Difference between revisions of "Nuclear Fusion"

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=Nuclear Fusion=
=Nuclear Fusion=
==Roadmap Overview==
The working principle and architecture of Laser Confined Nuclear Fusion is shown in the schematic below.
[[File:ICF Diagram 2.png]]
<ref name="Fusion">[https://lasers.llnl.gov/science/pursuit-of-ignition]</ref>
Nuclear fusion power generation fundamentally consists of fusing atoms to form heavier ones with a release of energy through neutrons. One of the main technology branches for demonstrating fusion power is Laser Confined Nuclear Fusion, LCNF which involves rapidly compressing a D-T (Deuterium-Tritium) fueled target pellet using some of the world’s most powerful lasers. The National Ignition Facility, at LLNL employs 192 UV laser beams at ~2MJ to converge on a gold cylinder, the size of a dime to generate x-rays and accelerate the fuel radially inward in less than 1 billionth to produce helium and high energy neutrons that could be captured to create a future energy source.
==Design Structure Matrix (DSM) Allocation==
[[File:T4DSM.jpg|1000px]]
The 2LCNF tree shows us that Laser Confined Nuclear Fusion is part of larger global Nuclear Fusion Power initiative to harness fusion power. The DSM and tree both show that 2LCNF requires the following technologies at the subsystem level 3: 3LAS Laser, 3TAR ICF Targets, 3DIA Diagnostics, 3CTP Cryogenic Target Positioning, and 3CHB Target Chamber. Each level 3 subsystem also require enabling technologies shown as level 4 systems.
==Roadmap Model using OPM==
The Object-Process-Diagram (OPD)  of the 2LCNF Laser Confined Nuclear Fusion is provided in the figure below. This diagram captures the main object of the roadmap, its various processes and instrument objects, and its characterization by Figures of Merit (FOMs). The '''Fusing Process''' is unfolded to show sub-processes and their instrument objects.
[[File:FusionOPL1.png|thumb|Object Process Language1]]
[[File:Fusion-OPL2.png|thumb|Object Process Language2]] [[File:FusionOPL-3.png|thumb|Object Process Language3]]
[[File:FusionOPL-4.png|thumb|Object Process Language4]]
[[File:FusionSD1.jpg|900px]]
Unfolding the '''Fusing Process''' at level SD1
[[File:FusionFusingUnfolded.jpg|800px]]
An Object-Process-Language (OPL) description of the roadmap scope is auto-generated and given below. It reflects the same content as the previous figure, but in a formal natural language.
==Figures of Merit==
The table below shows a list of FOMs by which Laser Confined Nuclear Fusion, LCNF can be assessed. FOMs on this list related specifically to fusion reactions, such as neutron and fusion yield are similar to other confined fusion experiments. For LCNF, the key FOMs are experiment implosion velocity, laser energy and neutron yield. Fusion yield is intrinsically related to neutron yield.
[[File:FOMteam4.png]]
Important FOMs such as implosion velocity and ITFX can be calculated from the equations in the table below. However, an understanding of neutron yield and thus fusion yield is found through both simulations and experiments in LCNF facilities.
[[File:Table-in-outputs.png]]<ref>Laser Indirect Drive input to NNSA 2020 report (LLNL-TR-810573)</ref>
Over the last 50 years, development of LCNF facilities enabled increases in laser energies (delivered to D-T fuelled targets) by 5 orders of magnitude. The National Ignition Facility, NIF at LLNL contains the world's most powerful laser.
[[File:Dopelasers2.png]]<ref>https://www.sseb.org/downloads/AM-2012/presentations/Dunne.pdf</ref>
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Revision as of 05:17, 12 October 2023

Nuclear Fusion

Roadmap Overview

The working principle and architecture of Laser Confined Nuclear Fusion is shown in the schematic below.

ICF Diagram 2.png <ref name="Fusion">[1]</ref>


Nuclear fusion power generation fundamentally consists of fusing atoms to form heavier ones with a release of energy through neutrons. One of the main technology branches for demonstrating fusion power is Laser Confined Nuclear Fusion, LCNF which involves rapidly compressing a D-T (Deuterium-Tritium) fueled target pellet using some of the world’s most powerful lasers. The National Ignition Facility, at LLNL employs 192 UV laser beams at ~2MJ to converge on a gold cylinder, the size of a dime to generate x-rays and accelerate the fuel radially inward in less than 1 billionth to produce helium and high energy neutrons that could be captured to create a future energy source.

Design Structure Matrix (DSM) Allocation

T4DSM.jpg


The 2LCNF tree shows us that Laser Confined Nuclear Fusion is part of larger global Nuclear Fusion Power initiative to harness fusion power. The DSM and tree both show that 2LCNF requires the following technologies at the subsystem level 3: 3LAS Laser, 3TAR ICF Targets, 3DIA Diagnostics, 3CTP Cryogenic Target Positioning, and 3CHB Target Chamber. Each level 3 subsystem also require enabling technologies shown as level 4 systems.

Roadmap Model using OPM

The Object-Process-Diagram (OPD) of the 2LCNF Laser Confined Nuclear Fusion is provided in the figure below. This diagram captures the main object of the roadmap, its various processes and instrument objects, and its characterization by Figures of Merit (FOMs). The Fusing Process is unfolded to show sub-processes and their instrument objects.

Object Process Language1
Object Process Language2
Object Process Language3
Object Process Language4

FusionSD1.jpg

Unfolding the Fusing Process at level SD1

FusionFusingUnfolded.jpg


An Object-Process-Language (OPL) description of the roadmap scope is auto-generated and given below. It reflects the same content as the previous figure, but in a formal natural language.

Figures of Merit

The table below shows a list of FOMs by which Laser Confined Nuclear Fusion, LCNF can be assessed. FOMs on this list related specifically to fusion reactions, such as neutron and fusion yield are similar to other confined fusion experiments. For LCNF, the key FOMs are experiment implosion velocity, laser energy and neutron yield. Fusion yield is intrinsically related to neutron yield.

FOMteam4.png

Important FOMs such as implosion velocity and ITFX can be calculated from the equations in the table below. However, an understanding of neutron yield and thus fusion yield is found through both simulations and experiments in LCNF facilities.

Table-in-outputs.png<ref>Laser Indirect Drive input to NNSA 2020 report (LLNL-TR-810573)</ref>

Over the last 50 years, development of LCNF facilities enabled increases in laser energies (delivered to D-T fuelled targets) by 5 orders of magnitude. The National Ignition Facility, NIF at LLNL contains the world's most powerful laser.

Dopelasers2.png<ref>https://www.sseb.org/downloads/AM-2012/presentations/Dunne.pdf</ref>











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