, CF3), 1222 (s, CF3), 1198 (s, CF3), 1180 (s, CF3), 1124 (s, CF3), 1107 (m), 1078 (m), 1049 ( m), 920 (w), 847 (m), 802 (m), 729 (m), 681 (w), 642 (w)
元素分析の結果を以下に示す。
結晶(1) Anal. Found: C, 52.98 %; H, 5.24 %; N, 3.66 %. Calcd. for EuC53H65N3O8F9: C, 53.27 %; H, 5.48 %; N, 3.52 %.
結晶(2) Anal. Found: C, 53.12 %; H, 5.34 %; N, 3.59 %. Calcd. for EuC53H65N3O8F9: C, 53.27 %; H, 5.48 %; N, 3.52 %.
結晶(3) Anal. Found: C, 56.09 %; H, 4.84 %; N, 3.41 %. Calcd. for EuC61H65N3O8F9・0.5H2O: C, 53.65 %; H, 5.12 %; N, 3.23 %.
結晶(4) Anal. Found: C, 53.69 %; H, 4.57 %; N, 2.61 %. Calcd. for EuC48H50N2O6F9: C, 53.69 %; H, 4.69 %; N, 2.61 %.The results of elemental analysis are shown below.
Crystal (1) Anal. Found: C, 52.98%; H, 5.24%; N, 3.66%. Calcd. For EuC 53 H 65 N 3 O 8 F 9 : C, 53.27%; H, 5.48%; N, 3.52 %.
Crystal (2) Anal. Found: C, 53.12%; H, 5.34%; N, 3.59%. Calcd. For EuC 53 H 65 N 3 O 8 F 9 : C, 53.27%; H, 5.48%; N, 3.52 %.
Crystal (3) Anal. Found: C, 56.09%; H, 4.84%; N, 3.41%. Calcd. For EuC 61 H 65 N 3 O 8 F 9・ 0.5H 2 O: C, 53.65%; H, 5.12 %; N, 3.23%.
Crystal (4) Anal. Found: C, 53.69%; H, 4.57%; N, 2.61%. Calcd. For EuC 48 H 50 N 2 O 6 F 9 : C, 53.69%; H, 4.69%; N, 2.61 %.
4種類のEu(facam)3錯体の黄色結晶(1)〜(4)の単結晶X線構造解析の結果を図22に示す。黄色結晶(3)に関し、単結晶X線構造解析によりR,R-Me-Ph-Pyboxのメチル基及びフェニル基の絶対配置が4S及び5S体であると判断した。この時、D-facamの絶対配置が変化していないことを確認した。またflack parameterは-0.006(5)(Friedel pairs: 6384)であった。FIG. 22 shows the results of single-crystal X-ray structure analysis of yellow crystals (1) to (4) of four types of Eu (facam) 3 complexes. Regarding yellow crystal (3), the absolute configuration of methyl group and phenyl group of R, R-Me-Ph-Pybox was determined to be 4S and 5S isomers by single crystal X-ray structural analysis. At this time, it was confirmed that the absolute configuration of D-facam did not change. The flap parameter was -0.006 (5) (Friedel pairs: 6384).
上述した各種分析の結果から、得られた黄色結晶(1)〜(4)はそれぞれ図23に示すEu(facam)3錯体であり、(1)[Eu(R-iPr-Pybox)(D-facam)3]錯体、(2)[Eu(S-iPr-Pybox)(D-facam)3]錯体、(3)[Eu(S,S-Me-Ph-Pybox)(D-facam)3]錯体、(4)[Eu(Phen)(D-facam)3]錯体であると同定された。From the results of the various analyzes described above, the obtained yellow crystals (1) to (4) are each Eu (facam) 3 complex shown in FIG. 23, and (1) [Eu (R-iPr-Pybox) (D- facam) 3 ] complex, (2) [Eu (S-iPr-Pybox) (D-facam) 3 ] complex, (3) [Eu (S, S-Me-Ph-Pybox) (D-facam) 3 ] Complex, identified as (4) [Eu (Phen) (D-facam) 3 ] complex.
3.Eu(facam)3錯体及びEu(facam)3錯体を構成する配位子のCDスペクトル及び吸収スペクトル
各Eu(facam)3錯体の円偏光発光特性を求めるために、Eu(facam)3錯体(1)〜(4)及び各Eu(facam)3錯体を構成する配位子のCDスペクトル及び吸収スペクトルを測定した。
いずれの測定においても、各Eu(facam)3錯体及び各Eu(facam)3錯体を構成する配位子の重アセトニトリル溶液(1.0×10-2M)を調製し、溶存酸素による消光を防ぐためにArバブリングを10分間行った後、測定した。
Eu(facam)3錯体を構成するPybox配位子及びPhen配位子のCDスペクトル及び吸収スペクトルを図24Aに、Eu(facam)3錯体(1)〜(4)のCDスペクトル及び吸収スペクトルを図24Bに示す。3. CD spectra and absorption spectra of the ligands that make up Eu (facam) 3 complex and Eu (facam) 3 complex To determine the circularly polarized emission characteristics of each Eu (facam) 3 complex, Eu (facam) 3 complex (1 ) To (4) and the CD spectrum and the absorption spectrum of the ligand constituting each Eu (facam) 3 complex were measured.
In any measurement, we prepared each Eu (facam) 3 complex and a heavy acetonitrile solution (1.0 × 10 -2 M) of the ligands constituting each Eu (facam) 3 complex to prevent quenching by dissolved oxygen. Measurement was performed after Ar bubbling for 10 minutes.
Fig. 24A shows the CD spectrum and absorption spectrum of the Pybox ligand and Phen ligand constituting the Eu (facam) 3 complex, and Fig. 24A shows the CD spectrum and absorption spectrum of the Eu (facam) 3 complex (1) to (4). Shown in 24B.
4.Eu(facam)3錯体のCPLスペクトル及び発光スペクトル
さらに、Eu(facam)3錯体(1)〜(4)のCPLスペクトル及び発光スペクトルを測定した。
測定試料の調製方法は、上述したCDスペクトル及び吸収スペクトルの測定時と同じである。
Eu(facam)3錯体(1)〜(4)のCPLスペクトル及び発光スペクトルを図25に示す。4). Eu (facam) 3 complexes of CPL and emission spectra were further measured CPL and emission spectra of Eu (facam) 3 complex (1) to (4).
The method for preparing the measurement sample is the same as that for measuring the CD spectrum and the absorption spectrum described above.
FIG. 25 shows CPL spectra and emission spectra of Eu (facam) 3 complexes (1) to (4).
5.Eu(facam)3錯体の発光量子収率
得られた吸収スペクトル及び発光スペクトルから各Eu(facam)3錯体(1)〜(4)の発光量子収率(Φ%)を求めた。発光量子収率はJASCO V-660を用い、絶対法により求めた。また併せて、試料に励起光として窒素レーザ(Usho KEC-160; wavelength、337nm; pulse width、600 ps; 10Hz)を照射し、発光をストリークカメラ(Hamamatsu、picosecond fluorescence measurement system、C4780)によって計測することにより、発光寿命(τ)を求めた。さらに、放射速度定数(kr)及び無放射速度定数(knr)をそれぞれ以下の式により算出した。
放射速度定数(kr)= Φ/100τ
無放射速度定数(knr)= (1-Φ)/100τ
これらを図26にまとめて示す。5. Was determined Eu (facam) emission quantum yield of 3 complexes of luminescence quantum yield obtained absorption spectrum and each of emission spectra Eu (facam) 3 complex (1) ~ (4) ( Φ%). The emission quantum yield was determined by the absolute method using JASCO V-660. In addition, the sample is irradiated with a nitrogen laser (Usho KEC-160; wavelength, 337 nm; pulse width, 600 ps; 10 Hz) as excitation light, and the emission is measured with a streak camera (Hamamatsu, picosecond fluorescence measurement system, C4780). Thus, the light emission lifetime (τ) was obtained. Furthermore, the radiation rate constant (k r ) and the non-radiation rate constant (k nr ) were calculated by the following equations, respectively.
Radiation rate constant (k r ) = Φ / 100τ
Non-radiation rate constant (k nr ) = (1-Φ) / 100τ
These are collectively shown in FIG.
6.Eu(facam)3錯体及びEu(facam)3錯体を構成する配位子の円偏光性
図24Bに示すCDスペクトルの結果を基に、以下の式を用いてg値(gCD)を計算した。
CDスペクトルからのg値=Δε/ε=2(εL−εR)/(εL+εR)
(式中、εLは左回りの円偏光における吸収係数、εRは右回りの円偏光における吸収係数を表す。)
g値の計算結果を図27に示す。6). Circular polarization of Eu (facam) 3 complex and ligands constituting Eu (facam) 3 complex Based on the result of CD spectrum shown in FIG. 24B, g value (g CD ) was calculated using the following formula. .
G value from CD spectrum = Δε / ε = 2 (ε L −ε R ) / (ε L + ε R )
(In the formula, ε L represents an absorption coefficient in counterclockwise circularly polarized light, and ε R represents an absorption coefficient in clockwise circularly polarized light.)
FIG. 27 shows the calculation result of the g value.
これらの結果から明らかなように、本実施例に係るEu(facam)3錯体の発光量子収率はLn(III)錯体に比べて相対的に低い。換言すれば、hfaの方がLn(III)を発光させる上で適しているということができる。As is clear from these results, the emission quantum yield of the Eu (facam) 3 complex according to this example is relatively low as compared with the Ln (III) complex. In other words, hfa is more suitable for emitting Ln (III).
次に、本発明の円偏光発光性希土類錯体を利用した光機能材料の実施例をいくつか述べる。
本発明に係る希土類錯体に一方の円偏光を吸収させれば、他方の円偏光を得ることができる。円偏光板などの円偏光フィルタと同じ役割を果たすことから、本発明に係る希土類錯体を円偏光フィルタに適用することが可能である。この円偏光フィルタは光多重通信など、広範な用途への適用が可能である。Next, several examples of optical functional materials using the circularly polarized light-emitting rare earth complex of the present invention will be described.
If the rare earth complex according to the present invention absorbs one circularly polarized light, the other circularly polarized light can be obtained. Since it plays the same role as a circularly polarizing filter such as a circularly polarizing plate, the rare earth complex according to the present invention can be applied to the circularly polarizing filter. This circularly polarizing filter can be applied to a wide range of applications such as optical multiplex communication.
本発明に係る希土類錯体では、旋光性の違いのみを有する配位子をそれぞれ(別個に)用いて錯体を合成することにより、同じ組成であっても左巻きの円偏光を強く吸収するものと、右巻きの円偏光を強く吸収するものの両方が得られる。また、一つの希土類錯体においても、波長に応じて左巻きの円偏光を強く吸収する場合と右巻きの円偏光を強く吸収する場合がある。そこで、一方の性質を示すものを「+1」、他方の性質を有するものを「−1」と定義すれば、この錯体、或いはこの錯体を含む光学機能材料を並べて情報を記録することができ、そこへ、円偏光を当てることにより情報を読み出すことができる。
本発明に係る希土類錯体をセキュリティー用途へ適用する場合には、励起による発光、円偏光及び温度による変色の3つの情報を保持することができるので、簡便により高度なセキュリティを実現することができる。In the rare earth complex according to the present invention, by synthesizing the complex using each of the ligands having only the optical rotation difference (separately), the left-handed circularly polarized light is strongly absorbed even with the same composition, Both strongly absorbing right-handed circularly polarized light are obtained. Further, even in one rare earth complex, left-handed circularly polarized light may be strongly absorbed or right-handed circularly polarized light may be strongly absorbed depending on the wavelength. Therefore, if one having one property is defined as “+1” and one having the other property is defined as “−1”, information can be recorded by arranging this complex, or an optical functional material containing this complex, Information can be read by applying circularly polarized light there.
When the rare earth complex according to the present invention is applied to security applications, it is possible to retain three pieces of information of light emission due to excitation, circularly polarized light, and discoloration due to temperature, so that higher security can be realized easily.
本発明の希土類錯体を光学機能材料として用いる際は、その錯体の結晶を直接用いてもよいし、その錯体を透明ポリマーや透明ガラスなどの透明固体担体に含有させてもよい。また、その錯体を溶媒に溶解、分散などさせて塗料とすることもできる。
本発明の希土類錯体は単独で、又は2種以上を混合して用いても良く、発光色を変化させるために有機色素を混合しても良い。本発明の希土類錯体は、その中心イオンとしての希土類イオンの種類や配位子の種類によって発光色が異なる。従って、本発明の希土類錯体の中心イオンや有機色素等の種類や混合比を適宜選択することにより、様々な色の発光を示す光機能性材料を作製することができる。When the rare earth complex of the present invention is used as an optical functional material, the crystal of the complex may be used directly, or the complex may be contained in a transparent solid support such as a transparent polymer or transparent glass. Alternatively, the complex can be dissolved or dispersed in a solvent to form a paint.
The rare earth complex of the present invention may be used alone or in combination of two or more, and an organic dye may be mixed in order to change the emission color. The rare earth complex of the present invention has different emission colors depending on the kind of rare earth ions as the central ions and the kind of ligands. Therefore, optical functional materials that emit light of various colors can be produced by appropriately selecting the type and mixing ratio of the central ions and organic dyes of the rare earth complex of the present invention.
本発明に係る希土類錯体を含有させる透明ポリマーとしては、ポリメチルメタクリレート、含フッ素ポリメタクリレート、ポリアクリレート、含フッ素ポリアクリレート、ポリスチレン、ポリエチレン、ポリプロピレン、ポリブテン等のポリオレフィン、含フッ素ポリオレフィン、ポリビニルエーテル、含フッ素ポリビニルエーテル、ポリ酢酸ビニル、ポリ塩化ビニル、及びそれらの共重合体、セルロース、ポリアセタール、ポリエステル、ポリカーボネイト、エポキシ樹脂、ポリアミド樹脂、ポリイミド樹脂、ポリウレタン、ナフィオン、石油樹脂、ロジン、ケイ素樹脂などが例示され、好ましくはポリメチルメタクリレート、含フッ素ポリメタクリレート、ポリアクリレート、含フッ素ポリアクリレート、ポリスチレン、ポリオレフィン、ポリビニルエーテル、及びそれらの共重合体、エポキシ樹脂等を使用することができる。もちろん、これらの2種以上を組み合わせたものであってもよい。
なお、本発明に係る希土類錯体を含む透明ポリマーは、公知の文献(Hasegawa, et al. Chem. Lett. 1999, 35.)に従い調製することができる。Examples of the transparent polymer containing the rare earth complex according to the present invention include polymethyl methacrylate, fluorine-containing polymethacrylate, polyacrylate, fluorine-containing polyacrylate, polyolefin such as polystyrene, polyethylene, polypropylene, polybutene, fluorine-containing polyolefin, polyvinyl ether, Examples include fluorine polyvinyl ether, polyvinyl acetate, polyvinyl chloride, and copolymers thereof, cellulose, polyacetal, polyester, polycarbonate, epoxy resin, polyamide resin, polyimide resin, polyurethane, Nafion, petroleum resin, rosin, and silicon resin. Preferably, polymethyl methacrylate, fluorine-containing polymethacrylate, polyacrylate, fluorine-containing polyacrylate, polystyrene, polyolefin Polyvinyl ethers, and copolymers thereof, may be used an epoxy resin or the like. Of course, it may be a combination of two or more of these.
The transparent polymer containing the rare earth complex according to the present invention can be prepared according to known literature (Hasegawa, et al. Chem. Lett. 1999, 35.).
本発明に係る希土類錯体を溶解、分散させることのできる溶剤は、アルコール系溶剤、ケトン系溶剤、エステル系溶剤、ニトリル系溶剤あるいはこれらの混合物である。好ましくは、アセトニトリルやメタノールを使用することができる。 The solvent capable of dissolving and dispersing the rare earth complex according to the present invention is an alcohol solvent, a ketone solvent, an ester solvent, a nitrile solvent, or a mixture thereof. Preferably, acetonitrile or methanol can be used.
本発明に係る希土類錯体と共に溶解、分散させることのできる色素は、緑色系の色素としては、アルカリ土類シリコンオキシナイトライド系蛍光体、及びピリジン−フタルイミド縮合誘導体、ベンゾオキサジノン系、キナゾリノン系、クマリン系、キノフタロン系、ナルタル酸イミド系等の蛍光色素、テルビウム錯体等の有機蛍光体などが挙げられる。また、赤色系の色素としては、アルファサイアロン構造をもつ酸窒化物を含有する蛍光体、及びβ−ジケトネート、β−ジケトン、芳香族カルボン酸、又は、ブレンステッド酸等のアニオンを配位子とする希土類元素イオン錯体からなる赤色有機蛍光体などが挙げられる。さらに青色系の色素としては、アルカリ土類アルミネート系蛍光体、ナフタル酸イミド系、ベンゾオキサゾール系、スチリル系、クマリン系、ピラリゾン系、トリアゾール系化合物の蛍光色素、ツリウム錯体等の有機蛍光体などが挙げられる。
希土類錯体は一般にカチオン性であるので、本発明に係る希土類錯体と共存させる色素としては、例えばアントラセン系色素のように炭素と水素だけで構成されている色素を用いることが好ましい。Dyes that can be dissolved and dispersed together with the rare earth complex according to the present invention include, as green dyes, alkaline earth silicon oxynitride phosphors, pyridine-phthalimide condensed derivatives, benzoxazinones, quinazolinones, Examples thereof include fluorescent dyes such as coumarin-based, quinophthalone-based, and naltalimide-based, and organic phosphors such as terbium complexes. Further, as a red dye, a phosphor containing an oxynitride having an alpha sialon structure, and an anion such as β-diketonate, β-diketone, aromatic carboxylic acid, or Bronsted acid as a ligand. Red organic phosphors composed of rare earth element ion complexes. Further, as blue dyes, alkaline earth aluminate phosphors, naphthalimide imides, benzoxazoles, styryls, coumarins, pyralizones, triazoles, fluorescent compounds, organic phosphors such as thulium complexes, etc. Is mentioned.
Since rare earth complexes are generally cationic, it is preferable to use a dye composed only of carbon and hydrogen, such as an anthracene dye, as a dye to coexist with the rare earth complex according to the present invention.
Claims (12)
で表されることを特徴とする請求項1に記載の円偏光発光性希土類錯体。General formula (6)
The circularly polarized light-emitting rare earth complex according to claim 1, wherein
で表されることを特徴とする請求項1に記載の円偏光発光性希土類錯体。Formula (11)
The circularly polarized light-emitting rare earth complex according to claim 1, wherein
一般式(12)
で表されることを特徴とする円偏光発光性希土類錯体。A circularly polarized light-emitting rare earth complex in which a ligand composed of a phenanthroline skeleton and a camphor derivative is coordinated to a rare earth ion,
Formula (12)
A circularly polarized light-emitting rare earth complex characterized by:
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