b. the wave with the highest amplitude
c. a longitudinal wave
d. the wave that strikes a solid barrier with the slowest speed.
15 points answer!
Answer:
A
Explanation: bc it has more stuff to hit
The wave with the longest wavelength will probably be diffracted the most. This is because diffraction, or the bending of waves around obstacles, is closely related to the wavelength of the wave. The longer the wavelength, the more a wave tends to diffract.
The wave that will probably be diffracted the most is a. the wave with the longest wavelength. Diffraction is the bending or spreading of waves as they encounter an obstacle or gap. This concept is closely related to the wavelength of a wave, which is the distance between one wave crest and the next. The longer the wavelength, the more a wave tends to spread out or diffract around obstacles. This is why low-frequency sound waves (which have long wavelengths) can easily be heard around corners, but high-frequency light waves (with their shorter wavelengths) are largely blocked by obstacles.
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Answer:
...in that Eukaryotes have membrane bound organelles, and prokaryote cells do not have a nucleus
Answer:
A blue room
Explanation:
Green light is the least effective for plants because they are themselves green due to the pigment Chlorophyll.. Blue light helps encourage vegetative leaf growth, and red light encourages flowers. this happens because the amount of blue, red and far red spectrum of light that reaches the planet changes with the seasons. As days start to get longer, more blue spectrum light reaches the surface of the earth. This initiates a vegetative growing stage for most plants leading into the spring and early summer. As the days start to grow shorter, and more of the red and far red spectrum reaches the surface, it leads into the late summer and fall reproductive season.
Answer:
Climax community
Explanation:
Knowing the correct order of information, specifically state what is occurring in Process #1 and in Process #2.
Please be very specific in your answer as i cannot assume which blank and process you are referring to. Be sure to provide this information and to have your blanks noted in the correct order
PLEASE ANSWER ME ASAP
Answer:
The central dogma of molecular biology explains the flow of genetic information, from DNA ?to RNA?, to make a functional product, a protein?.
The central dogma suggests that DNA contains the information needed to make all of our proteins, and that RNA is a messenger that carries this information to the ribosomes?.
The ribosomes serve as factories in the cell where the information is ‘translated’ from a code into the functional product.
The process by which the DNA instructions are converted into the functional product is called gene expression?.
Gene expression has two key stages - transcription? and translation?.
In transcription, the information in the DNA of every cell is converted into small, portable RNA messages.
During translation, these messages travel from where the DNA is in the cell nucleus to the ribosomes where they are ‘read’ to make specific proteins.
The central dogma states that the pattern of information that occurs most frequently in our cells is:
From existing DNA to make new DNA (DNA replication?)
From DNA to make new RNA (transcription)
From RNA to make new proteins (translation).
Illustration showing the flow of information between DNA, RNA and protein.
An illustration showing the flow of information between DNA, RNA and protein.
Image credit: Genome Research Limited
Reverse transcription is the transfer of information from RNA to make new DNA, this occurs in the case of retroviruses, such as HIV?. It is the process by which the genetic information from RNA is assembled into new DNA.
Does the ‘Central Dogma’ always apply?
With modern research it is becoming clear that some aspects of the central dogma are not entirely accurate.
Current research is focusing on investigating the function of non-coding RNA?.
Although this does not follow the central dogma it still has a functional role in the cell.
Explanation: