Copper spectra in a laser-generated plasma: measurements and classifications of Cu xii to Cu xxi

J. Sugar; V. Kaufman

doi:10.1364/JOSAB.3.000704

Journal of the Optical Society of America B
Vol. 3,
Issue 5,
pp. 704-710
(1986)
•https://doi.org/10.1364/JOSAB.3.000704

Copper spectra in a laser-generated plasma: measurements and classifications of Cu xii to Cu xxi

J. Sugar and V. Kaufman

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J. Sugar and V. Kaufman, "Copper spectra in a laser-generated plasma: measurements and classifications of Cu xii to Cu xxi," J. Opt. Soc. Am. B 3, 704-710 (1986)

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Abstract

A vapor containing 10- to 20-times-ionized copper was generated by focusing a 1-GW, 15-nsec, Nd–glass-laser pulse down to 0.3 mm on a metallic copper sample. Spectral radiation in the range of 125 to 450 Å was recorded photographically with the National Bureau of Standards 10.7-m grazing-incidence spectrograph. Ninety-two spectral lines arising from Cu xii to Cu xxi (Ar i through F i isoelectronic sequences) were identified. Twenty-six of these, mainly in Cu xix and Cu xxi, had been interpreted previously. The transition arrays observed were of the type 3s² 3pⁿ–3s² 3pⁿ⁻¹3d and −3s3pⁿ⁺¹. Slater integrals were fitted to the energy levels derived from these data and from previously measured magnetic-dipole lines.

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Ion	Wavelength (Å)	Intensities	Earlier Measurement^a	Classification
xxi	78.404	100	0.388 KKRC	2s²2p⁵		²P_3/2–2s2p⁶	²S_1/2
	90.361	30	0.353 KKRC			²P_1/2–	²S_1/2
xix	46.094	20	0.090 KRC	3p		²P_3/2–4s	²S_1/2
	47.339	30	0.340 KRC	3d		²D_3/2–4f	²F_5/2
	47.448	80	0.445 KRC			²D_5/2–	²F_7/2
	102.956	5	0.960 KRC	4d		²D_3/2–5f	²F_5/2
	103.186	10	0.179 KRC			²D_5/2–	²F_7/2
	111.265	5	0.274 KRC	4f		²F_5/2–5g	²G_7/2
	111.347	10	0.353 KRC			²F_7/2–	²G_9/2
	207.329	500	0.315 KRC	3p		²P_1/2–3d	²D_3/2
	221.382	500	0.376 KRC			²P_3/2–	²D_5/2
	224.240	50	0.240 KRC			²P_3/2–	²D_3/2
	273.371	500	0.361 KRC	3s		²S_1/2–3p	²P_3/2
	303.563	200				²S_1/2–	²P_1/2
xviii	185.614	50	0.58 FH	3s3p		³P₀ –3s3d	³D₁
	188.235	200	0.20 FH			³P₁ –	³D₂
	188.973	20				³P₁ –	³D₁
	196.399	200	0.40 FH			³P₂ –	³D₃
	197.672	10				³P₂ –	³D₂
	204.092	30	0.06 FH			¹P₁ –	¹D₂
	234.219	500	0.24 FH	3s²		¹S₀ –3s3p	¹P₁
	234.630	10		3s3p		³P₁ –3p²	³P₂
	247.011	10				³P₀ –	³P₁
	249.487	100				³P₂ –	³P₂
	253.001	10				³P₁ –	³P₁
	266.278	20				³P₁ –	³P₀
	270.336	10				³P₂ –	³P₁
xvii	174.180	50	0.12 FH	3s²3p		²P_1/2–3s²3d	²D_3/2
	183.504	100	0.47 FH			²P_3/2–	²D_5/2
	184.876	5				²P_3/2–	²D_3/2
	203.895	5		3s²3p		²P_1/2–3s3p²	²P_3/2
	208.348	3				²P_1/2–	²P_1/2
	218.732	100				²P_3/2–	²P_3/2
	223.834	10				²P_3/2–	²P_1/2
	223.550	1		3s3p²		⁴P_1/2–3p³	⁴S_3/2
	224.852	10		3s²3p		²P_1/2–3s3p²	²S_1/2
	230.695	2		3s3p²		⁴P_3/2–3p³	⁴S_3/2
	239.482	5				⁴P_5/2–	⁴S_3/2
	? 290.251	2		3s²3p		²P_3/2–3s3p²	²D_5/2
xvi	164.248	10		3s²3p²		¹D₂ –3s²3p3d	¹F₃
	165.524	2				³P₁ –	¹F₃
	166.226	3				³P₀ –	³P₁
	166.907	3				³P₁ –	³P₁
	168.039	1				³P₁ –	³P₁
	168.311	10				³P₂ –	³P₁
	168.899	20	0.80 FH			³P₂ –	³P₁
	169.474	1				³P₂ –	³P₁
	173.941	2				¹S₀ –	³P₁
	178.979	5				³P₂ –	³P₁
	184.633	20				³D₁ –	³P₁
	195.786	5		3s²3p²		³P₁ –3s3p³	³S₁
	203.175	10				³P₁ –	³S₁
	209.180	10				³P₂ –	³S₁
	210.405	10				¹D₂ –	¹P₁
	251.974	1				³P₁ –	³P₁
	259.877	3				³P₂ –	³P₂
	261.267	1				³P₂ –	³P₁
	276.841	2				³P₀ –	³D₁
	291.723	3				³P₁ –	³D₂
	298.182	3				³P₂ –	³D₃
xv	154.725	200	0.67 FH	3s²3p³	²D_5/2–3s²3p²(³P)3d		²F_7/2
	158.964	10			²D_3/2–	(¹D)	²D_5/2
	159.870	5			⁴S_3/2–	(³P)	⁴P_3/2
	161.398	5	0.34 FH		⁴S_3/2–	(³P)	⁴P_5/2
	164.608	5			²P_3/2–	(³P)	²S_1/2
	169.943	10			²D_3/2–	(³P)	²D_3/2
	172.841	5			²D_5/2–	(³P)	²D_3/2
	194.380	3			²D_5/2–	(³P)	⁴D_7/2
	205.309	2			²D_5/2–	(³P)	⁴D_7/2^b
xiv	140.590	10		3s²3p⁴	¹D₂ –3s²3p³(²P)3d		¹P₁
	148.329	200	0.30 FH		³P₂ –	(⁴S)	³D₃
	150.662	10			³P₁ –	(⁴S)	³D₂
	150.846	20			³P₂ –	(²D)	³D₂
	151.953	5			¹D₂ –	(²D)	¹D₂
	152.477	20			¹S₀ –	(²P)	¹P₁
	159.870	5			³P₂ –	(²P)	³P₂
	160.163	10			³P₂ –	(²P)	³D₃
	165.369	10			¹D₂ –	(²P)	¹F₃
	166.226	3			³P₁ –	(²P)	³P₂
	175.044	10			³P₁ –	(²P)	³D₁
	175.235	5			³P₀ –	(²P)	³D₁
	187.810	10			¹D₂ –	(²P)	¹D₂
	188.974	20			³P₂ –	(²D)	³D₃
	250.449	1			¹D₂ –3s3p⁵		¹P₁
	268.668	1			³P₂ –		³P₁
	277.270	1			³P₁ –		³P₀
	282.058	1			³P₂ –		³P₂
	302.426	1			³P₁ –		³P₂
xiii	138.082	20		3s²3p⁵	²P_3/2–3s²3p⁴(³P)3d		²D_3/2
	142.999	200			²P_3/2–		²D_5/2
	143.776	200 b1			²P_1/2–		³D_5/2
	144.733	20			²P_3/2–		³D_3/2
	153.307	10			²P_3/2–	(¹S)	³D_5/2
	162.695	1			²P_1/2–	(¹S)	³D_3/2
	186.476	1			²P_3/2–	(¹D)	³P_1/2
	? 274.799	1			²P_3/2–3s3p⁶		³S_1/2
xii	139.193	300	0.180 GF	3s²3p⁶	¹S₀ –3s²3p⁵3d		¹P₁
	174.893	5			¹S₀ –		³D₁

	Cu xiii	Cu xiv	Cu xv	Cu xvi	Cu xvii	Cu xviii
	n = 5	n = 4	n = 3	n = 2	n = 1	n = 0
	sp⁶ + s²p⁴d	sp⁵ + s²p³d	sp⁴ + s²p²d	sp³ + s²pd	sp² + s²d	sp
3s3pⁿ⁺¹
A	447 721(50)	481 872(350)		555 014(210)	450 918(15)	333 470(20)
F²(pp)				165 831(790)	168 536(100)
G¹(sp)		186 951(480)		191 439(330)	192 959(40)	182 954(100)
ζ(p)		21 141(170)		21 435(180)	21 719(30)	22 310(47)
α				220^a
3s²pⁿ⁻¹3d
A	640 014(14)	664 302(160)	644 643(20)	603 109(390)	557 943(50)
F²(pp)	126 330(210)	129 721(790)	144 184(240)
F²(pd)	146 839(180)	145 004(410)	148 307(190)	146 781(690)
G¹(pd)	145 104(40)	146 536(170)	164 097(52)	169 379(1000)
G³(pd)	94 024^a	97 001(540)	107 496^a	111 842(460)
ζ(p)	19 097(34)	21 135(200)	21 021(43)	21 788(80)
ζ(d)	1472^a	1 573(140)	1 721^a	1 868(65)	1 850(20)
D¹(pd)			12 544^a	12 544(650)
α			220^a
Configuration interaction R¹(sd, pp)	172 424^a	174 206(350)	155 378^a	156 755(930)	159 279(170)
rms level fit	30	140	37	84	29

	Cu xiii	Cu xiv	Cu xv	Cu xvi	Cu xvii	Cu xviii
	n = 5	n = 4	n = 3	n = 2	n = 1	n = 0
	sp⁶ + s²p⁴d	sp⁵ + s²p³^d	sp⁴ + s²p²d	sp³ + s²pd	sp² + s²d	sp
3s3pⁿ⁺¹
F²(pp)				0.991	0.994
G¹(sp)		0.895		0.892	0.890	0.834
ζ(p)		1.115		1.045	1.019	1.054
3s²pⁿ⁻¹3d
F²(pp)	0.794	0.802	0.877
F²(pd)	0.918	0.902	0.905	0.878
G¹(pd)	0.803	0.803	0.891	0.909
G³(pd)	0.80^a	0.816	0.89^a	0.919
ζ(p)	1.048	1.115	1.066	1.063
ζ(d)	0.80^a	0.805	0.83^a	0.835	0.802
Configuration interaction R¹(sd, pp)	0.91^a	0.912	0.80^a	0.803	0.812

Designation		J	Energy (cm⁻¹)	Leading Percentages
3s²3p⁵	²P	$\frac{3}{2}$	0	100
		½	28560(2)	100
3s3p⁶	²S	½	? 363902	74	26	3p⁴(⁴D)3d	²S
3s²3p⁴(¹D)3d	²P	½	536262	51	38	(³P)	²P
3s²3p⁴(¹S)3d	²D	$\frac{3}{2}$	643207	64	27	(¹D)	²D
		$\frac{5}{2}$	652286	74	16
3s²3p⁴(³P)3d	²P	$\frac{3}{2}$	690927	54	34	(¹D)	²P
3s²3p⁴(³P)3d	²D	$\frac{5}{2}$	699306	68	24	(¹D)	²D
		$\frac{3}{2}$	724207	61	16

Designation	J		Energy (cm⁻¹)	Leading Percentages
3s²3p⁴	³P	2	0	92	8		¹D
		1	23897(6)	100
		0	24520	87	13		¹S
3s²3p⁴	¹D	2	52460 + x	92	8		³P
3s²3p⁴	¹S	0	107911 + x	87	13		³P
3s3p⁵	³P	2	354547	82	13	3p³(²D)3d	³P
		1	372207	79	13
		0	384556	81	14
3s3p⁵	¹P	1	451743 + x	57	34	3p³(²D)3d	¹P
3s²3p³(²D)3d	³D	3	529172	32	27	(⁴S)	³D
3s²3p³(²P)3d	¹D	2	584913 + x	57	21	(²D)	³D
3s²3p³(²P)3d	³D	1	595182	55	32	(²D)	³D
		3	624364	41	30
3s²3p³(²P)3d	³P	2	625498	79	5	(²D)	³D
3s²3p³(²P)3d	¹F	3	657168 + x	55	21	(²P)	³D
3s²3p³(²D)3d	¹P	2	662928	78	14	3s3p⁵	⁵P
3s²3p³(⁴S)3d	³D	3	674177	47	20	(²P)	³D
		2	687634	35	27
3s²3p³(²D)3d	¹D	2	710558 + x	58	21	(²P)	¹D
3s²3p³(²P)3d	¹P	1	763748 + x	85	4	(⁴S)	³D

Designation		J	Energy (cm⁻¹)	Leading Percentages
3s²3p³	⁴S	$\frac{3}{2}$	0	93	6	²P
3s²3p³	²D	$\frac{3}{2}$	47939(5)	81	15	²P
		$\frac{5}{2}$	57805	100
3s²3p³	²P	½	(90950)^a	100
		$\frac{3}{2}$	105865(22)	79	18	²D
3s²3p²(³P)3d		$\frac{7}{2}$	544876	42 ⁴D	35	(¹D)	²F
3s²3p²(³P)3d	⁴D	$\frac{7}{2}$	572261	52	23	(¹D)	²F
3s²3p²(³P)3d	⁴P	$\frac{5}{2}$	619586	84	6	3s3p⁴	⁴P
		$\frac{3}{2}$	625508	71	8	3s²3p²	(¹D) ²D
3s²3p²(¹S)3d	²D	$\frac{3}{2}$	636372	36	33	(³P)	²D
3s²3p²(¹D)3d	²D	$\frac{5}{2}$	677012	59	31	(¹S)	²D
3s²3p²(³P)3d	²F	$\frac{7}{2}$	704172	62	37	(¹D)	²F
3s²3p²(¹D)3d	²S	½	713369	76	14	3s3p⁴	²S

Designation		J	Energy (cm⁻¹)	Leading Percentages
3s²3p²	³P	0	0	94	6	¹S
		1	18 597(1)	100
		2	32 653(15)	82	18	¹D
3s²3p²	¹D	2	72 016(11)	82	18	³P
3s²3p²	¹S	0	123 550(33)	94	6	³P
3s3p³	⁵S	2	(261 100)	98	2	³P
3s3p³	³D	1	361 218	84	8	3p3d	³D
		2	361 388	82	10	3s3p³	³P
		3	368 019	92	8	3p3d	³D
3s3p³	³P	0	(413 450)	93	7	3p3d	³P
		1	415 433	85	7	3p3d	³P
		2	417 450	74	9	3s3p³	³D
3s3p³	¹D	2	(464 200)	54	37	3p3d	¹D
3s3p³	³S	1	510 752	73	24		³P
3s3p³	¹P	1	547 290	62	26		³S
3s²3p3d	³F	2	(522 800)	97	2	3s3p³	¹D
		3	(534 500) 98	1			³D
		4	(553 270)	100
3s²3p3d	³P	2	591 378	48	19	3p3d	¹D
		0	617 733	93	7	3s3p³	³P
		1	622 726	50	39	3p3d	³D
3s²3p3d	¹D	2	613 664	38	23		³D
3s²3p3d	³D	1	601 591	52	38	3p3d	³P
		3	624 723	89	8	3s3p³	³D
		2	626 791	55	31	3p3d	³P
3s²3p3d	¹F	3	680 851	97	2		³D
3s²3p3d	¹P	1	698 458	84	12	3s3p³	¹P

Designation		J	Energy (cm⁻¹)	Leading Percentages
3s²3p	²P	½	0	100
		$\frac{3}{2}$	33 239(3)	100
3s 3p²	⁴P	½	266 840 + x	98	2		²S
		$\frac{3}{2}$	280 695 + x	100
		$\frac{5}{2}$	296 600 + x	97	3		²D
3s 3p²	²D	$\frac{3}{2}$	(373 330)^a	89	9	3s²3d	²D
		$\frac{5}{2}$	? 377 768	88	9
3s 3p²	²S	½	? 444 737	62	36		²P
3s 3p²	²P	½	479 982	64	36		²S
		$\frac{3}{2}$	490 434	98	1		²D
3s²3d	²D	$\frac{3}{2}$	574 130	90	10	3s3p²	²D
		$\frac{5}{2}$	578 186	91	9
	⁴S	$\frac{3}{2}$	714 167 + x

Designation		J	Energy (cm⁻¹)	Leading Percentages
3s²	¹S	0	0
3s3p	¹P	0	279 820	100
		1	289 400	99	1	¹P
		2	314 763	100
3s3p	¹P	1	426 951	99	1	³P
3p²	³P	0	664 947
		1	684 663
		2	715 594
3s3d	³D	1	818 574
		2	820 651
		3	823 930
3s3d	¹D	2	916 926

Abstract

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Tables (9)

Equations (2)

Journal of the Optical Society of America B