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. 2022 Aug 4;61(37):e202208305. doi: 10.1002/anie.202208305

Table 2.

Summary data for MOFs for potential O2 separation reported in the literature.

Metal–organic frameworks

Surface area [m2 g−1]

O2 adsorption [mmol g−1]

Pressure [bar]

Heat of adsorption, Qst [kJ mol−1]

T [K]

Ref.

BET

Langmuir

Cd(bpndc)(4,4′‐bpy)

6.7

1

90

[48]

Co2(OH)2(BBTA)

1360

1.2

1

45

298

[25]

Co2Cl2(BBTA)

1280

≈ 0.26

1

19

298

[25]

Co‐BTTri

1595

1853

4.8

1

34

195

[24, 25]

Co‐BDTriP

1332

1517

4.8

1

47

195

[24, 25]

Co‐MOF‐74

1417

18

0.015 P/P 0

77

[49]

Co‐MOF‐74 Composite

1008

1150

4.8

1.2

19

204

[46]

Cr3(BTC)2

1810

2040

0.73

0.21

298

[22]

Cr3(BTC)2

1403

4.46

1

298

[50]

Cr‐BTT

2030

2300

2.5

1

65

298

[23]

Cu(BDT)

200

14

1.0 P/P 0

77

[51]

Cu(BDTri)L (L=DMF)

1160

17.8

0.2

77

[52]

Cu(BDTri)L (L=DEF)

240

15.9

0.2

77

[52]

Cu3(BTC)2

1206

0.2

1

298

[50]

Cu3(BTC)2

2141

25.8

0.015 P/P 0

77

[49]

Cu‐BTC

2237

0.3

1

10.7

298

[53]

Cu‐BTC Composite

1143

0.34

1

15.3

298

[47]

Fe‐BTTri

1630

1930

5.9

1

51

195

[19, 54]

Fe‐MOF‐74

1360

1535

5.33

0.21

41

226

[18]

Mg3(NDC)3

190

3.5

1.0 P/P 0

77

[55]

MIL‐100 (Fe)

1900

0.25

1

8.5

298

[56]

MIL‐100 (Sc)

1635

0.28

1

15.1

298

[56]

MIL‐101 (Cr) Composite

264

424

2.0

1

298

[57]

MIL‐101 (Ti)

2970

4440

0.85

9x10−4

298

[58]

MOF‐177

3100

≈4300

0.18

1

298

[21, 59]

Ni2(cyclam)2(mtb)

141

154

1.2

0.196

77

[60]

Ni‐MOF‐74

1234

15

0.015 P/P 0

77

[49]

PCN‐13

150

3.0

1.0 P/P0P/P 0

77

[30]

PCN‐17

820

9.3

1.0 P/P 0

77

[31]

PCN‐224FeII

2901

2.4

1

34

195

[61]

UMCM‐1

4100

6500

0.23

0.96

4.9

298

[20]

Zn(TCNQ‐TCNQ)bpy

12.0

1.0 P/P 0

77

[29]

K0.82Fe2(bdp)3

1700

0.53

1

298

[28]

1.43

1

453

[28]

K1.09Fe2(bdp)3

750

0.68

1

298

[28]

1.32

1

473

[28]

K1.88Fe2(bdp)3

70

0.87

1

298

[28]

1.64

1

473

[28]

K2.07Fe2(bpeb)3

600

0.65

1

298

[28]

2.3

1

453

[28]