Файл: Weber H., Herziger G., Poprawe R. (eds.) Laser Fundamentals. Part 1 (Springer 2005)(263s) PEo .pdf

Crystal

θpm, type of

λpump

Ithr

λOPO

τp

η

Ref.

Notes

interaction

[µm]

[MW cm−2]

[µm]

[ns]

[%]

KTP

ϕ = 0 ◦

0.532

80

0.7–0.9;

3.5

12

[93Bos,

L = 15 mm, E = 3 mJ, ∆ ν = 0.02 cm−1

1.3–2.2

92Bos]

θ = 69 ◦ , ϕ = 0 ◦

0.532

–

0.75–1.04

4–6

27

[95Sri]

OPO-OPA, L1 = L2 = 10 mm, E = 45 mJ

θ = 60 ◦ , ϕ = 0 ◦

0.532

–

0.75–0.87;

4

–

[95Hui]

∆ ν = 200 MHz (with Fabry-Perot etalon),

1.83–1.37

28 (64 a) [94Yan]

E = 0.6 mJ, L = 16 mm

θ = 90 ◦ , ϕ = 0 ◦

0.532

4.3 W

1.09; 1.039

cw

SROPO, P = 1.9 W, L = 15 mm

θ = 90 ◦ ,

0.531

40 mW

1.0617

cw

30

[93Lee]

DROPO, L = 8 mm

ϕ = 25.3 ◦

θ = 69 ◦ , ϕ = 0 ◦

0.532

7

0.76–1.04

6

30

η = 40 % (380–520 nm)

KTA

θ = 53 ◦ , ϕ = 0 ◦

0.773–0.792

–

1.45; 1.7

300

0.3

[92Jan]

DROPO, L = 7 mm

type II

–

–

1.11–1.20;

cw

90

[98Edw]

Intracavity (Ti:Sa) SROPO, P = 1.46 W,

2.44–2.86

L = 11.5 mm

RTA

θ = 90 ◦ , ϕ = 0 ◦

0.77–0.83

70 mW

1.21–1.26;

cw

–

[97Sch]

SROPO, L = 12 mm, P = 84 mW, ∆ ν < 10 MHz

2.1–2.4

Banana

θooe = 90 ◦

0.532

–

0.75–1.82

10

5

[80Bar3]

SROPO, T = 80–220 ◦ C

KNbO3

along the b axis

0.532

3.5

0.88–1.35

10

32

[82Kat]

DROPO, T = 180–200 ◦ C, P = 12 MW

Urea

θoeo = 81–90 ◦

0.355

55 (45 mW) 0.5–0.51;

7

20

[84Don]

SROPO, L = 12.7 mm, I0 = 90 MW cm−2

1.17–1.22

θoeo = 50–90 ◦

0.355

–

0.5–1.23

7

23

[85Ros2,

SROPO, L = 23 mm

85Ros1]

θoeo = 64–90 ◦

0.308

16–20

0.537–0.72

4–6

37

[89Ebr]

L = 15 mm

NPP

eeo

0.266

–

0.33–0.42

7

–

[85Ros1]

θ = 9.5–13 ◦ ,

0.5927

30

0.9–1.7

1

5

[92Jos,

L = 1.9 mm

ϕ = 0 ◦

93Dou]

θ = 30 ◦

0.583–0.59

0.5

1–1.5

7

–

[95Kho]

Crystal

θpm, type of

λpump

Ithr

λOPO

τp

η

Ref.

Notes

interaction

[µm]

[MW cm−2]

[µm]

[ps]

[%]

KDP

eoe

0.532

–

0.8–1.67

40

25

[78Kry]

TWOPO, E = 1 mJ, L1 = L2 = 4 cm

eoe

0.532

–

0.9–1.3

30

51

[78Dan2,

TWOPO, ∆ ν ∆ τ = 0.7, L1 = 4 cm, L2 = 6 cm,

79Kab]

I0 = 15–20 GW cm−2

eoe

0.527

–

0.82–1.3

0.3–0.5

2

[83Bar,

SP OPO, E = 20 µJ

82Dan]

eoe

0.355

–

0.45–0.64,

45

15

[78Dan3] TWOPO, L1 = L2 = 4 cm

0.79–1.69

ADP

θooe = 90 ◦

0.266

–

0.44–0.68

10

10

[76Mas2] TWOPO, T = 50–110 ◦ C, L1 = L2 = 5 cm

CDA

θooe = 90 ◦

0.532

–

0.854–1.41

10

30–60

[74Mas]

L = 3 cm, T = 50–70 ◦ C,

I0 = 0.3 GW cm−2

θooe = 90 ◦

0.53

1000

0.8–1.3

10

12.5

[87Ion]

SP OPO, L = 4 cm, I0 = 3 GW cm−2

LiIO3

ooe

0.532

–

0.61–4.25

6

4

[77Dan,

TWOPO, L1 = 1 cm, L2 = 2.5 cm,

78Dan1]

I0 = 2 GW cm−2

θooe = 25–30 ◦

0.53

3000

0.68–2.4

–

5

[77Kry]

TWOPO, L1 = L2 = 4 cm, I0 = 6 GW cm−2

LiNbO3

ooe

1.06

–

1.4–4.0

3.5

10

[78Sei]

TWOPO, ∆ ν = 6.5 cm−1,

I0 = 1 GW cm−2

45–51 ◦

1.064

–

1.37–4.83

40

17

[77Iva]

TWOPO

47 ◦

1.054

100

1.35–2.11

0.5

15

[90Lae1]

SP OPO, L = 18 mm, I0 = 0.14 GW cm−2

84 ◦

0.53

–

0.66–2.7

40

17

[77Iva]

TWOPO, T = 46–360 ◦ C

90 ◦

0.532

–

0.68–0.76

20

9

[79Liu]

SP OPO

90 ◦

0.532

8

0.85–1.4

15

17.5

[86Pis]

SROPO, P = 30 kW, f = 10 kHz

90 ◦

0.532

< 30

0.65–3.0

10

7.2

[87Ion]

SP OPO, L = 25 mm

LiNbO3:MgO

θ = 48.5 ◦

0.75–0.84

4000

2.6–4.5

2–3

18

[96Lin]

L1 = L2 = 20 mm

θooe = 60–84 ◦

0.532

–

0.7–2.2

30

5.4

[91He]

TWOPO, ∆ λ = 0.3 nm (0.7 µm) and 1.4 nm

Crystal

θpm, type of

λpump

Ithr

λOPO

τp

η

Ref.

Notes

interaction

[µm]

[MW cm−2]

[µm]

[ps]

[%]

BBO

θooe = 20.7–22.8 ◦ 0.532

–

0.67–2.58

18

13

[92Zhu]

TWOPO, L1 = L2 = 9 mm,

I0 = 2.5–3.8 GW cm−2, E = 0.1–0.5 mJ

ooe

0.53

–

0.63–3.2

1.3

25

[93Dan]

TWOPO-OPA, L1 = L2 = 8 mm

ooe

0.36

500

0.406–3.17

20

30

[90Bur]

SP OPO, L = 12 mm, I0 = 2 GW cm−2,

E = 3 mJ, ∆ λ = 0.24 nm

θooe = 26–33 ◦

0.355

–

0.4–2.0

15

30

[90Hua]

OPO-OPA, L1 = 12 mm, L2 = 6 mm,

L3 = 15 mm, I0 = 3 GW cm−2, ∆ λ = 0.3 nm

ooe

0.355

–

0.4–2.86

24

6.5

[90Suk]

TWOPO, L1 = L2 = L3 = 8 mm,

I0 = 5 GW cm−2, ∆ ν = 10 cm−1

ooe

0.355

–

0.43–2.1

15

30

[93Zha1]

Injection seeding, L = 15 mm

θooe = 33 ◦

0.3547

–

0.42–2.8

30

61

[94Hua]

OPO-OPA, P = 51 MW

LBO

ooe, θ = 90 ◦ ,

0.8

700

1.15–2.26

1–2.2

27 (48 a) [95Ebr1]

SP OPO, P = 325 mW, L = 30 mm,

ϕ = 0 ◦

(400 mW)

T = 120–230 ◦ C

ooe, θ = 90 ◦ ,

0.8

320

1.374–1.53;

0.52

7.5

[95Ebr3]

SP OPO, P = 90 mW, L = 16 mm

ϕ = 0 ◦

1.676–1.828

type I

0.77–0.8

350

1.16–2.26

1

34

[96Fre]

SP SROPO, P = 580 mW, L = 16 mm

θ = 81 ◦ , ϕ = 5 ◦

0.57–0.63

–

1.2–1.5

0.58

10

[91Bay]

Injection seeding by 1.08 µm

θ = 85 ◦ , ϕ = 9 ◦

0.57–0.63

–

1.2–1.5

0.4

25

[92Akh]

Injection seeding by 1.08 µm (40 ps), L = 9 mm,

I0 = 1 TW cm−2

θ = 90 ◦ , ϕ = 0 ◦

0.532

–

0.75–1.8

35

20

[91Hua]

Injection seeding OPO, T = 106.5–148.5 ◦ C

θ = 90 ◦ , ooe

0.53

–

0.65–2.5

15

24

[91Lin]

OPA, angle (ϕ = 8.7–15.9 ◦ ) and temperature

tuning (T = 103–210 ◦ C), E = 0.45 mJ

θ = 90 ◦ , ϕ = 0 ◦

0.532

1500

0.77–1.7

100

30

[93Zho]

SP SROPO, L = 15 mm, T = 105–137 ◦ C,

∆ λ = 0.14 nm

ooe, θ = 90 ◦ ,

0.532

–

0.68–2.44

25

8

[95Liu]

L1 = L2 = 15 mm

ϕ = 11.5 ◦

θ = 0 ◦ , ϕ = 0 ◦

0.532

–

0.75–1.8

15

20

[95Wal]

P = 200 mW, L = 15 mm

θ = 90 ◦ , ϕ = 0 ◦

0.5235

2500

0.652–2.65

12

13

[92Ebr2,

SROPO, L = 12 mm, T = 125–190 ◦ C

(10 mW)

93Ebr,

93Hal1]

Crystal

θpm, type of

λpump

Ithr

λOPO

τp

η

Ref.

Notes

interaction

[µm]

[MW cm−2]

[µm]

[ps]

[%]

LBO

θ = 90 ◦ , ϕ = 0 ◦

0.5235

1100

0.909–1.235

33

50

[93Hal1,

DROPO, T = 167–180 ◦ C

(4.5 mW)

92Ebr1]

θ = 90 ◦ , ϕ = 0 ◦

0.5235

15 (30 mW)

0.65–2.65

1.7

50

[93Hal1]

DROPO, L = 12 mm, P = 0.21 W

ooe, θ = 90 ◦ ,

0.5235

47 mW

0.839–1.392

1.8

70 a

[94Rob1] SP SROPO, P = 88 mW, L = 3 mm

ϕ = 0 ◦

75 a

ooe, θ = 90 ◦ ,

0.5235

170 mW

0.65–2.7

1.63

[95But]

SP OPO, P = 210 mW, L = 15 mm

ϕ = 0 ◦

θ = 90 ◦ , ϕ = 0 ◦

0.523

100

0.72–1.91

1

34

[93McC1] SP SROPO, L = 13 mm, T = 125–175 ◦ C,

θ = 90 ◦ , ϕ = 0 ◦

27 (75 a) [93But]

Pav = 89 mW

0.523

80 (70 mW)

0.8–1.5

1.2–1.5

SROPO, L = 12 mm, Pav = 78 mW

θ = 90 ◦ ,

0.355

–

0.46–1.6

15

30

[91Zha]

Injection seeding from OPO, L = 16 mm,

ϕ = 27–43 ◦

I0 = 2.8 GW cm−2, E = 0.3 mJ

θ = 90 ◦ ,

0.355

–

0.403–2.58

12

28

[92Kra]

TWOPO, L1 = L2 = 15 mm, I0 = 5 GW cm−2,

ϕ = 18–42 ◦

E = 0.1–1 mJ

θ = 0 ◦ , ϕ = 0 ◦

0.355

2300

0.4159–

30

38

[92Hua,

TWOPO, L = 10 mm, T = 21–450 ◦ C,

θ = 90 ◦ ,

0.4826

93Hua]

I0 = 18 GW cm−2, ∆ λ = 0.15 nm

0.355

1000

0.452–1.65

9

26

[93Agn]

DROPO, L = 10.5 mm, E = 0.15 mJ

ϕ = 30–42 ◦

KTP

θ = 82–90 ◦ ,

1.064

0.8 W

1.57–1.59;

2–3

15

[93Chu]

SROPO, L = 10 mm, f = 75 MHz,

ϕ = 0 ◦

3.21–3.30

∆ λ = 1.5 nm

–

1.064

2.128

100

25

[93Lot]

SP OPO with 6 KTP (total length 58 mm),

P = 14 W

θ = 81–90 ◦ ,

1.053

5.8 W

1.55–1.56;

12

21

[93Gra]

SP OPO, L = 6 mm, P = 2 W

ϕ = 0 ◦

3.22–3.28

θ = 40.6–45.2 ◦ ,

0.8

–

1.02–1.16;

2.6

–

[95Gra]

OPA, E = 0.04 mJ

ϕ = 0 ◦ , oeo

2.6–3.7

θ = 53 ◦ , ϕ = 0 ◦ ,

0.72–0.85

0.8 W

1.44–1.64

1.1

20

[96Qia]

SP SROPO, P = 200 mW, L = 7 mm

Crystal

θpm, type of

λpump

Ithr

λOPO

τp

η

Ref.

Notes

interaction

[µm]

[MW cm−2]

[µm]

[ps]

[%]

KTP

θ = 90 ◦ , ϕ = 0 ◦

0.72–0.853

150

1.052–1.214;

1.2

42

[93Neb]

SP OPO, L = 6 mm, P = 0.7 W

2.286–2.871

θ = 54 ◦ , ϕ = 0 ◦ ,

0.532

250

0.614–4.16

0.39

12

[94Umb]

L = 14 mm

eoo

eoe, θ = 90 ◦ ,

0.527

0.9 W

0.851–0.938;

2.4–3.2

13

[95Che]

SROPO, P = 80–280 mW, L = 5 mm

ϕ = 35 ◦

1.2–1.381

θ = 40–70 ◦ ,

0.526

–

0.6–2.0

30

10

[88Van]

L = 20 mm

ϕ = 90 ◦

θ = 40–80 ◦ ,

0.526

–

0.6–4.3

30

10

[88Van]

L = 20 mm

ϕ = 0 ◦

16 (79 a) [92McC]

θ = 90 ◦ ,

0.523

57 (61 mW)

1.002–1.096

2.2

SP OPO, L = 5 mm, P = 42 mW

ϕ = 10–35 ◦

10 (56 a) [91Ebr1,

–

0.5235

1000

0.946–1.02;

8

SP SROPO, L = 5 mm, P = 2 mW

(2 mW)

1.075–1.172

93Hal1]

θ = 90 ◦

0.523

60 (61 mW)

0.938–1.184

1–2

16

[93McC2] SROPO, L = 5 mm, f = 125 MHz, P = 40 mW

θ = 90 ◦ ,

0.526

0.5 W

1.01–1.1

14

44

[93Gra]

SP OPO, L = 6 mm, P = 0.58 W

ϕ = 0–33 ◦

KTA

θ = 90 ◦ , ϕ = 0 ◦

1.064

–

1.54; 3.47

7

75

[98Ruf]

SP OPO, L = 15 mm

Banana

θooe = 90 ◦

0.532

5

0.8–1.6

10

25

[83Oni]

SP OPO

θooe = 90 ◦

0.53

50

0.65–3

10

5.3

[87Ion]

SP OPO, I0 = 250 MW cm−2

θooe = 90 ◦

0.532

7–9

0.672–2.56

15–45

8.1

[89Pis,

SP SROPO, L = 10 mm, f = 139 MHz,

90Pis]

T = 75–350 ◦ C

α–HIO3

eoe

0.532

–

0.7–2.2

30–45

10–12

[77Dan]

TWOPO, L1 = L2 = 2 cm, I0 = 4–5 GW cm−2

eoe

0.527

60

–

5–6

10

[80Bar2]

SP OPO, ∆ ν ∆ τ = 0.7