Photorefractive effect in LN: Theoretical part Weiwen Zou May 16,2003

My view on the research

2 • 1. Microscopic changes: In different non-stoichiometric crystals without or with different doping concentration – Defects (Intrinsic and extrinsic) • The gating ratio – Impurity levels in the gap of crystal – Which location in lattice – … • Absorption change • 2. Macroscopic performances (change): • Sensitivity • M#(M number) • Dynamic range • Dark decay • Optical quality • …..

3 • • •

Outline

The concise introduction of photorefractive effect

– A common nonlinear optical effect – The photorefractive effect – Two wave mixing – Holography – Applications of photorefractive materials

One-color holography Vs. two-color holography

– One-color holography – Two-color holography – Analogy

LiNbO 3 for the two-color holography

– Crystal growth and congruent melting – Nonstoichiometry and stoichiometry – LiNbO 3 and its defects – Charge transport models

4

Outline

•

The performance change of the crystal due to doping

– Defect changes due to varying dopants – Intrinsic defects – Extrinsic defects – Relative sequence •

Next plan

–

Experiments of two-color holography (part II)

• The two-color holography’s parameters • Determination methods and the corresponding precautions for them • Setup of the experiment • Doubly doped by Manganese(Mn) and Iron (Fe) (Nature,1998) • Doped by Indium (In) • Doped by Magnesium (Mg)

5

The concise introduction of photorefractive effect

 A common nonlinear optical effect  The photorefractive effect • Two wave mixing • Holography • Applications of photorefractive materials

The concise introduction of photorefractive effect

A traditional nonlinear optical effect

6

Linear optics:

the polarization in a medium is linear with the illuminated optical field. In other word, the susceptibility is independent with the optical field.

P

  0  (1)

E

A traditional nonlinear optical effect:

it can be described by a nonlinear susceptibility which is dependent with the optical field.

P : The polarization of the medium

P

  0  (1)

E

  0  (2 )

E

2   0  (3)

E

3  E : The optical field  0 : Absolute Electric constant  1 : The linear susceptibility of the medium  (

n

) : The different order nonlinear susceptibility.

The concise introduction of photorefractive effect

The photorefractive effect

• • •

Definition:

The photorefractive effect is the change in refractive index of an optical material that results from the optically induced distribution of carriers in the material, such as electrons and holes etc.

Characteristics:

It is quite different from the other nonlinear optical effect above.

The reason is that, under a wide range of conditions, the change in refractive index in steady state is independent of the intensity (or optical field) of the light that induces the change.

Mechanism:

(See the figure of next page) 7

The concise introduction of photorefractive effect

Mechanism

(+dopants) Ferroelectric Crystal Congruent melting Space-charge Electric field E SC Due to the electrooptic effect in X’tal The refractive index has been changed by the E-O principle.

n->n’

Defects or impurities Dynamic Equilibrium State This is the crystal’ certain nonlinear performance named as photorefractive effect X’tal(:dopa nt) Laser illuminating Impurity or defect is excited and begins to diffuse or drift 8

The concise introduction of photorefractive effect

The coherent beams interfere to form the distribution of intensity The carriers redistribute under the light illumination The space charge field is formed by the redistribution of the carriers induced by the illuminating light Due to the linear Electro-optical effect in the material, the refractive index variation The phase relationship among the interfering beams (  1 ), the charge density ( space charge field (  3 ):  3    2 2  ) and the 2   1   2 9

The concise introduction of photorefractive effect

Bragg grating

Two-wave mixing

(two-beam coupling) Two beams are incident on the crystal.

Due to the photorefractive effect in the crystal, a Bragg grating is formed.

LiNbO 3 Because the grating is formed by those 2 beams, each of them satisfies the Bragg condition and is diffracted by the grating.

This is so-called two-wave mixing or two-beam coupling.

Note: It exists by other nonlinear effects such as Stimulated Brillioun Scatting (BRS)...

10

The concise introduction of photorefractive effect

Mirror

Holography(

Writing

)

Reference beams LiNbO 3 :Photosensitive medium Object beams Hologram Laser beams 11 Lion: one object

The concise introduction of photorefractive effect

Holography(

Reading

)

Reference beams Diffracted beams Hologram Note: The reference beams should satisfy the so-called Bragg condition.

12

13

One-color holography Vs. two-color holography

• One-color holography • Two-color holography • Analogy

One-color Vs. two-color

One-color Holography(physics)

14 Note: All of these figures ©

IBM

One-color Vs. two-color

15

Characters of one-color holography

• Advantage – Easy to erase – Mechanical stability – Recording reversibility • Disadvantage – The reversibility makes the holograms volatile, so that they can be easily erased during the process of reading the recorded information.

• The reason : the reading process is that the hologram is due to the space-charge field which is induced by the space-charge redistribution stimulated by the interference between the object and reference beam both of which has the same wavelength. So if one reading beam is incident on the crystal, electrons trapped to form the space charge will be excited uniformly to erase the hologram.

16

One-color Vs. two-color

The ways to solve the disadvantage

• Thermal fixing • Electrical fixing • Two-wavelength fixing (2-color holography or “photo gated” recording)

17

One-color Vs. two-color

Thermal fixing • Mechanism(copy the space-charge pattern into a pattern of immobile ions):

A copy of the stored index gratings is made by thermally activating proton diffusion, which creates an optically stable complementary proton grating to store the hologram.

• Disadvantages

– Long time for fixing – Not easy for erosion.

18

One-color Vs. two-color

Electrical fixing • Mechanism(copy space-charge pattern into felloelectric domains) • Disadvantage

– Not easy for erosion.

19

One-color Vs. two-color

Two-color holography

Ref.

:Adibi et al.,

J.Opt.Soc.Am.B

,

18

, 584-601 (1997)

20

One-color Vs. two-color

Two-color holography

Gate photon Conduction band (C.B.) Writing Photon Shape level Deep level Valence band (V.B.) Carrier: Electron Conduction band (C.B.) Deep level Shape level Writing Photon Valence band (V.B.) Carrier: Hole Gate photon

One-color Vs. two-color

21

Two-color holography

A shorter light (

gating

) excites the carriers from the deep level, which tend to be trapped at the shape level. Then the small polaron formed is sensitive to infrared light but is metastable at room temperature.(long dark decay.) Gate photon e X e K + e e K e Shallow level e Writing Photon e Deep level e e X + Valence band If coherent inhomogeneous beams (

writing

) incident, they write the holograms as the spatial distribution of filled shallow centers(PR effect). Due to be unstable( dark decay ), the electrons at shallow centers will be transferred to that at deep centers, so the hologram is recorded in the deep level too . While readout photon ( condition stable and nonvolatile.

with the same wavelength of writing and satisfying the Bragg ) is not enough to excite electrons from the deep level to the Conduction band. Therefore, there holograms by this means are

One-color Vs. two-color

Vs.

22 Note: All of these figures ©

IBM

23

LiNbO

3

for the two-color holography

• Crystal growth and congruent melting • Non-stoichiometry vs. stoichiometry • LiNbO 3 intrinsic defects • Charge transport models

LiNbO 3 for the two-color holography

Crystal growth • Congruent melting • Reduction treatment:

heat treatment in an oxygen-poor atmosphere

• Doped with other transient (damage resistant) elements

24

25

Rough sketch of lithium nibote

Copyrig ht: crystaltechnology

LiNbO 3 for the two-color holography

LiNbO

3

and its structure

Lithium Oxygen Niobium 1. Li + and Nb 5+ have nearly identical ionic radii.

26 2. The environments of them are similar. Both ions are surrouded by distorted octahedra of six O 2 ions.

3. Nb 5+ - O 2 is stronger than Li + - O 2 Results: Lithium Niobate has a tendency to non-stoichiometry with Li/Nb<1 (usually 48.6:51.4

).

27 Usually, congruently melted LiNbO3 crystal is always a non-stoichiometric one, which means [

Li

 ] [

Li

 ]  [

Nb

5  ]  48.6

mol

%  50% The formulation for it can be rewritten as

Li

1 

x Nb

1 

x

/ 5

O

3 or [

Li

1 

x Nb x

/ 5 

y

][

Nb

1 

y

]

O

3 However, other ways can form the stoichiometric crystal. For example, before melting the concentration of Lithium can be much more than that of Niobium.

LiNbO 3 for the two-color holography Intrinsic defects on the congruent melting crystals (without or with reduction treatment)

5 

Nb Li

Intrinsic anti-site defects Postgrowth reduction treatment: A loss of oxygens and the diffusion of the excess Li and Nb 5+ ions.

Bipolaron 4 

Nb Li

4 

Nb Nb

4 

Nb Li

4 

Nb Nb

That Li/Nb is less than unity makes some Nb ions locate at the Li sites 28

LiNbO 3 for the two-color holography

Charge transport models

Reason: Where the free charge carriers come from and where they are trapped is crucial for the holography.

Function: It determines macroscopic properties like

absorption, absorption changes, conductivity and holographic sensitivity.

Models: One-center model without and with electron-hole competition; two-center model; the three-valence models.

Notes: Independent on the sign of the dominant charge carrier (either electrons or holes) ; dependent on not only the host 29

LiNbO 3 for the two-color holography

One-center model

Electrons are excited by light or by thermal processes from filled traps C into the CB Free electrons recombine from CB with empty traps C 0 In fact, one-color holography is based on this model.

30 Arrows indicate excitation and recombination of electrons at C /C 0 . C can be any defects ions in crystal, such as Fe 3+ , Nb Li 5+ and so

LiNbO 3 for the two-color holography

Models with electron-hole competition

Orlowski and Kratzig demonstrated by beam-couping experiments that simultaneously electrons and holes can be involved in the charge transport.

Their relative contributions to the conductivity depend on the light wavelength and on the oxidizaton-reduction state of the crystal.

This is the straight forward extension of the one-center model.

Thermal and light-induced excitantions of valence band electrons into C 0 Recombination of electrons from C valence band holes with 31

LiNbO 3 for the two-color holography

Two-center model

• • • • In 1983, it was formulated for explanation of grating erasures with two distinct time constants(Thermal generation rates not considered) In 1986,based on transient photocurrent measurements, shallow centers => the charge transport In 1988, light-induced absorption changes was explained by this model by considering a large thermal generation rate of charge carriers at shallow centers .

In 1989, this model is applied into the photoconductivity.

32

LiNbO 3 for the two-color holography

Two-center model

e e X e K + e K e Shallow level Deep level e e e e X + Valence band

Without considering the thermal generation rates X and K are different photorefractive centers, respectively.

33

Ref.

:K. Buse,

Appl. Phys. B

,

64

, 273 291 (1997)

LiNbO 3 for the two-color holography

Two-center model

Gate photon e X e K + e e K e Shallow level e Writing Photon e Deep level e e X + Valence band In fact, two-color holography is based on this model.

34

LiNbO 3 for the two-color holography

Three-valence model

At low light intensities, only C 0 present. (the same and C as one-center model) are For sufficiently high light intensities, the electron concentration in CB becomes large enough that an appreciable number of electrons recombines with C and generates C 2 . Then C act as additional traps for C 2 35 The difference between three-valence model and two center model: 1. In two-center model, filled deep and shallow traps are coupled only via the density of electrons in CB .

2. In three-valence, there is also an additional coupling due to the relationship of the centers, which is the same element .

There is only one center C which can occur in three different valence states, denoted by 0, -1, 2-.

LiNbO 3 for the two-color holography

Applications

• Production of outstanding interference filters and wavelength demultiplexers (Holographic gratings) • Construction of volume holographic memories (Holographic gratings) • Optical detection systems of ultrasonic waves (Non-steady-sate photocurrents) • Laser-beam clean-up (two-wave mixing) • Efficient coupling of light from a multimode into a single-mode fiber (Self-pumped phase conjugation) • Optical computing • Enhanced detection of phase modulations • Femtosecond optical storage and processing 36

37

The performance change of the crystal due to doping

• Defect Changes due to varying dopants • Intrinsic defects • Extrinsic defects • Relative sequence

The performance change due to doping

Defect changes by the doping procedure

• When a certain element is doped into the non-stoichiometric LN, the impurity ion enters into the sites so that the concentration of the intrinsic defects decrease, which is formed by the non-stoichiometric composition.

 If the concentration of the impurity ions exceed the so-called optical-damage threshold value, all the intrinsic defects are almost displaced by the impurities.  It results that the absorption band by the intrinsic defects is shifted the new-formed defects.

owning to 38

The performance change due to doping

The importance of defects • Deferent configuration (or formulation) of one crystal with different defects will have different holographic performance according to its mechanism.

39

The performance change due to doping

Intrinsic defects • O

-

trapped holes (

Cation vacancy

) • Nb

4+

small polaron

( An electron self-trapped at Nb Nb 5+ orNb Li 5+ )

• Bipolarons

(Nb Nb 4+ Nb Li 4+ : diamagnetic pairs of electrons trapped at Nb Nb 5+ Nb Li 5+ complex )

• Oxygen Vacancies (V

O

)

40

The performance change due to doping

Extrinsic defects • Magnesium (

Mg

) • Iron(Fe) • Further extrinsic defects

41

The performance change due to doping

•

Cation vacancy: O

-

trapped holes

Form:

by capturing a defect electron(hole) at one of the neighboring O 2 , local charge compensation can be achieved under ionizing radiation •

Evidence:

– ESR(electron spin resonance) of congruent Lithium niobate by two photon X- and by e--irradiation. It consists of several overlapping lines, which cannot be disentangled, due to unresolved Li and Nb hyperfine interaction. – Optical absorption band: peak at 2.5ev

(approximate 0.495um

). It is caused by the light induced transfer of the hole from site to an equivalent O 2 ions around the defect its original trapping (like a small polaron).

– The Dark decay dynamics of the absorption coeffeicent change. (Pro. Tomita’ Group) 42

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Cation vacancy: O

-

trapped holes

•

Temperature dependence

of the X-ray-induced O coloration: – In the 50-200 K range, decaying at the same rate as to Nb 4+ , the ioniztion energy of which: 0.54ev

the absorption due – In 100-200K, using isochronal annealing, optical absorption and ESR decay simultaneously .

– In about 15K, X-irradiation in LN doped with 9% Mg, no trapped holes are formed; with 6% Mg the concentration is rather low .

• In Mg-doped crystal, the electron trapping energy is much less than undoped crystals. => The Nb 4+ electrons recombine with O in at rather low temperature.

• The concentration of cation vacancies rises with decreasing [Li]/[Nb], whereas self-trapping of holes cannot be excluded for high [Li]/[Nb].

43

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Small polarons

• •

Evidence:

– A characteristic 10-line pattern by two-photon (2*2.46ev) and X irradiation of congruent undoped LN, which is caused by hyperfine interaction with the nucleus of 93 Nb (the only stable isotope of Nb) – In reduced undoped LN after illumination with light of wavelength < 600nm at T<80K, the same ESR was found.

• Before illumination, peak at approximate 2.5ev

(500nm) due to bipolarons • After illumination,

1.6ev (760nm)

attributed to small polarons and the low energy party of the band explained by small polaron absoption based on

Form:

ev ) an electron self-trapped at a Nb Li 5+ ion to a free small polaron. ( 1.6 44

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

45 • • •

Bipolarons

(Electron pairs trapped at Nb Li -Nb Nb )

Form:

Electron pairs trapped at Nb Li -Nb Nb

Evidence:

– In reduced undoped LN after illumination with light of wavelength < 600nm at T<80K, the same ESR was found.

• Before illumination, peak at approximate 2.5ev(500nm) due to bipolarons • After illumination, 1.6ev (760nm) attributed to small polarons • The reduced crystal is diamagnetic and no ESR signal accompanying the absorption band => the absorption at 2.5ev

not due to small polarons and oxygen trapped holes

Characteristics:

– Dissociation: By heating or light illumination, a transfer of one of the paired electrons out of the cluster.

– The efficiency of coloration by reducing ~ the [Li]/[Nb] ratio : raising the ration decreases the coloration. crystal.) (because only in strongly non-stoichiometric crystals is a sufficient number of sites for electrons trapped after O left the

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Magnesium (Mg)

46 • •

General comment:

defects its properties is strongly related to those of the intrinsic

Evidence:

– 4.6mol% MgO compared with a lower Mg concentration, the effect for reducing the optical damage is much strongly .

– A distinct threshold at a critical Mg concentration: [Mg] c >4.5mol%.

– The effect due to the Mg concentration bigger than critical value (

not deliberately doped with Fe)

• The optical absorption in reduced crystals (due to intrinsic defects) decreases • The intensity of X-ray-induced luminescence increases by several orders of magnitude while other related properties , such as width and energy of the band, also change abruptly.

• The absorption edge shows a blueshift • The X-ray-induced Nb 4+ ESR intensity decreases to zero.

– Codoped with Fe and Mg, the photoconductivity increases effect is not be effected and the photovoltaic

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Magnesium (Mg)

• •

Similarity:

The features for high [Li]/[Nb] are similar to those for low [Li]/[Nb] but with high [Mg] doping.

– All of those experiment results for high [Li]/[Nb] are the same as those of high doping.

– With [Mg] fixed and the ratio of [Li]/[Nb] varying, the threshold for the change of properties is influenced by the ratio .

Function:

For Mg only indirectly influences the behavior of the specimens investigated, the function of Mg doping is to replace the Nb Li .

47

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Iron (Fe)

• • Fe 2+ and Fe 3+ – Only both the charge states occur in the doped Fe crystal.

– Converted into each other by reduction and oxidation treatments, respectively – In Both of them, Fe occupies the same type of lattice sites.

– Optical absorption: • Fe 2+ : 1.1ev

(d-d transitions --> Donor state transitions ) and 2.6 ev (Fe 2+ -Nb 5+ intervalence transfer), the latter of which is similar those of trapped hole and bipolaron absorption.

• Fe3+: Function: – The photoconductivity: 

p



I

 [

Fe

2  ] [

Fe

3  ] 48

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Relative sequence of defects I

CB ~ 2.5ev

~ 1.6ev

Small polarons/ Mg 2+ Bipolarons/O- holes VB 49

The performance change due to doping

Relative sequence II

(impurity levels) CB Mn 2+ 3+ Cu 1+ 2+ Fe 2+ 3+ Ti 3+ 4+ VB 50

Ref.

: O.F.Schirmer et. al.,

J.Phys.

Chem.Solids

,

52

, 185-200 (1991)

The performance change due to doping

Interrelation between intrinsic and extrinsic defects

Any possible manipulations with dopants induce change in the subsystem of intrinsic defects and, by their common influence cause variations of the properties of LN Because of the high concentration of intrinsic defects, the conventional congruent crystals are tolerant to impurities substituting for Li or Nb ions There are different of the dopants complexes , such as “impurity ion-intrinsic defect” or “impurity-impurity” and so on, due to the variation and the concentration 51 The strong coupling of extrinsic and intrinsic defects is one of the most important features of LN, which is indeed rather flexible and very sensitive to changes in both defects.

Ref.

: G.Malovichko et.al.

Appl. Phys.

B

,

68

, 785-793 (1997)

52

Next plan

•

Experiments of two-color holography

– The two-color holography’s parameters – Determination methods and the corresponding precautions for them – Setup of the experiment – Doubly doped by Manganese(Mn) and Iron (Fe) (

Nature,1998

) – Doped by Indium (In) – Doped by Magnesium (Mg) (

The main topic in our group

)

53