87:, photons, and electrons, and two muon arms which focus on the measurement of muon particles. There are also additional event characterization detectors that provide additional information about a collision, and a set of three huge magnets that bend the trajectories of the charged particles. These detectors work together in an advanced high-speed data acquisition system to collect information about the event and subsequently investigate properties of the QGP.
371:
90:
The experiment consists of a collaboration of more than 400 scientists and engineers from around the world. The collaboration is led by a spokesperson, elected by members every three years, along with a team of deputies and other appointed members who oversee various aspects of operating the detector
70:
The PHENIX Experiment consists of a collection of detectors, each of which perform a specific role in the measurement of the results of a heavy ion collision. The detectors are grouped into two central arms, which are capable of measuring a variety of particles including
47:
PHENIX is an exploratory experiment for the investigation of high energy collisions of heavy ions and protons, and is designed specifically to measure direct probes of the collisions such as
161:
K. Adcox et al. (PHENIX Collaboration) (2005). "Formation of dense partonic matter in relativistic nucleus–nucleus collisions at RHIC: Experimental evaluation by the PHENIX Collaboration".
123:. PHENIX data suggest that a new form of matter has indeed been discovered, and that it behaves like a perfect fluid. PHENIX scientists are now working to study its properties.
111:
The PHENIX collaboration performs basic research with high energy collisions of heavy ions and protons. The primary mission of PHENIX is the following:
412:
335:
436:
149:
32:
31:(for Pioneering High Energy Nuclear Interaction eXperiment) is the largest of the four experiments that have taken data at the
36:
431:
405:
91:
and managing the large group of scientist and institutions affiliated with it. Past and present spokespeople include
63:(QGP). Detecting and understanding the QGP allows us to understand better the universe in the moments after the
266:"Exploring the QCD phase diagram via the collision energy dependence of multi-particle femtoscopy with PHENIX"
116:
60:
398:
136:
287:
236:
182:
92:
277:
198:
172:
96:
163:
378:
295:
244:
190:
300:
265:
249:
224:
119:, which is believed to be the state of matter existing in the universe shortly after the
291:
240:
186:
382:
425:
202:
100:
194:
370:
59:. The primary goal of PHENIX is to discover and study a new state of matter called
327:
132:
Study the most basic building blocks of nature and the forces that govern them.
350:
337:
323:
120:
84:
64:
48:
177:
17:
76:
56:
282:
126:
Study matter under extreme conditions of temperature and pressure.
80:
72:
52:
318:
386:
406:
225:"Strangeness production in PHENIX experiment"
8:
115:Search for a new state of matter called the
413:
399:
299:
281:
248:
176:
215:
270:Journal of Physics: Conference Series
229:Journal of Physics: Conference Series
129:Learn where the proton gets its spin.
7:
367:
365:
223:Kotov, D. O.; et al. (2016).
25:
369:
264:Csanád, M.; et al. (2020).
301:10.1088/1742-6596/1602/1/012009
195:10.1016/j.nuclphysa.2005.03.086
150:Relativistic Heavy Ion Collider
33:Relativistic Heavy Ion Collider
250:10.1088/1742-6596/668/1/012017
37:Brookhaven National Laboratory
1:
385:. You can help Knowledge by
453:
364:
437:Particle physics stubs
381:–related article is a
137:quantum chromodynamics
107:The physics of PHENIX
432:Particle experiments
135:Create a map of the
351:40.8831°N 72.8817°W
347: /
292:2020JPhCS1602a2009C
241:2016JPhCS.668a2017K
187:2005NuPhA.757..184A
117:quark–gluon plasma
97:William Allen Zajc
61:quark–gluon plasma
394:
393:
356:40.8831; -72.8817
324:PHENIX experiment
276:(12009): 012009.
235:(12017): 012017.
164:Nuclear Physics A
99:(1998–2006), and
39:, United States.
16:(Redirected from
444:
415:
408:
401:
379:particle physics
373:
366:
362:
361:
359:
358:
357:
352:
348:
345:
344:
343:
340:
306:
305:
303:
285:
261:
255:
254:
252:
220:
206:
180:
171:(1–2): 184–283.
21:
452:
451:
447:
446:
445:
443:
442:
441:
422:
421:
420:
419:
355:
353:
349:
346:
341:
338:
336:
334:
333:
315:
310:
309:
263:
262:
258:
222:
221:
217:
212:
178:nucl-ex/0410003
160:
158:
156:Further reading
146:
109:
45:
29:PHENIX detector
23:
22:
15:
12:
11:
5:
450:
448:
440:
439:
434:
424:
423:
418:
417:
410:
403:
395:
392:
391:
374:
331:
330:
321:
319:PHENIX webpage
314:
313:External links
311:
308:
307:
256:
214:
213:
211:
208:
157:
154:
153:
152:
145:
142:
141:
140:
139:phase diagram.
133:
130:
127:
124:
108:
105:
93:Shoji Nagamiya
44:
41:
24:
14:
13:
10:
9:
6:
4:
3:
2:
449:
438:
435:
433:
430:
429:
427:
416:
411:
409:
404:
402:
397:
396:
390:
388:
384:
380:
375:
372:
368:
363:
360:
329:
325:
322:
320:
317:
316:
312:
302:
297:
293:
289:
284:
279:
275:
271:
267:
260:
257:
251:
246:
242:
238:
234:
230:
226:
219:
216:
209:
207:
204:
200:
196:
192:
188:
184:
179:
174:
170:
166:
165:
155:
151:
148:
147:
143:
138:
134:
131:
128:
125:
122:
118:
114:
113:
112:
106:
104:
103:(2007–2012).
102:
101:Barbara Jacak
98:
95:(1992–1998),
94:
88:
86:
82:
78:
74:
68:
66:
62:
58:
54:
50:
42:
40:
38:
34:
30:
19:
387:expanding it
376:
332:
273:
269:
259:
232:
228:
218:
168:
162:
159:
110:
89:
69:
46:
28:
26:
354: /
328:INSPIRE-HEP
426:Categories
342:72°52′54″W
339:40°52′59″N
326:record on
283:2007.04751
210:References
35:(RHIC) in
203:119511423
85:deuterons
49:electrons
144:See also
121:Big Bang
65:Big Bang
43:Overview
288:Bibcode
237:Bibcode
183:Bibcode
77:protons
57:photons
201:
55:, and
18:PHENIX
377:This
278:arXiv
199:S2CID
173:arXiv
81:kaons
73:pions
53:muons
383:stub
274:1602
27:The
296:doi
245:doi
233:668
191:doi
169:757
428::
294:.
286:.
272:.
268:.
243:.
231:.
227:.
197:.
189:.
181:.
167:.
83:,
79:,
75:,
67:.
51:,
414:e
407:t
400:v
389:.
304:.
298::
290::
280::
253:.
247::
239::
205:.
193::
185::
175::
20:)
Text is available under the Creative Commons Attribution-ShareAlike License. Additional terms may apply.