esybeast
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same lmao
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Physics Predictions/Thoughts (4 Viewers)
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from what I’ve been hearing and how I found it, around 85 for band 6 cutoff
nsw..wollongong
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is that just bc it was an easy test or does phys always scale like this?
Rattlehead15
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Easy test. Physics usually scales high 70s-low 80s. Last year was a massive outlier and this one probably will be to a lesser extent so maybe theyre tryna make physics an easier subject now idk
in 2019-21 it was decent alignment/scaling but 2022 aligned awfully and scaled worse asw, and I think the consensus is this year was slightly harder than that
nsw..wollongong
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slightly harder but still rlly easy? everyone im talking to is so confident abt the test its crazy
yeah still definitely easy compared to 19/20/21slightly harder but still rlly easy? everyone im talking to is so confident abt the test its crazy
chem was slightly easier than usual asw, maybe 86 or so
natsnapshoot
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Similar to last year, which was 85
scaling in chem last year was quite generous though which makes up for it
natsnapshoot
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Well yeah, the average Chem student probably would have found it harder than last year so it should be ok
scaryshark09
∞∆ who let 'em cook dis long ∆∞
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75 english would be around 83
65 ext 2 would be around 89
Rattlehead15
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Does anyone have physics solutions 
Most of them are done by eddie:Does anyone have physics solutions
1-20: DCCBDDCBADABCCACBABD
Last edited:
esybeast
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For question 24, Would you have to say the direction of the B-field?
Here is a solution to 33 but it is not eddie's
The statement that the interaction of subatomic particles with fields, as well as with other types of particles and matter, has increased our understanding of processes that occur in the physical world and of the properties of the subatomic particles themselves is supported by a vast body of experimental evidence and observations. Here are some key points that justify this statement:
In summary, the interaction of subatomic particles with fields, other particles, and matter has been a cornerstone of modern physics, leading to the development of fundamental theories and significantly advancing our understanding of the physical world and the properties of subatomic particles. This understanding has not only deepened our knowledge of the fundamental forces of the universe but also had practical applications in a wide range of scientific and technological fields.
The statement that the interaction of subatomic particles with fields, as well as with other types of particles and matter, has increased our understanding of processes that occur in the physical world and of the properties of the subatomic particles themselves is supported by a vast body of experimental evidence and observations. Here are some key points that justify this statement:
- Quantum Field Theory: One of the most successful theories in modern physics is quantum field theory. It describes how subatomic particles interact with fields, such as the electromagnetic field (described by quantum electrodynamics) and the strong nuclear force field (described by quantum chromodynamics). These theories have been tested and validated through numerous experiments, and they provide a profound understanding of how particles interact with these fields.
- Discovery of Subatomic Particles: Through experiments with particle accelerators, scientists have discovered numerous subatomic particles, such as electrons, protons, neutrons, quarks, and more. These discoveries have greatly expanded our knowledge of the fundamental building blocks of matter and their properties.
- Fundamental Forces: The interaction of subatomic particles with fields is responsible for the fundamental forces in the universe, such as electromagnetism, gravity, and the strong and weak nuclear forces. The study of these interactions has led to a deeper understanding of the nature of these forces and how they govern the behavior of matter on both cosmic and microscopic scales.
- Unification of Forces: The study of subatomic particles and their interactions has led to the development of grand unified theories and the quest for a theory of everything. These theories aim to unify the fundamental forces and have made significant progress in bringing together the forces of the Standard Model (electromagnetic, weak, and strong) into a single, coherent framework.
- Cosmic Observations: The interaction of subatomic particles with fields and with cosmic matter has also increased our understanding of the universe's evolution. Observations of cosmic microwave background radiation, for instance, have provided insights into the early universe and its properties, and these observations are closely tied to particle physics principles.
- Particle Colliders: Experiments at particle colliders, such as the Large Hadron Collider (LHC), have allowed scientists to recreate extreme conditions that existed shortly after the Big Bang. These experiments have provided crucial insights into the properties of subatomic particles, the Higgs boson's discovery, and the validation of the Standard Model.
- Applications in Technology: Our understanding of subatomic particles and their interactions has also led to the development of many technologies, including nuclear power, particle beam therapy for cancer treatment, and particle detectors used in various fields, from medical imaging to materials science.
In summary, the interaction of subatomic particles with fields, other particles, and matter has been a cornerstone of modern physics, leading to the development of fundamental theories and significantly advancing our understanding of the physical world and the properties of subatomic particles. This understanding has not only deepened our knowledge of the fundamental forces of the universe but also had practical applications in a wide range of scientific and technological fields.