Ernest courant traineeship main - Revision history

YichaoJing: /* The Future: Space Weather and Accelerator Training */

2024-07-31T20:04:09Z

‎The Future: Space Weather and Accelerator Training

YichaoJing at 19:56, 31 July 2024

2024-07-31T19:56:35Z

YichaoJing: /* Coherent Electron Cooling: A Futuristic Technology */

2023-06-14T14:36:34Z

‎Coherent Electron Cooling: A Futuristic Technology

YichaoJing at 14:34, 14 June 2023

2023-06-14T14:34:10Z

YichaoJing at 16:41, 3 January 2023

2023-01-03T16:41:06Z

YichaoJing: /* RF Superconductivity for Accelerators in a Course */

2022-11-29T16:57:36Z

‎RF Superconductivity for Accelerators in a Course

YichaoJing at 16:55, 29 November 2022

2022-11-29T16:55:06Z

YichaoJing at 14:25, 7 November 2022

2022-11-07T14:25:52Z

YichaoJing: /* Wakefield Accelerators: Miniaturized yet Powerful */

2022-09-09T16:17:17Z

‎Wakefield Accelerators: Miniaturized yet Powerful

YichaoJing: /* Wakefield Accelerators: Miniaturized yet Powerful */

2022-09-09T16:17:01Z

‎Wakefield Accelerators: Miniaturized yet Powerful

← Older revision		Revision as of 20:04, 31 July 2024
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	=='''The Future: Space Weather and Accelerator Training'''==		=='''The Future: Space Weather and Accelerator Training'''==
		+
		+	[[Image:sw1.jpg\|600px\|Image: 1200 pixels\|center]]

	Space weather refers to the variation in the flow of high-energy charged particles in space from the sun and from outside the solar system. It can especially degrade or damage living things, such as astronauts, and electronics in spacecraft. As we enter a period with a greater presence in space, promising a new age of exploration and economic growth, there is a need to understand the effect of radiation on people and electronics and how to mitigate its harmful effects.		Space weather refers to the variation in the flow of high-energy charged particles in space from the sun and from outside the solar system. It can especially degrade or damage living things, such as astronauts, and electronics in spacecraft. As we enter a period with a greater presence in space, promising a new age of exploration and economic growth, there is a need to understand the effect of radiation on people and electronics and how to mitigate its harmful effects.

← Older revision		Revision as of 19:56, 31 July 2024
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	[[Fund_Accelerator\|'''Read more''']]		[[Fund_Accelerator\|'''Read more''']]
		+
		+	=='''The Future: Space Weather and Accelerator Training'''==
		+
		+	Space weather refers to the variation in the flow of high-energy charged particles in space from the sun and from outside the solar system. It can especially degrade or damage living things, such as astronauts, and electronics in spacecraft. As we enter a period with a greater presence in space, promising a new age of exploration and economic growth, there is a need to understand the effect of radiation on people and electronics and how to mitigate its harmful effects.
		+
		+	[[Future_space_training\|'''Read more''']]

	== '''Coherent Electron Cooling: A Futuristic Technology''' ==		== '''Coherent Electron Cooling: A Futuristic Technology''' ==

@@ Line 29: / Line 29: @@
 == '''Coherent Electron Cooling: A Futuristic Technology''' ==
-[[Image:atf1.jpg|600px|Image: 1200 pixels|center]]
+[[Image:cec1.png|600px|Image: 1200 pixels|center]]
 Physicists and engineers who create particle accelerators are often working on such new, cutting edge ideas that they have yet to be implemented in practice.  One such idea is Coherent electron Cooling (CeC) which would help to provide powerful beams of colliding particles in significantly less time than other techniques.  It uses the coherent responses of the electrons in an electron beam to reduce or maintain the emittances of a circulating particle beam in a storage ring.  The CeC technique has not been yet demonstrated experimentally but efforts are underway to do just that.

← Older revision		Revision as of 14:34, 14 June 2023
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	[[Fund_Accelerator\|'''Read more''']]		[[Fund_Accelerator\|'''Read more''']]

		+	== '''Coherent Electron Cooling: A Futuristic Technology''' ==
		+
		+	[[Image:atf1.jpg\|600px\|Image: 1200 pixels\|center]]
		+
		+	Physicists and engineers who create particle accelerators are often working on such new, cutting edge ideas that they have yet to be implemented in practice. One such idea is Coherent electron Cooling (CeC) which would help to provide powerful beams of colliding particles in significantly less time than other techniques. It uses the coherent responses of the electrons in an electron beam to reduce or maintain the emittances of a circulating particle beam in a storage ring. The CeC technique has not been yet demonstrated experimentally but efforts are underway to do just that.
		+
		+	[[CeC\|'''Read more''']]

	== '''Wakefield Accelerators: Miniaturized yet Powerful '''==		== '''Wakefield Accelerators: Miniaturized yet Powerful '''==

← Older revision		Revision as of 16:41, 3 January 2023
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	[[Next_generation_talent\|'''Read more''']]		[[Next_generation_talent\|'''Read more''']]
		+
		+	== '''Fundamentals of Accelerators Course – Learning by Doing''' ==
		+
		+	[[Image:atf1.jpg\|600px\|Image: 1200 pixels\|center]]
		+
		+	Fundamentals of Accelerator Physics and Technology is the second in a two course series at Stony Brook University on accelerator science and technology. The purpose of this course is to introduce the fundamentals of beam physics via experimental investigation and beam dynamics simulations on scaled experiments employing electron beams. The course is 25% lecture, 30% simulation and 45% experimental.
		+
		+	[[Fund_Accelerator\|'''Read more''']]
		+

	== '''Wakefield Accelerators: Miniaturized yet Powerful '''==		== '''Wakefield Accelerators: Miniaturized yet Powerful '''==

@@ Line 29: / Line 29: @@
 == '''RF Superconductivity for Accelerators in a Course  '''==
-[[Image:650MHz.jpg|600px|Image: 1200 pixels|center]]
+[[Image:Tesla 9cell.jpg|600px|Image: 1200 pixels|center]]
 A game changing technology for accelerator design and operation is the use of radio frequency superconductivity. It allows much more energy efficient and also much more powerful accelerators to be constructed and utilized.   The science and technology of radio frequency (RF) superconductivity involves the application of superconductors to RF devices. The Stony Brook University course PHY 543 (RF Superconductivity for Accelerators) is about the application of RF superconductivity to the acceleration of charged particles (electrons, positrons, protons, ions).
 [[RF_Superconductivity|'''Read more''']]
 == '''High Power RF – Working at the Extremes  ''' ==

← Older revision		Revision as of 16:55, 29 November 2022
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	== '''RF Superconductivity for Accelerators in a Course '''==		== '''RF Superconductivity for Accelerators in a Course '''==
		+
		+	[[Image:650MHz.jpg\|600px\|Image: 1200 pixels\|center]]

	A game changing technology for accelerator design and operation is the use of radio frequency superconductivity. It allows much more energy efficient and also much more powerful accelerators to be constructed and utilized. The science and technology of radio frequency (RF) superconductivity involves the application of superconductors to RF devices. The Stony Brook University course PHY 543 (RF Superconductivity for Accelerators) is about the application of RF superconductivity to the acceleration of charged particles (electrons, positrons, protons, ions).		A game changing technology for accelerator design and operation is the use of radio frequency superconductivity. It allows much more energy efficient and also much more powerful accelerators to be constructed and utilized. The science and technology of radio frequency (RF) superconductivity involves the application of superconductors to RF devices. The Stony Brook University course PHY 543 (RF Superconductivity for Accelerators) is about the application of RF superconductivity to the acceleration of charged particles (electrons, positrons, protons, ions).

← Older revision		Revision as of 14:25, 7 November 2022
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	[[Wakefield_Accelerators\|'''Read more''']]		[[Wakefield_Accelerators\|'''Read more''']]
		+
		+	== '''RF Superconductivity for Accelerators in a Course '''==
		+
		+	A game changing technology for accelerator design and operation is the use of radio frequency superconductivity. It allows much more energy efficient and also much more powerful accelerators to be constructed and utilized. The science and technology of radio frequency (RF) superconductivity involves the application of superconductors to RF devices. The Stony Brook University course PHY 543 (RF Superconductivity for Accelerators) is about the application of RF superconductivity to the acceleration of charged particles (electrons, positrons, protons, ions).
		+
		+	[[RF_Superconductivity\|'''Read more''']]
		+

	== '''High Power RF – Working at the Extremes ''' ==		== '''High Power RF – Working at the Extremes ''' ==

← Older revision		Revision as of 16:17, 9 September 2022
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	[[Image:ATF.png\|600px\|Image: 1200 pixels\|center]]''[[Experimental Area At BNL ]]''		[[Image:ATF.png\|600px\|Image: 1200 pixels\|center]]''[[Experimental Area At BNL ]]''
−
−	~~File:ATF.png\|1200px\|center\|Experimental Area At BNL~~

	Wakefield Acceleration enables the miniaturization of accelerating structures by creating much higher-energy particles in the same footprint as the usual accelerators. There are only 5-10 universities in the USA that offer courses in this emerging field of Wakefield Acceleration. Stony Brook University is proud to be on this short list. This new concept will eventually usher in a new generation of compact accelerators and radiation sources. Equivalent sources of ultra-relativistic electrons, with miniaturized footprint, may one day be applied to high-energy colliders “to extend our understanding of the basic laws of [the] universe” according to the Plasma Science Report by the National Academies of Sciences, Engineering, and Medicine. In addition to fundamental physics research, applications of these electron sources include producing x-rays and gamma rays (currently equivalent to third-generation light sources) which will be a powerful enabling technology for medicine and industry.		Wakefield Acceleration enables the miniaturization of accelerating structures by creating much higher-energy particles in the same footprint as the usual accelerators. There are only 5-10 universities in the USA that offer courses in this emerging field of Wakefield Acceleration. Stony Brook University is proud to be on this short list. This new concept will eventually usher in a new generation of compact accelerators and radiation sources. Equivalent sources of ultra-relativistic electrons, with miniaturized footprint, may one day be applied to high-energy colliders “to extend our understanding of the basic laws of [the] universe” according to the Plasma Science Report by the National Academies of Sciences, Engineering, and Medicine. In addition to fundamental physics research, applications of these electron sources include producing x-rays and gamma rays (currently equivalent to third-generation light sources) which will be a powerful enabling technology for medicine and industry.

@@ Line 23: / Line 23: @@
 [[Image:ATF.png|600px|Image: 1200 pixels|center]]''[[Experimental Area At BNL ]]''
-<gallery widths=1200px heights=800px>
+File:ATF.png|1200px|center|Experimental Area At BNL
 File:ATF.png|center|Experimental Area At BNL
-</gallery>
 Wakefield Acceleration enables the miniaturization of accelerating structures by creating much higher-energy particles in the same footprint as the usual accelerators.  There are only 5-10 universities in the USA that offer courses in this emerging field of Wakefield Acceleration.  Stony Brook University is proud to be on this short list. This new concept will eventually usher in a new generation of compact accelerators and radiation sources.  Equivalent sources of ultra-relativistic electrons, with miniaturized footprint, may one day be applied to high-energy colliders “to extend our understanding of the basic laws of [the] universe” according to the Plasma Science Report by the National Academies of Sciences, Engineering, and Medicine. In addition to fundamental physics research, applications of these electron sources include producing x-rays and gamma rays (currently equivalent to third-generation light sources) which will be a powerful enabling technology for medicine and industry.