ARS

Why the design for reentry vehicle is always smooth-curved (like the underside of space shuttle or the design of Apollo/ Soyuz capsule). What if the reentry capsule/ vehicle design itself is viable for reentry but with highly angular design? (aka, same design, but all smooth and curved part is turned into blocky angular), compare Apollo/ Soyuz capsule with WH40k space marine drop pods

Does the solar reflector satellite in the Bond film "Die Another Day" actually makes sense in context of real-life application? It's said in the movie that the satellite is meant to focus solar energy on a designated area and provide year-round sunshine for crop development. Does this makes sense in real life concept of application? (even without the laser module, someone would came up with the idea to weaponize it). I mean, crop development is actually going normally today, with current day and night cycle. It's not like the crop needs sunlight exposure for 24/7 just for increased productivity, unless the daytime sunlight exposure is so dimly lit like post-nuclear winter that it necessitates direct sunlight reflection from space

In the fire triangle, there are 3 things needed to form a combustion: oxygen, heat and fuel. Modifying any of these parameter will change how things burn. In case of oxygen, if you're increasing the oxygen percentage of the atmosphere, it speeds up the process of combustion. Higher oxygen percentage on the atmosphere will create an even faster burning process. However, like in the fire triangle, things have to be balanced: Too much oxygen with too little fuel means the paper will be burned to ash almost instantly before the fire becomes self-extinguishing because there's nothing left to burn. Too much fuel with too little oxygen means the fire will also self-extinguishing before the paper fully burned because there's not enough oxygen to sustain the process. By default, oxygen itself is not flammable, but it does support and required for the combustion process, adding more just accelerate it or even makes things catch fire at lower temperature (that doesn't stop early alchemists and researchers calling it "Fire air"). If you want paper to burn at a temp higher than F451, the parameter you need to change in the triangle is the fuel (aka the paper itself), not the oxygen content (some materials do becomes significantly more combustible (more reactive) than usual in high oxygen environment, look no further than Apollo 1 fire that killed 3 astronauts)

So... I found a stuff on Youtube that compressed a compilation of songs (around 60 minutes of songs) into 2 seconds-video. The idea is if you played the song at super ultra-slow speed, you could listen the entire song. So I'm wondering, if audio files can be compressed into shorter length (for example, to send a secret message in a particular segment of a song), is there a limit of message length that can be compressed into 1-second audio before it starts to be unreadable as a message (aka, just garbled noise no matter how slow it's played, like the pixels on "zoom and enhance" situation)?

Does the heat propagation (from hot object to cold object) affected by the temperature difference between the 2 objects? Does the greater the difference means the colder object more "receptive" towards the heat from hotter object? For example: There's a hot iron rod with a temperature of 100 ºC. The temperature is uniform on the surface of this iron rod. Now we attach 3 iron rods at once (all touching the hot iron rod at the same time), but each of them has different temperature: rod A is at 70 ºC, rod B is at 35 ºC and rod C is at 0 ºC Does the rod C more "receptive" with heat propagation because of it's much larger temperature difference with the hot iron rod compared with the other 2? (in other words, rod C is prioritized more for heat flow than rod A and B)

Could tornadoes be dispersed by detonating a tactical nuke (or sufficiently large bomb) in the eye of it? I mean, the explosive shockwave displace large amount of air instantly that should, in theory disrupt tornado's vortex and causes it to dissipate

Does explosive-tipped arrow makes sense or actually useful in real life?

Does this situation possible considering how light reflects off a reflective surface? 2 Snipers are hunting each other. They are elite soldiers expert in camouflage. At one point, while both are under camouflage, and facing each other (they're not aware they are staring at each other), the sun is positioned in such a way that the sunlight glints from the scope's lens of both of them (basically they see the scope glint of each other, not just only one of them) Also, since lasers can reflect off reflective surface, is it possible for sufficiently powerful laser to not reflect off reflective surface at all simply by burning through it from the sheer amount of heat at the moment of contact? Basically a laser that melts through the mirror it's supposed to reflect off

Weird, I often left my mining outpost unattended and never had any problems like that. Maybe you need more radiators? Forgot to activate it? Or maybe it's just a glitch. I don't know, but for my 3 years playing KSP I never had such a problem. Though my mining outpost is also beyond the timewarp range since the main base is very far away, so maybe timewarping while it's still in range might cause it

I wish that the kerbals have specialized EVA suit based on their job occupation, complete with specialized abilities and features. I've made a concept for it long time ago Pilot: can use maneuver nodes while in EVA, jetpack has extra fuel and has more powerful thrusters strong enough to be used as actual jetpack on atmospheric condition. Suits has much more G and heat tolerance. Maneuverability and controls for EVA movement is more responsive. Parachute has more air control. More options while piloting craft such as "leveling aircraft" Engineer: can use mining auger to perform small scale mining, with onboard micro ISRU providing refueling capabilities for EVA jetpack for self or other kerbals. Has onboard solar panels on EVA suit that can be used to passively recharge nearby batteries or drone cores. Has a small onboard antenna to transmit science report from nearby Kerbal or craft (it's much weaker than even the weakest antenna, but better than nothing). Has brighter and wider flashlight illumination area Scientist: can carry handheld experiments and other scientific instrument items on EVA backpack's slot, allowing the science experiments to be conducted with boots on the ground (different from the one slapped on the craft of plopped on the ground). Automatically refresh the non-repeatable experiments and has more options for "no tool science" than pilot or engineer while on the ground other than "take surface sample" and "sitrep". Can store several science report of the same type (but not unlimited like experiment storage box). Reduced scientific efficiency loss when collecting same science report over and over again

I prefer they take their time to finish and polish KSP2, even of it means delaying the release date. Glitch and bugs at release is inevitable, no game is perfect, but there's a major difference between glitch/ bugs that occurs during normal plays and those that happens during abnormal play. Take KSP for example, if your SSTO suddenly stages it's part in flight even though it has no staging at all, then yeah, that's a very serious one that isn't supposed to happen in normal play. On the other hand, the one that happens during the abnormal play is the one that happens during action that the player does not expected to do in normal play, like how Danny2462 found all of his game breaking shenanigans because you're not supposed to grab Kerbal and pull them apart with 2 asteroid grabbing claws. Though this also makes me say that, in the eyes of Kerbal: "there are no glitches/bugs in KSP, only krakens"

This turns out to be much longer than what I expected. Ok to clarify some stuff, I have a task in my metallurgical department. Let's just say we're measuring the atomic distance of a cupronickel alloy sample (apologize for the confusion about compound and alloy) in material's lab (each group may or may not get the same sample). The goal is to find the distance between atoms in the crystalline structure of the sample, first the distance between the atoms of same types (Cu with Cu, Ni with Ni) and the second is the distance between the atoms of different type (Cu with Ni). Things go as planned before suddenly, in the middle of operation, the test machine broke (can't blame it, it's kinda old anyway). We asked the teacher for the solution for this and basically it boils down to the "if the actual test can't be performed, then use the mathematical calculations to find it out" Now we could calculate the atomic distance of individual types when it's separated, but for the atomic distance for alloys, things get complicated. The ratio of cupronickel in question is 3:1, the distance from each Ni atoms should be uniform, same case with Cu. The main question is, how to calculate the distance between Ni and the nearest Cu atom inside the cupronickel alloy, and the distance between Ni atoms with each other in cupronickel allow with a ratio of 3:1 (assuming Ni atoms distributed evenly), it doesn't matter if it's exact value or approximate value (if we change the ratio, then the distance between Cu and Ni should be different too, right?)

Thanks!

[Moderator's note: This topic was originally split off from For Questions That Don't Merit Their Own Thread, since the ensuing discussion turned out to be a lengthy one.] Is it possible to calculate the distance between molecules on a metal compound purely by mathematical calculation as long as we know the ratio of the metals used, density and molar mass of each metal as well as the resulting shape of the crystal matrix of the compound? Assuming that the metal constituent is evenly distributed in ideal condition

From VAB: Stock rocket that malfunctions shortly after liftoff because of premature staging that caused the whole rocket to break apart From SPH: A horribly unbalanced plane that spins out of control and explodes before it even lifts off

Considering their appearance, behaviour and their stupidity (or suicidal overconfidence) tendencies, then yeah, I consider them cute, especially their expression of joy (or terror) when their aircraft are barrel rolling towards the cliffside at 1200 km/h with one wing missing (I still try to not them get killed though. Planes are easy to replace, skilled personnel are not)

The An-225 Mriya has twintail design to mitigate the lack of airflow when Buran is loaded on top the fuselage by moving the rudders on the sides. If for example, on aircraft with large propellers on wings placed directly on the way of rear twintail with short fuselage length, (think V-22 Osprey design) does the fast-moving airflow from behind the propellers hitting on twintail rudders actually improves rudder performance compared with regular airflow without propellers in front of the twintails?

Is there any reason or backstory why prototype model is almost always referred as "mark" (like mark.1, mark.2, mark.3, etc.) or "object" for Soviet/Russian-made ones (object 279, object 195, object 252, etc.)?

Thanks for the answer. It really helps me to define the changes of energy between cold and hot temperature. I got the idea for the question when I stumbled upon a sentence: "...coldness isn't energy, but rather lack of it (from the point of view of our environment's parameters)..."

Is it correct when I said "Cold is the state of non-energy, the opposite of hot where there's a lot of energy"?

The answer is … no, and I don't think it worked that way... Let me explain. You see, Most major planets in our solar system stay within 3 degrees of the ecliptic. Mercury is the exception; its orbit is inclined to the ecliptic by 7 degrees. The dwarf planet Pluto is a widely known exception to this rule. Its orbit is inclined to the ecliptic by more than 17 degrees. It makes sense that most large planets in our solar system stay near the ecliptic plane. Our solar system is believed to be about 4 1/2 billion years old. It’s thought to have arisen from an amorphous cloud of gas and dust in space. The original cloud was spinning, and this spin caused it to flatten out into a disk shape. The sun and planets are believed to have formed out of this disk, which is why, today, the planets still orbit in a single plane around our sun Since Jupiter is already at the current ecliptic plane, it makes sense that any planets in the early age of solar system that's not at the ecliptic plane would be either thrown out or forced into the current ecliptic plane. However, this is extremely unlikely as most of the planets are formed near-simultaneously on the ecliptic plane, their largest deviation of inclination from the ecliptic plane should be few degrees at best. This doesn't really apply on the planets that sits on the outer edge of the solar system though. Pluto for example has 17 degrees of deviation in inclination. At that distance, Jupiter's gravity is too weak to influence Pluto's orbital plane. As you peer further into deep space, many Trans-Neptunian objects in deep space have extreme deviation from solar ecliptic plane. Some of these are legitimately formed at the same time as the solar system, but most of them are captured kuiper belt or oort cloud object In any case, it seems that the main driving point of the orientation of the ecliptic plane is the star at the center of the system itself. The massive gravity well it emits defines the plane itself in the first plane when the system are born. This massive gravity field also affects the angle of the entire system's ecliptic plane relative to the galactic core, depending on the star's rotation and inclination as it formed. But what about double star system? Surprisingly, it affects the ecliptic plane too! With a young double star system – surrounded by a planet-forming disk – whose disk lies at right angles to the orbits of the two central stars. In other words, the two stars do orbit more or less in the plane of each other’s equators. But their star-forming disk has flipped up over the orbital plane of those stars. It’s oriented instead above the stars’ poles This, of course raises an even bigger question: What the ecliptic plane of the trinary star system looks like?

When a tensile test is performed on a metal sample, after the sample breaks, there's a noticeable heat on the sample, with harder metal typically giving off more heat than softer ones. My question is, does this heat actually come from the kinetic energy of pulling the sample apart (and converted into heat before the sample finally breaks)? Does the amount of total heat on the sample equal with the total energy required to break that sample?

The real joke here is, WHAT IN THE HELL (pun intended) YOU'RE BUILDING A BASE ON VENUS!? I get it with the moonbase on the previous game because moon is Earth's closest neighbor and it's low gravity is at least useful for assisting further space mission in terms of logistic and launch infrastructure, but a freakin' Venus!!? There's nothing to mine there, no resources except corrossive sulphuric acid, building infrastructure is a nightmare, and it has no strategic importance at all since the 3rd reich is pretty much controlling the space. It's just a huge money sink with no actual benefit. I get it that ODIN codes are certainly at the same level of importance as nuclear missile codes, but to build a base in Venus just for that!?

What's the best guidance systems used on missiles for space battles? Especially the one that takes place in-orbit of a planet? Could normal missile guidance be used normally? (Infrared, heatseeking, radar-guided, laser-guided etc.)

What do you call a government that works by: 1. The country is ruled by king (if male) or queen (if female) from monarchy. A single noble family holds a central authority 2. If the current ruler dies or incapable of ruling anymore, the eldest descendant (male or female) take their place 3. The country is divided into several states with one state acting as central authority where the king/ queen lives and ruled the entire country and other states 4. The states are ruled by the descendants/ relatives of the family, each have their own jurisdiction and rules for their states, but all of them obey the central authority. The state's ruler also follows the central authority method of transfer of power (for example, if the king dies, the eldest son (let's say his name is A) of state X takes the throne and his son inherit the state X. If A dies, the next eldest member of state Y (lets say his/her name is B) takes the throne while B's son/ daughter inherit the state Y) 5. Each states are allowed to have their own military force that's commanded by the ruler of that state and central authority, but obey the latter if the orders from both sides are contradictory 6. Each states strives for the prosperity of their own people, but also required to contribute for the prosperity of the entire country (either by exporting goods for developing other states or helping them by sending military aid in times of war) Note that said country is rather small in terms of habitable landmass. Most of the country consists of uninhabited mountain peaks with small amount of states (around 4-5 plus the central authority state)