Structures by: Dhara A. K.
Total: 14
C48H38CuN6,ClO4
C48H38CuN6,ClO4
Dalton transactions (Cambridge, England : 2003) (2020) 49, 39 13829-13839
a=12.3221(3)Å b=18.2014(6)Å c=18.6062(6)Å
α=90° β=97.754(3)° γ=90°
C13H19CuNO6,H2O
C13H19CuNO6,H2O
Dalton Trans. (2017)
a=7.682(5)Å b=26.946(5)Å c=8.247(5)Å
α=90° β=113.877(5)° γ=90°
C20H26Cu2N2O6
C20H26Cu2N2O6
Dalton Trans. (2017)
a=12.8083(8)Å b=8.4214(5)Å c=10.2651(6)Å
α=90° β=103.604(3)° γ=90°
C22H30Cu2N2O8
C22H30Cu2N2O8
Dalton Trans. (2017)
a=29.866(4)Å b=8.1887(9)Å c=10.1006(12)Å
α=90° β=94.706(11)° γ=90°
C22H30Cu2N2O8
C22H30Cu2N2O8
Dalton Trans. (2017)
a=14.7617(11)Å b=8.5963(7)Å c=10.0181(7)Å
α=90° β=109.639(3)° γ=90°
C26H42Cu2N2O12
C26H42Cu2N2O12
Dalton Trans. (2017)
a=7.5702(5)Å b=26.9513(17)Å c=8.0232(5)Å
α=90° β=111.061(2)° γ=90°
C26H38Cu2N2O12,C12H26CuN2O6,2(H2O)
C26H38Cu2N2O12,C12H26CuN2O6,2(H2O)
Dalton Trans. (2017)
a=7.6515(2)Å b=7.8302(2)Å c=19.9839(6)Å
α=93.0960(10)° β=90.4780(10)° γ=107.6040(10)°
C30H48CuN2O10
C30H48CuN2O10
Dalton Trans. (2017)
a=7.3376(14)Å b=21.415(4)Å c=10.712(2)Å
α=90° β=103.900(19)° γ=90°
C26H40CuN2O10
C26H40CuN2O10
Dalton Trans. (2017)
a=8.4412(3)Å b=10.9602(4)Å c=15.2987(5)Å
α=90° β=92.7410(10)° γ=90°
C44H46Cu2N6O12
C44H46Cu2N6O12
Dalton Trans. (2017)
a=25.0426(14)Å b=10.0519(5)Å c=23.0481(13)Å
α=90° β=119.402(2)° γ=90°
C42H32Cu2O12
C42H32Cu2O12
Dalton Trans. (2017)
a=10.7710(9)Å b=11.7039(11)Å c=15.2527(15)Å
α=90° β=91.111(5)° γ=90°
C24H36CuN2O8
C24H36CuN2O8
Dalton Trans. (2017)
a=7.055(5)Å b=8.673(5)Å c=21.625(5)Å
α=90° β=92.895(5)° γ=90°
C38H32Cl2N6O4Zn2
C38H32Cl2N6O4Zn2
Inorganic Chemistry Frontiers (2016) 3, 12 1543
a=11.506(7)Å b=11.966(7)Å c=15.127(9)Å
α=84.49(3)° β=89.19(3)° γ=63.54(3)°
C44H32Cl2N6O2Zn2,C2H3N
C44H32Cl2N6O2Zn2,C2H3N
Inorganic Chemistry Frontiers (2016) 3, 12 1543
a=19.314(4)Å b=12.669(3)Å c=17.150(4)Å
α=90.00° β=90.00° γ=90.00°