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A phase is a portion of a substance where all the properties—like temperature, density, and chemical makeup—are essentially the same throughout, and it's often physically separate from other parts of the material. Understanding phases matters because it helps us predict how substances behave and change, such as when water turns to ice or steam, and how different materials interact with each other.
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Phases – The Physics Hypertextbook
The 3 most famous phases of matter are solid, liquid, and gas. Did you know that glass is also a phase? Or that plasma is the most common phase in the universe?, The 3 most famous phases of matter are solid, liquid, and gas. Did you know that glass is also a phase? Or that plasma is the most common phase in the universe?
physics.info →Notes from some long forgotten source. "Chaos (χαος) was used to define the most disperse and fluid state of matter, that in which no particular order could be observed. Interestingly enough, when van Helmont wanted to refer to steam-state of materials he was studying used the term chaos but in the particular Flemish accent, converting it to gas, by which the state is known to us today." To my mind it appears that the difficulty is only imaginary and not real. Rigidity and plasticity are not absolute terms but relative, and all solids are in fact both rigid and plastic. The apparent contrast between the two properties belongs to the laboratory and to those phenomena of nature involving small masses and small forces. When great masses and great forces are involved, as for example in the making of continents and mountain chains, the distinction loses value. The phenomena of mountain structure demonstrate that under sufficient strains great bodies of rock both bend and flow. Increased pressure increases the range of temperatures over which a substance can exist as a liquid. Reduced pressure reduces this range. At a certain special pressure the boiling and melting points will equal, and the substance can no longer exist as a liquid. Below this pressure, the only possible phase transition is from solid to gas (and vice versa). This phase change is called sublimation (the reverse process is called deposition or desublimation) and the temperature at which it occurs is called the sublimation point (or sublimation temperature). That's the essence of the upcoming discussion. If this is enough info for you, stop reading and jump to the next section. If you want to understand what I'm talking about then keep reading. Knowing why some phenomenon occurs is often more important than knowing that it occurs. (Of course, the reverse is also true, which is why I offer you the option to read on or jump ahead.) To a certain extent, liquids are like a minimum security prison. (Solids are like a maximum security prison in permanent lock down, but that's another matter.) The molecules within have limited freedom and can only leave infrequently or with great effort. As long as a liquid has some surface area exposed to the atmosphere, here and there a molecule within the liquid near the surface will be moving fast enough to escape the liquid prison and enjoy the freedom of a vapor molecule in the surrounding atmosphere. But rather unlike a a prison, the reverse process is also possible. From time to time, a molecule in the atmosphere will be traveling fast enough to plow its way through the tightly guarded walls of the liquid only to find itself trapped within. Both events are happening simultaneously, but not necessarily with equal probability. What is boiling and how is it different from evaporation? Both processes involve the same liquid to gas phase transition, but where evaporation can occur at any temperature boiling occurs only at a specific temperature. Let's return to the description of evaporation just discussed. Evaporation occurs whenever more molecules leave a liquid than enter. Condensation occurs whenever more enter than leave. These changes are driven by the concentration of liquid molecules in the atmosphere. When their concentration is low, it's more likely that molecules will leave the liquid phase than enter it, so evaporation rules. When their concentration is high, it's more likely that molecules will enter the liquid phase than leave it. When neither process dominates it must be because the atmosphere has just the right concentration of liquid molecules floating around within it — no more, no less than what it can handle. Under these circumstances the atmosphere is said to be saturated. The most energetic vapor molecules present in the atmosphere are fighting their way into the liquid. The most energetic liquid molecules are fighting their way out into the atmosphere. There's room in the atmosphere, but it has a limit. When
相(そう、英: phase)とは、化学的組成及び物理的状態が一様な物質系の実体である。 相とは化学組成及び物理的状態が全体的に一様な形態のものである。 気体、液体、固体は、物質の三つの形態(物質の三態)として知られているが、固体や液体には複数の違った形態をとる場合があることもまた知られている。そこで、これらを区別する別の用語が必要になる―それに相という用語が使用される。 例えば完全に溶解した食塩水はどの部分を取り出しても同一の組成、物性を示すので1つの相だけからなる。氷水はどの部分を取り出しても水分子だけからなる同一の組成を持つが、固体と液体という異なる物性を示す2つの部分があるので、その氷が一つの塊であろうと、クラッシュアイスであろうと、2つの相からなる。 牛乳のようなコロイド溶液は肉眼ではどの部分も同じように見えるが、限外顕微鏡でみると乳脂肪からなる油滴の部分と水の部分に分かれているので2つの相からなる。 また、たとえば土壌は、固相、液相(水相)、気相の三相からなり、固相は土壌粒子、気相は土壌空気、水相は土壌水と呼ばれる。また、大気は、そのほとんどを気相が占めるが、エアロゾル(厳密にはエアロゾル分散媒)が清浄な空気でも8 x 10-5 m3-エアロゾル/m3-大気が存在する。 エアロゾルは、水相と固相の二相からなるので、大気もまた、固相、気相、液相の三相により構成される。 もっとも分かりやすい相の分類は固相、液相、気相であろう。多くの純物質は温度や圧力を変化させた場合、固体、液体、気体の3つの状態をとる。これらそれぞれの状態に対応する相が固相、液相、気相である。ただし、多くの物質は複数の固相を持つ。たとえば * 固体の硫黄には斜方硫黄と単斜硫黄があり、これらは別の相である。 * 炭素にはグラファイト、ダイヤモンド、フラーレン構造などの形態が存在する。 * 炭酸カルシウムは方解石とアラレ石のかたちで存在する。 * 氷には少なくとも12種類の形態が存在している。 ヘリウムは複数の液相を持つ。水も2つの液相があると言われている。気相を複数持つ物質はない。また、液晶など、別の相を持つ物質もある。 飽和した砂糖水を冷却すると、溶けきれなくなった砂糖が固体として析出する。このように1つの相が複数の相に分離することを相分離という。 液体の水を冷却すると1気圧下では0℃で氷(固体の水)となり、加熱すると100℃で水蒸気(気体の水)となる。このように1つの相の温度や圧力を変化させた場合、2つの相の共存状態を経て別の1つの相へと変化することがある。これを相転移という。 ある系の組成や圧力、温度(状態変数)を指定したときに熱力学的平衡状態でどのような相を取るかを示した図を相図という。また、平衡状態にある系内の相の数と変化できる状態変数の数(自由度)と成分の数の間には相律という関係が成立する。 固体、液体、気体の3相の他に、プラズマ、ボース=アインシュタイン凝縮がそれぞれ物質の第4、第5の相とされることがある。
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Discovered by embedding cosine similarity (sentence-transformers MiniLM, 384-dim).
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