静态网站悖论
个人网站的两种不同实现方式:一种是复杂的内容管理系统(CMS),另一种是简单的静态 HTML 文件。文章指出,尽管大多数普通用户倾向于使用复杂的解决方案(如 WordPress),但实际上,只有少数专业软件工程师能够选择更简单的静态网站。
via HackerNews 2024 10 09
前两天刚好听朋友说 square space 已经涨到了近乎搞笑的 $25 月费,做不用来盈利的个人博客实在难以 justify。这篇文章中吐槽得很在点子上:
normal users are stuck with a bunch of greedy clowns that make them pay for every little thing, all while wasting ungodly amounts of computational power to render what could have been a static website in 99% of cases.
普通用户被困在了一群屁大点功能都要收费的贪婪小丑手里,与此同时浪费着人神共愤额度的算力来渲染 99% 的情况下都可以作为静态的网站。
当然原文中说的“只有少数专业软件工程师才能选择更简单的静态网站”略微夸张并不认同,因为静态站至少是比 self-host 的动态 CMS 少太多维护了。我的 backlog 里也一直躺了篇安利新手用静态站并拉踩 WP 的文,不过网上这种文已经有无数了也还是拦不住前赴后继往各种 CMS 的坑里冲的新手,觉得写了又有什么意义呢就还搁着没写。(当然迟早会像以前反复造的无数轮子一样被废话欲战胜的 but not today)
#indieblog#newletter
🪐 Magnetars like Swift J1822.3−1606, discovered in the constellation Sagittarius, create magnetic fields over a trillion times stronger than Earth's—so intense they can distort atoms and transform empty space itself into a strange state called a “quantum vacuum.” These extreme conditions make magnetars some of the most powerful natural magnets ever found, unleashing bursts of high-energy X-rays and gamma rays that briefly outshine everything nearby. ✨
#magnetar⚡#neutronstar⚡#extremes⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 The magnetar PSR J1745−2900, found near the center of our Milky Way close to Sagittarius A*, showcases magnetic fields so intense they can disrupt atoms and twist space itself. Its field strength is estimated at over a quadrillion times higher than Earth's, making PSR J1745−2900 one of the most extreme magnets in the galaxy and a prime example of how magnetars stretch the laws of physics to their limits. ✨
#magnetar⚡#neutronstar⚡#extremes⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 Deep in the constellation Carina sits the magnetar 1E 2259+586, a neutron star with a magnetic field so powerful—over 100 trillion times stronger than Earth's—that it can twist and shatter its own crust. When this happens, it releases bursts of high-energy X-rays and gamma rays, briefly outshining entire galaxies before fading back into cosmic silence. ✨
#magnetar⚡#neutronstar⚡#extremes⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 In the constellation Ophiuchus, the neutron star PSR J1846–0258 stunned astronomers when it suddenly switched from behaving like a typical pulsar—flashing regular radio waves—to emitting powerful X-ray bursts, a feature seen in "magnetars," which are neutron stars with ultra-strong magnetic fields. This rare identity shift blurs the line between two of the most extreme types of dead stars, revealing the unpredictable and mysterious nature of cosmic objects. ✨
#neutronstar⚡#magnetar⚡#phenomena⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 The magnetar CXOU J171405.7−381031, found in the supernova remnant CTB 37B, is famous for its exceptionally strong magnetic field—over a thousand trillion times more powerful than Earth's. Such intense magnetism can twist the star’s crust, causing violent starquakes and bursts of high-energy radiation that briefly outshine everything else in its region of space. ✨
#magnetar⚡#supernova⚡#neutronstar⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 On August 27, 1998, astronomers detected a remarkable gamma-ray burst from the magnetar SGR 1900+14, located about 20,000 light-years away in the constellation Aquila. This event released more than a thousand times the energy of the Sun in just a fraction of a second, making it one of the brightest gamma-ray flashes ever recorded and proving that magnetars—neutron stars with ultra-strong magnetic fields—can unleash explosions powerful enough to briefly outshine entire galaxies. ✨
#gamma-ray-bursts ⚡#magnetar⚡#cosmic-explosions ⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 Deep in the constellation Vulpecula, the magnetar 1E 2259+586 unleashes magnetic fields so powerful—over 100 trillion times stronger than Earth's—that they can physically warp the star's crust. When these intense magnetic forces crack the surface, they release bursts of high-energy X-rays and gamma rays, briefly making the magnetar outshine every other X-ray source in its region of space. ✨
#magnetar⚡#neutronstar⚡#extrememagnetism⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 The magnetar named J1745−2900, discovered near the center of our galaxy close to Sagittarius A*, has one of the most powerful magnetic fields ever measured—enough to disrupt radio signals and, in theory, even deform atoms into thin strings. This type of neutron star is so incredibly magnetic that its field would erase every credit card on Earth from a distance of half the Moon’s span, making J1745−2900 an extreme natural magnet impossible to recreate in any lab. ✨
#magnetar⚡#neutronstar⚡#extremespace⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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🪐 The magnetar 1RXS J170849.0–400910, located about 18,000 light-years away in the constellation Ophiuchus, is known for its titanic magnetic field, which can reach over 100 trillion times the strength of Earth's. This intense magnetism is so powerful that it can twist the star's crust, triggering sudden bursts of X-rays and gamma rays—brief flashes that outshine entire regions of space before fading into darkness. ✨
#magnetar⚡#Xrays⚡#Ophiuchus⚡#nasa⚡#galaxy⚡#stars⚡#astronomy⚡#universe⚡#cosmos⚡#space
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