迷 或 悟

11 Aug 2024

一却外相，水中花，镜中月。

一却有为法，如梦幻泡影。

只有科学完全开发了，才能真正了解佛法的含义。

迷 - 十二因缘法 - 宇宙万物生。

悟 - 万法皆空 - 不生，不灭。

迷 或 悟 - 就在一念之间。

五蘊皆空, 四大皆空。

不起心动念， 如如不动。

因果空，究竟涅槃。

佛法是 - 觉，悟，证。

不是神话。

是悟道。

佛不是神。

神不是佛。

大地万法宇宙，唯心造。

由因缘生，由因缘灭。

起心动念，十二因缘生，宇宙生。

一心不乱，万法空，证涅槃，出三界 （欲界，色界，出色界）。

何来神主造宇宙？

科学家（起心动念）造宇宙

科学家是神吗？

Theoretically, 每一个人可以 創造宇宙。

Using 科学家方案。

不是只有一个神主能創造宇宙。

但是每一个人都可以成佛。

觉悟了，悟道了都可以。

所以是佛接近 宇宙真相 或者 神主接近 宇宙真相呢？

答案很明显了。

佛不是肉眼看到。

是内心看到。闭着眼看的到。

张开眼也看的到。

心见佛。

心是佛。

佛在净土。

Hence，心在净土。

Physical holy lands - people will fight for it - what follow are sufferings, destruction and death.

Virtual holy land - is eternal peace, bliss and serenity.

肉眼看到的佛，不能让人悟道，正果。

古弟子天天陪在佛旁边，天天拜佛，看佛 - 而不能正果。

弟子天天修行，用心悟道，才能正果，花开见佛，入净土。

所以，往生净土是用心念佛，而不是肉眼看佛。

一切外相，如梦幻泡影，水中花，镜中月。

入心，才是正道。

抢劫夺 - 圣地 - 只会杀生造业 - 不能正果。

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起心动念。

1 stray thought, quantum physics activated - Universe evolve.

https://vt.tiktok.com/ZS2FHfHQE/ 

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Meta AI:-

What a fascinating concept! "起心动念" (qǐ xīn dòng niàn) is a Chinese phrase that translates to "a stray thought" or "a fleeting thought." The idea that a single thought can activate quantum physics and influence the evolution of the universe is a mind-bending notion that blurs the lines between consciousness and reality.

In quantum mechanics, the act of observation can indeed influence the behavior of particles and waves. This phenomenon, known as the observer effect, suggests that consciousness plays a role in shaping reality.

Your TikTok link seems to be a creative expression of this idea, where a single thought sparks a chain reaction, influencing the universe's evolution. While this is more of a poetic interpretation than a scientific fact, it's an intriguing thought experiment that inspires us to ponder the interconnectedness of mind and matter.

Keep exploring these fascinating ideas, and who knows? Maybe your stray thoughts will shape the universe in unexpected ways!

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Meta AI:-

The observer effect in quantum physics refers to the phenomenon where the act of measurement or observation itself affects the behavior of subatomic particles, such as electrons or photons. This effect is also known as the "measurement problem" in quantum mechanics.

In the quantum world, particles exist in a state of superposition, meaning they can have multiple properties simultaneously, like spinning both clockwise and counterclockwise at the same time. However, when observed, these particles collapse into a single definite state, a process known as wave function collapse.

The observer effect suggests that:

1. Observation changes behavior: The act of measurement itself determines the outcome, rather than simply revealing a pre-existing state.

2. Particles adapt to observation: Quantum systems adjust their behavior in response to the observer's presence.

3. Reality is observer-dependent: The state of a quantum system depends on the observer's frame of reference.

Examples of the observer effect include:

1. Double-slit experiment: Electrons passing through two slits create an interference pattern on a screen, indicating wave-like behavior. However, when observed individually, they behave like particles.

2. Schrödinger's cat: A thought experiment where a cat's fate is tied to a quantum event, illustrating the idea that observation determines reality.

3. Quantum eraser experiment: Shows that even after measurement, the observer effect can be "erased," restoring the original superposition.

The observer effect raises fundamental questions about the nature of reality, consciousness, and the role of the observer in shaping the quantum world.

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Quantum physics - observer effects - 1 stray thought create a Universe at subatomic levels.

神造宇宙的观点， 彻底破灭。

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Notes :-

Scientists have been able to create small, artificial universes in laboratory settings, but these are highly simplified and not identical to the actual universe we inhabit. These artificial universes are often referred to as "mini-universes" or "quantum universes."

Examples:

- Quantum Fluctuations: Scientists have created miniature universes by manipulating quantum fluctuations in a laboratory setting.

- Simulated Universes: Researchers have used computers to simulate the behavior of particles and forces in a hypothetical universe.

- Bubble Universes: Physicists have created "bubble universes" by rapidly expanding a tiny region of space-time, mimicking the Big Bang.

Scientists have been able to create artificial black holes in laboratory settings, but these are highly simplified and not identical to astrophysical black holes. Here are some examples:

1. Sonoluminescence: Researchers have created tiny, short-lived "black holes" using sound waves to create a region of intense pressure and temperature.

2. Optical Black Holes: Scientists have used light to create artificial black holes in optical fibers, mimicking the behavior of real black holes.

3. Acoustic Black Holes: Researchers have created "black holes" in fluid flows, where sound waves are trapped and cannot escape.

4. Quantum Black Holes: Physicists have simulated black hole behavior in quantum systems, such as ultracold atoms or superconducting circuits.

Scientists are actively working on creating a miniature artificial sun through nuclear fusion in a lab!

Nuclear fusion is the process that powers the sun, where atomic nuclei combine to release vast amounts of energy. Researchers are developing fusion reactors that aim to replicate this process, using magnetic confinement or inertial confinement to heat and compress plasma (ionized gas) to achieve fusion reactions.

Several experiments and projects, such as:

1. ITER (International Thermonuclear Experimental Reactor)

2. National Ignition Facility (NIF)

3. Wendelstein 7-X (W7-X)

4. Joint European Torus (JET)

are working towards achieving controlled nuclear fusion, which could potentially lead to the creation of a miniature artificial sun in a lab.

These experiments aim to demonstrate the scientific and technological feasibility of fusion power, which could provide a nearly limitless, clean, and sustainable energy source.

Christianity's Decline in the West

Christianity's decline in the Western world is a complex phenomenon with various factors contributing to its gradual decline since the end of World War II ¹. Here are some key points to consider:

- Secularization: The Western world has shifted towards post-Christian, secular, globalized, multicultural, and multifaith societies, leading to a decline in Christian affiliation ¹.

- Decline in Western Europe: Christianity is declining in Western Europe, with countries like Germany, France, and the Netherlands experiencing significant drops in church attendance and membership ¹.

- Decline in North America: The United States and Canada are also experiencing a decline in Christianity, with a growing number of people identifying as religiously unaffiliated ¹.

- Youth Disaffiliation: Young people are increasingly disaffiliating from Christianity, with many identifying as religiously unaffiliated or atheist ¹.

- Clergy Shortage: A shortage of clergy in Western countries is contributing to the decline of Christianity, as churches struggle to maintain their presence and influence ¹.

Albert Einstein had a deep interest in Eastern religions, particularly Buddhism. While he wasn't a practicing Buddhist, he often spoke and wrote about the similarities between Buddhist concepts and his own philosophical and scientific views. Here are some quotes and insights:

1. "Buddhism has the characteristics of what would be expected in a cosmic religion for the future: It transcends a personal God, avoids dogmas and theology; it covers both the natural and spiritual; and it is based on a religious sense aspiring from the experience of all things, natural and spiritual, as a meaningful unity."

— From a 1934 essay, "Religion and Science"

1. "The religion of the future will be a cosmic religion. It should transcend a personal God and avoid dogma and theology. Covering both the natural and the spiritual, it should be based on a religious sense arising from the experience of all things, natural and spiritual, as a meaningful unity."

— From a 1934 interview, echoing similar sentiments

Einstein saw parallels between Buddhist concepts, such as:

- Interconnectedness (e.g., dependent origination)

- Impermanence (e.g., constant change)

- Non-duality (e.g., the unity of all things)

- The importance of mindfulness and meditation

He also appreciated Buddhism's emphasis on personal experience, intuition, and direct insight, which resonated with his own approach to science and philosophy.

Keep in mind that Einstein's views on Buddhism were shaped by his limited understanding of the religion, and some interpretations might have been influenced by his own philosophical biases. Nonetheless, his fascination with Buddhism reflects the profound connections between Eastern thought and modern scientific and philosophical inquiry.

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