J/A+A/387/1146 M1 and E2 emission lines in K-like ions (Charro+, 2002) ================================================================================ Atomic data for M1 and E2 emission lines in the potassium isoelectronic sequence Charro E., Curiel Z., Martin I. =2002A&A...387.1146C ================================================================================ ADC_Keywords: Atomic physics Keywords: atomic data - atomic processes Abstract: Relativistic Quantum Defect Orbital (RQDO) calculations of transition probabilities for E2 (electric quadrupole) and M1 (magnetic dipole) forbidden transition in the potassium sequence have been performed. Intensities for the higher ions are reported, to our knowledge, for the first time, as they are potentially important for the study of the plasma in astrophysical objects and fusion devices. File Summary: -------------------------------------------------------------------------------- FileName Lrecl Records Explanations -------------------------------------------------------------------------------- ReadMe 80 . This file tables.dat 131 56 E2 and M1 transition probabilities (tables 1-5) -------------------------------------------------------------------------------- See also: J/A+A/376/1106 : Forbidden transitions in Co(16+) (Charro+, 2001) Byte-by-byte Description of file: tables.dat -------------------------------------------------------------------------------- Bytes Format Units Label Explanations -------------------------------------------------------------------------------- 1- 10 A10 --- Ion Ion designation 12- 13 I2 --- Z Atomic number 15- 22 E8.3 --- TP1 This work transition probabilities for 3d3/2 <- 4s1/2 E2 spectral line (1) 24- 30 E7.3 --- TPA1 ? Ali et al. transition probabilities for 3d3/2 <- 4s1/2 E2 spectral line (1) 32- 38 E7.3 --- TPB1 ? Biemont transition probabilities for 3d3/2 <- 4s1/2 E2 spectral line (1) 40- 47 E8.3 --- TP2 This work transition probabilities for 3d5/2 <- 4s1/2 E2 spectral line (1) 49- 55 E7.3 --- TPA2 ? Ali et al. transition probabilities for 3d5/2 <- 4s1/2 E2 spectral line (1) 57- 63 E7.3 --- TPB2 ? Biemont transition probabilities for 3d5/2 <- 4s1/2 E2 spectral line (1) 65- 72 E8.3 --- TP3 This work transition probabilities for 3d3/2 <- 3d5/2 E2 spectral line (1) 74- 80 E7.3 --- TPA3 ? Ali et al. transition probabilities for 3d3/2 <- 3d5/2 E2 spectral line (1) 82- 88 E7.3 --- TPB3 ? Biemont transition probabilities for 3d3/2 <- 3d5/2 E2 spectral line (1) 90- 96 E7.3 --- TPBH3 ? Biemont & Hansen transition probabilities for 3d3/2 <- 3d5/2 E2 spectral line (1) 98-105 E8.3 --- TP4 This work transition probabilities for 3d3/2 <- 3d5/2 M1 spectral line (1) 107-113 E7.3 --- TPA4 ? Ali et al. transition probabilities for 3d3/2 <- 3d5/2 M1 spectral line (1) 115-121 E7.3 --- TPB4 ? Biemont transition probabilities for 3d3/2 <- 3d5/2 M1 spectral line (1) 123-129 E7.3 --- TPBH4 ? Biemont & Hansen transition probabilities for 3d3/2 <- 3d5/2 M1 spectral line (1) -------------------------------------------------------------------------------- Note (1): References: This work: Relativistic Quantum Defect Orbital Method Ali et al.: Multiconfiguration Dirac-Fock Code, Ali et al., 1988 Phys. Rev. A, 38 (8), 3992 Biemont: Multiconfiguration Dirac-Fock Code, Biemont, 1990, Bulletin de la Societe Royale des Sciences de Liege, 59e annee, 3-4, 319 Biemont & Hansen: Relativistic Hartree-Fock approach, Biemont & Hansen, 1989, Phys. Scr., 39(3), 308 -------------------------------------------------------------------------------- History: From electronic version of the journal ================================================================================ (End) Patricia Bauer [CDS] 23-May-2002