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source: source/entities.js @ 332:3fbe0a3ca068

Last change on this file since 332:3fbe0a3ca068 was 308:e6f21812dfce, checked in by Evgeny Stambulchik <Evgeny.Stambulchik@…>, 12 years ago
Oops. The plasmon energy was 2*pi smaller...
File size: 13.3 KB

Rev	Line
[70]	1	var plasma_entities = new Array(
	2	{
[181]	3	id : "plasma_frequency",
[70]	4	name : "Plasma frequency",
	5	dimension : "frequency",
	6	nspecies : 1,
[210]	7	section : "waves",
[96]	8	formula : "%s1.getPlasmaFrequency()",
	9	wikiLink : "Plasma_frequency"
[70]	10	},
	11	{
[181]	12	id : "gyrofrequency",
[70]	13	name : "Gyrofrequency",
	14	dimension : "frequency",
	15	nspecies : 1,
	16	section : "fundamental",
[144]	17	formula : "%s1.getGyroFrequency(this.plasma.B)",
[96]	18	wikiLink : "Gyrofrequency"
[70]	19	},
	20
	21	{
[221]	22	id : "wigner_seitz_radius",
	23	name : "Typical inter-particle distance",
[119]	24	dimension : "length",
	25	nspecies : 1,
	26	section : "fundamental",
[221]	27	formula : "%s1.getTypicalDistance()",
	28	wikiLink : "Wigner-Seitz_radius"
[119]	29	},
	30	{
[181]	31	id : "debye_length",
[70]	32	name : "Debye length",
	33	dimension : "length",
	34	nspecies : 1,
	35	section : "fundamental",
[96]	36	formula : "%s1.getDebyeLength()",
	37	wikiLink : "Debye_length"
[70]	38	},
	39	{
[181]	40	id : "full_debye_length",
[70]	41	name : "Full Debye length",
	42	dimension : "length",
	43	nspecies : 1,
	44	section : "fundamental",
[144]	45	formula : "this.plasma.getFullDebyeLength(%s1)",
[96]	46	wikiLink : "Debye_length"
[70]	47	},
	48	{
[181]	49	id : "gyroradius",
[119]	50	name : "Gyroradius",
[70]	51	dimension : "length",
	52	nspecies : 1,
	53	section : "fundamental",
[144]	54	formula : "%s1.getGyroRadius(this.plasma.B)",
[119]	55	wikiLink : "Gyroradius"
[70]	56	},
	57	{
[181]	58	id : "distance_of_minimal_approach",
[70]	59	name : "Distance of minimal approach",
	60	dimension : "length",
	61	nspecies : 1,
	62	section : "fundamental",
	63	formula : "%s1.getMinApproachDistance()"
	64	},
	65	{
[181]	66	id : "inertial_length",
[70]	67	name : "Inertial length",
	68	dimension : "length",
	69	nspecies : 1,
[210]	70	section : "waves",
[96]	71	formula : "%s1.getInertialLength()",
	72	wikiLink : "Inertial_length"
[70]	73	},
[119]	74	{
[181]	75	id : "de_broglie_wavelength",
[119]	76	name : "De Broglie wavelength",
	77	dimension : "length",
	78	nspecies : 1,
	79	section : "fundamental",
	80	formula : "%s1.getDeBroglieLength()",
	81	wikiLink : "DeBroglie_wavelength"
	82	},
[70]	83
	84	{
[181]	85	id : "thermal_velocity",
[70]	86	name : "Thermal velocity",
	87	dimension : "velocity",
	88	nspecies : 1,
	89	section : "fundamental",
[96]	90	formula : "%s1.getThermalVelocity()",
	91	wikiLink : "Thermal_velocity"
[70]	92	},
	93	{
[181]	94	id : "alfven_velocity",
[70]	95	name : "Alfven velocity",
	96	dimension : "velocity",
[101]	97	nspecies : 0,
[103]	98	section : "waves",
[144]	99	formula : "this.plasma.getAlfvenVelocity(this.plasma.B)",
[96]	100	wikiLink : "Alfven_velocity"
[70]	101	},
	102
	103	{
[181]	104	id : "coupling_parameter",
[70]	105	name : "Coupling parameter",
	106	dimension : "none",
	107	nspecies : 1,
	108	section : "fundamental",
	109	formula : "%s1.getCoupling()"
	110	},
	111	{
[181]	112	id : "typical_debye_screening",
[70]	113	name : "Typical Debye screening",
	114	dimension : "none",
	115	nspecies : 1,
	116	section : "spectroscopy",
[221]	117	formula : "var r = %s1.getTypicalDistance()/%s1.getDebyeLength(); \
[70]	118	(1 + r)*Math.exp(-r)"
	119	},
	120
	121	{
[181]	122	id : "transition_energy",
[70]	123	name : "Transition energy",
	124	dimension : "energy",
	125	nspecies : 0,
	126	section : "spectroscopy",
[295]	127	formula : "this.plasma.r.getTransitionEnergy()"
[70]	128	},
	129	{
[181]	130	id : "natural_linewidth",
[70]	131	name : "Natural linewidth",
	132	dimension : "energy",
	133	nspecies : 0,
	134	section : "spectroscopy",
[295]	135	formula : "this.plasma.r.getNaturalWidth()"
[70]	136	},
	137	{
[190]	138	id : "Fine_structure",
	139	name : "Fine structure",
	140	dimension : "energy",
	141	nspecies : 0,
	142	section : "spectroscopy",
[295]	143	formula : "this.plasma.r.getFineStructure()",
[190]	144	wikiLink : "Fine_structure"
	145	},
	146	{
[181]	147	id : "doppler_fwhm",
[70]	148	name : "Doppler FWHM",
	149	dimension : "energy",
	150	nspecies : 0,
	151	section : "spectroscopy",
[295]	152	formula : "2*this.plasma.r.getDopplerHwhm()",
[96]	153	wikiLink : "Doppler_broadening"
[70]	154	},
	155	{
[181]	156	id : "zeeman_splitting",
[70]	157	name : "Zeeman splitting",
	158	dimension : "energy",
	159	nspecies : 0,
	160	section : "spectroscopy",
[144]	161	formula : "2*this.plasma.getZeemanSplitting()"
[70]	162	},
	163	{
[181]	164	id : "total_stark_fwhm",
[70]	165	name : "Total Stark FWHM",
	166	dimension : "energy",
	167	nspecies : 0,
	168	section : "spectroscopy",
[144]	169	formula : "2*this.plasma.getStarkHwhm()"
[70]	170	},
	171	{
[181]	172	id : "stark_fwhm",
[119]	173	name : "Stark FWHM",
	174	dimension : "energy",
	175	nspecies : 1,
	176	prepos : "due to",
	177	section : "spectroscopy",
[144]	178	formula : "2this.plasma.getQsHwhm(%s1)this.plasma.getStarkQuasistaticity(%s1)"
[119]	179	},
	180
	181	{
[181]	182	id : "qs_stark_fwhm",
[70]	183	name : "QS Stark FWHM",
	184	dimension : "energy",
	185	nspecies : 1,
[87]	186	prepos : "due to",
[70]	187	section : "spectroscopy",
[144]	188	formula : "2*this.plasma.getQsHwhm(%s1)"
[70]	189	},
	190
	191	{
[181]	192	id : "dynamic_stark_range",
[70]	193	name : "Dynamic Stark range",
	194	dimension : "energy",
	195	nspecies : 1,
	196	section : "spectroscopy",
[197]	197	formula : "this.plasma.getMicrofieldFrequency(%s1)"
[70]	198	},
	199
	200	{
[181]	201	id : "minimal_energy_distance",
[70]	202	name : "Minimal energy distance",
	203	dimension : "energy",
	204	nspecies : 0,
	205	section : "spectroscopy",
[295]	206	formula : "this.plasma.r.getMinEnergyDistance()"
[70]	207	},
[75]	208	{
[223]	209	id : "plasmon_energy",
	210	name : "Plasmon energy",
	211	dimension : "energy",
	212	nspecies : 0,
	213	section : "spectroscopy",
[308]	214	formula : "this.plasma.e.getPlasmaFrequencyW()",
[223]	215	wikiLink : "Plasmon"
	216	},
	217	{
[181]	218	id : "fermi_energy",
[75]	219	name : "Fermi energy",
	220	dimension : "energy",
	221	nspecies : 0,
	222	section : "fundamental",
[144]	223	formula : "this.plasma.getFermiEnergy()",
[96]	224	wikiLink : "Fermi_energy"
[75]	225	},
[135]	226	{
[181]	227	id : "chemical_potential",
[135]	228	name : "Chemical potential",
	229	dimension : "energy",
	230	nspecies : 1,
	231	section : "fundamental",
	232	formula : "%s1.getChemicalPotential()",
	233	wikiLink : "Chemical_potential"
	234	},
[70]	235
	236	{
[268]	237	id : "mass_density",
	238	name : "Mass density",
	239	dimension : "mass_density",
	240	nspecies : 1,
	241	section : "fundamental",
	242	formula : "%s1.getMassDensity()",
	243	wikiLink : "Density"
	244	},
	245	{
	246	id : "mass_density",
	247	name : "Total mass density",
	248	dimension : "mass_density",
	249	nspecies : 0,
	250	section : "fundamental",
	251	formula : "this.plasma.getMassDensity()",
	252	wikiLink : "Density"
	253	},
	254
	255	{
[181]	256	id : "beta",
[119]	257	name : "Beta",
[70]	258	dimension : "none",
[119]	259	nspecies : 0,
	260	section : "fundamental",
[144]	261	formula : "this.plasma.getBeta()",
[119]	262	wikiLink : "Beta_(plasma_physics)"
[70]	263	},
[119]	264
[70]	265	{
[299]	266	id : "transition_wavelength",
	267	name : "Transition wavelength",
	268	dimension : "length",
	269	nspecies : 0,
	270	section : "spectroscopy",
	271	formula : "pf.base.Bohr.c/this.plasma.r.getTransitionEnergy()(2Math.PI)"
	272	},
	273	{
	274	id : "transition_frequency",
	275	name : "Transition frequency",
	276	dimension : "frequency",
	277	nspecies : 0,
	278	section : "spectroscopy",
	279	formula : "this.plasma.r.getTransitionEnergy()/(2*Math.PI)"
	280	},
	281
	282	{
[288]	283	id : "f_abs",
	284	name : "Oscillator strength",
	285	dimension : "none",
	286	nspecies : 0,
	287	section : "spectroscopy",
[295]	288	formula : "this.plasma.r.getOscillatorStrength()",
[288]	289	wikiLink : "Oscillator_strength"
	290	},
[289]	291	{
	292	id : "A",
	293	name : "Einstein coefficient",
	294	dimension : "frequency",
	295	nspecies : 0,
	296	section : "spectroscopy",
[295]	297	formula : "this.plasma.r.getEinsteinA()",
[289]	298	wikiLink : "Einstein_coefficients"
	299	},
[288]	300
	301	{
[181]	302	id : "stark_quasistaticity",
[70]	303	name : "Stark quasistaticity",
	304	dimension : "none",
	305	nspecies : 1,
	306	section : "spectroscopy",
[144]	307	formula : "this.plasma.getStarkQuasistaticity(%s1)"
[70]	308	},
[119]	309	{
[181]	310	id : "static_to_dynamic_stark_ratio",
[119]	311	name : "Static/dynamic Stark ratio",
	312	dimension : "none",
	313	nspecies : 1,
	314	section : "spectroscopy",
[144]	315	formula : "this.plasma.getStarkRatio(%s1)"
[119]	316	},
[70]	317
	318	{
[181]	319	id : "holtsmark_field",
[70]	320	name : "Holtsmark field",
	321	dimension : "efield",
	322	nspecies : 1,
	323	section : "spectroscopy",
	324	formula : "%s1.getHoltsmarkField()"
	325	},
	326
	327	{
[181]	328	id : "microfield_frequency",
[70]	329	name : "Microfield frequency",
	330	dimension : "frequency",
	331	nspecies : 1,
	332	section : "spectroscopy",
[144]	333	formula : "this.plasma.getMicrofieldFrequency(%s1)"
[70]	334	},
	335
	336	{
[181]	337	id : "cyclotron_losses",
[70]	338	name : "Cyclotron losses",
	339	dimension : "power_density",
	340	nspecies : 1,
	341	section : "radiation",
[144]	342	formula : "%s1.getCyclotronLosses(this.plasma.B)",
[96]	343	wikiLink : "Cyclotron_radiation"
[70]	344	},
	345
	346	{
[181]	347	id : "free-free_losses",
[70]	348	name : "Free-free losses",
	349	dimension : "power_density",
	350	nspecies : 0,
	351	section : "radiation",
[192]	352	formula : "this.plasma.getBremsstrahlungLosses()",
	353	wikiLink : "Bremsstrahlung"
[70]	354	},
	355
	356	{
[181]	357	id : "dree-free_spectral_density",
[70]	358	name : "Free-free spectral density",
	359	dimension : "spectral_power_density",
	360	nspecies : 0,
	361	section : "radiation",
[192]	362	formula : "this.plasma.getBremsstrahlungSpectralDensity()",
	363	wikiLink : "Bremsstrahlung"
[70]	364	},
	365
	366	{
[181]	367	id : "free-bound_losses",
[70]	368	name : "Free-bound losses",
	369	dimension : "power_density",
	370	nspecies : 0,
	371	section : "radiation",
[144]	372	formula : "this.plasma.getFreeBoundLosses()"
[70]	373	},
	374
	375	{
[181]	376	id : "free-bound_spectral_density",
[70]	377	name : "Free-bound spectral density",
	378	dimension : "spectral_power_density",
	379	nspecies : 0,
	380	section : "radiation",
[144]	381	formula : "this.plasma.getFreeBoundSpectralDensity()"
[70]	382	},
	383
	384	{
[181]	385	id : "ideal_gas_pressure",
[70]	386	name : "Ideal gas pressure",
	387	dimension : "pressure",
	388	nspecies : 1,
	389	section : "fundamental",
[96]	390	formula : "%s1.getPressure()",
	391	wikiLink : "Ideal_gas"
[70]	392	},
	393
	394	{
[181]	395	id : "total_pressure",
[70]	396	name : "Total pressure",
	397	dimension : "pressure",
	398	nspecies : 0,
	399	section : "fundamental",
[144]	400	formula : "this.plasma.getPressure()"
[70]	401	},
	402
	403	{
[181]	404	id : "magnetic_field_pressure",
[70]	405	name : "Magnetic field pressure",
	406	dimension : "pressure",
	407	nspecies : 0,
	408	section : "fundamental",
[144]	409	formula : "this.plasma.getMagneticFieldPressure()",
[96]	410	wikiLink : "Magnetic_pressure"
[70]	411	},
	412
	413	{
[181]	414	id : "coulomb_logarithm",
[102]	415	name : "Coulomb logarithm",
	416	dimension : "none",
[214]	417	nspecies : 2,
[103]	418	section : "collisions",
[215]	419	formula : "this.plasma.getCoulombLog(%s1, %s2)",
[192]	420	wikiLink : "Coulomb_collision"
[102]	421	},
	422
	423	{
[218]	424	id : "relaxation_rate",
	425	name : "Relaxation rate",
	426	dimension : "frequency",
	427	nspecies : 2,
	428	section : "collisions",
	429	formula : "this.plasma.getRelaxationRate(%s1, %s2)"
	430	},
	431
	432	{
[181]	433	id : "thomson_cross-section",
[70]	434	name : "Thomson cross-section",
	435	dimension : "area",
	436	nspecies : 1,
	437	section : "collisions",
[96]	438	formula : "%s1.getThomsonXsTotal()",
	439	wikiLink : "Thomson_cross_section"
[219]	440	},
	441
	442	{
[224]	443	id : "classical_ionization_field",
	444	name : "Classical ionization field",
	445	dimension : "efield",
	446	nspecies : 0,
	447	section : "spectroscopy",
[295]	448	formula : "this.plasma.r.getClassicalIonizationField()"
[227]	449	},
	450	{
	451	id : "inglis_teller_field",
	452	name : "Inglis-Teller field",
	453	dimension : "efield",
	454	nspecies : 0,
	455	section : "spectroscopy",
[295]	456	formula : "this.plasma.r.getInglisTellerField()",
[227]	457	wikiLink : "Inglis-Teller_equation"
[228]	458	},
	459	{
	460	id : "dreicer_field",
	461	name : "Dreicer field",
	462	dimension : "efield",
	463	nspecies : 0,
	464	section : "collisions",
	465	formula : "this.plasma.getDreicerField()"
[70]	466	}
	467	);

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