シャドーイング練習: The Magic of Thorium Nuclear Reactors - YouTubeで英語スピーキングを学ぶ
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Thorium is a kind of miraculous element.
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Thorium is a kind of miraculous element.
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Thorium found in nature isn't fissile – the atom's nucleus won't split when it absorbs a neutron.
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And yet, if you put a chunk of this same thorium in a special nuclear reactor,
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after a while most of the thorium will be gone,
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a whole bunch of energy will have been generated,
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and you'll be left with typical byproducts of fission.
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It's as if thorium is fissile, even though it's not.
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This is the genius of thorium breeder reactors.
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Oh, and I should disclose here that this video is sponsored by Copenhagen Atomics,
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who are working to make thorium power a reality,
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but they didn't get any say in the video and didn't get to review it before posting.
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The standard oversimplified picture of a fission reactor is,
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a uranium nucleus splits apart,
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or fissions, releasing heat energy and two or three neutrons,
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and those neutrons go on to be captured by more uranium nuclei and cause them to fission,
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releasing more heat energy and more neutrons, and so on.
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The heat is used to generate electricity,
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the neutrons to maintain the fission chain reaction.
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However, the actual story is more complicated.
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When a nucleus splits, there are actually four things that can happen to the neutrons it emits.
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One, like we've already mentioned,
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they can be captured by a fissile atom like uranium-235,
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causing it to fission and release more neutrons,
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and this part has to happen on average at least once per fission to sustain the chain reaction.
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Two, neutrons can be captured by the nuclei of other atoms in the reactor,
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without causing fission, like maybe the metal case,
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or the moderator, or the control rods, or whatever.
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3 Neutrons can escape and leave the reactor entirely.
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Or 4 A neutron can be captured by an atom that's not fissile,
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and transmute it into an atom that is fissile.
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Because remember, these are atomic nuclei we're dealing with.
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Absorption of a neutron will turn uranium-238 into uranium-239,
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the number is just the total number of protons and neutrons.
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And uranium-239 can then radioactively decay into neptunium-239,
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which can then decay into plutonium-239, which is fissile.
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If the capture of a neutron transforms a non-fissile element into a fissile one,
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it's called a fertile capture.
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And fertile capture is what makes thorium useful.
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In fact, even in a normal uranium reactor,
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fertile capture accounts for over a third of the energy generated by the reactor.
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A normal nuclear reactor uses uranium-235,
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which is fissile, but naturally occurring uranium ore contains only 0.7% uranium-235.
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Almost all the rest is uranium-238,
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which is essentially non-fissile, but it is fertile.
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Even when using fuels with enriched levels of uranium-235 undergoing fission,
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there's so much non-fissile U-238 around that some of the chain reaction neutrons instead transform U-238 into plutonium-239,
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which can then fission.
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But U-235 doesn't make enough neutrons,
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and U-238 doesn't turn into plutonium easily enough
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that you can both sustain a fission chain reaction and continue to transform new fissile fuel.
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So at the end you're left with a big chunk of unfissioned but still full of radioactive waste, uranium-238.
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There's a different kind of reactor,
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called a fast breeder reactor,
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that uses plutonium as the primary fissile fuel,
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and uranium-238 as a fertile secondary source.
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This combination can both sustain the fission chain reaction and transform new fuel in a self-sustaining way.
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But fast breeder reactors are less researched,
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more expensive, and harder to run effectively.
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For now.
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This is where thorium comes in.
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The same route used in the transformation of uranium-238 to plutonium-239 can be replicated down here,
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starting instead with thorium-232.
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By adding a neutron, we get thorium-233,
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which decays to protactinium-233, which decays to uranium-233,
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which is fissile and can be used to generate energy.
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So if you load your reactor with thorium-232,
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which, remember, is not fissile,
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and you throw in some starter fissile fuel,
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then for each fission reaction,
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the number of new fissile atoms created is more than one on average,
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and the number of new atoms split is more than one on average,
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and remember those atoms give you more neutrons.
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So the transformation of thorium,
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and the fission of uranium,
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can keep going and going and going,
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until in principle, all of the thorium is gone.
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And crucially, thorium transformation can happen in a reactor that doesn't have the same challenges as a fast breeder reactor,
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and it gets rid of most of the long-lived radioactive waste.
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And thorium is more abundant than uranium,
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and doesn't need the expensive refining process to concentrate the fissile uranium-235,
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and so you can see why people get excited about thorium.
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There are, of course, challenges and downsides to making thorium reactors,
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which is why we don't have and so far have never had commercial energy generation from thorium.
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But that's fertile material for another time.
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Getting commercial power from thorium may soon be possible thanks to the work of organizations such as this video's sponsor, Copenhagen Atomics.
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Copenhagen Atomics is building compact,
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modular thorium reactors to produce cheap energy.
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Unlike traditional nuclear power stations,
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which are giant infrastructure projects,
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Copenhagen Atomics are designing a self-contained reactor unit that can fit inside a shipping container.
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The reactors are based on a design pioneered over 50 years ago that uses molten salt to carry the fuel,
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resulting in fewer lost neutrons and more complete combustion,
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so you get more energy for less waste.
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These reactors can also use plutonium waste from classic nuclear reactors as fuel,
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extracting ten times more energy out of spent nuclear fuel than the initial reactor did in the first place,
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and in doing so converting long-lived radioactive waste into short-lived radioactive waste.
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In theory, these reactors could run anything from grids to ships to moon bases.
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Check out Copenhagen Atomics website to learn more about their work.
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このレッスンについて
このレッスンでは、トリウム核反応炉に関するビデオの内容を通じて、英語のシャドーイング技術を用いて英語スピーキングの練習を行います。ビデオは核エネルギーの仕組みについて解説しており、専門用語やフレーズが多く含まれています。このレッスンを通じて、英語シャドーイングの効果を体感し、リスニング能力と発音を向上させることができます。
重要な語彙とフレーズ
- トリウム (Thorium) - 核反応に用いる元素の一つ。
- 核分裂 (Fission) - 原子核が分裂する反応。
- 中性子 (Neutron) - 原子核の構成要素の一つ。
- エネルギー (Energy) - 物質が持つ力のこと。
- 富化 (Enrichment) - 核燃料の成分を増やすプロセス。
- 肥沃な捕獲 (Fertile Capture) - 非核分裂元素が核分裂元素に変わる過程。
- プルトニウム (Plutonium) - 核反応で生成される重要な元素。
- 反応炉 (Reactor) - 核反応を行う装置。
練習のヒント
このビデオのスピードは比較的速いですが、以下のアドバイスを参考にして英語のシャドーイングを効果的に行いましょう。
- ビデオを最初はスローモーションで再生し、話者の発音に合わせて声に出してみましょう。これにより、発音やリズムが取りやすくなります。
- 重要なフレーズや語彙に注目し、それらを繰り返し練習してみてください。「英語スピーキング練習」を行うことで、フレーズの使い方が定着します。
- ビデオの内容を自分の言葉でまとめながら、話してみることで理解を深めると同時に、スピーキング能力を向上させます。
- 「YouTubeで英語学習」を活用して他の関連動画も視聴し、多様な表現や語彙に触れることも大切です。
- 最後に、実際の会話で使用できるように「IELTS スピーキング対策」として、練習を続けてください。
シャドーイングとは?英語上達に効果的な理由
シャドーイング(Shadowing)は、もともとプロの通訳者養成プログラムで開発された言語学習法で、多言語習得者として知られるDr. Alexander Arguelles によって広く普及されました。方法はシンプルですが非常に効果的:ネイティブスピーカーの英語を聞きながら、1〜2秒の遅延で声に出してすぐに繰り返す——まるで「影(shadow)」のように話者を追いかけます。文法ドリルや受動的なリスニングと異なり、シャドーイングは脳と口の筋肉が同時にリアルタイムで英語を処理・再現することを強制します。研究により、発音精度、抑揚、リズム、連音、リスニング力、そして会話の流暢さが大幅に向上することが確認されています。IELTSスピーキング対策や自然な英語コミュニケーションを目指す方に特におすすめです。