What monomers are found in DNA and RNA?


A-amino acids

B-nucleotides

C-fatty acids

D-saccharides

To find the density of any sample, you need to know the Mass (grams), and its Volume (measured in mL or cm³). Divide the mass by the volume in order to get a sample's Density.

Density (P)= Mass(m)/Volume(V)

P=m/V

P=245.8grams/94ml

P=2.65grams per ml 

In precipitation reactions, components of two compounds exchange to form a new, insoluble solid product, making them double-replacement reactions; however, not all products are liquids, nor does the reaction always involve a redox process. Option A is correct.

When considering which statements are true of precipitation reactions, we can confirm that:

They are also double-replacement reactions. This is true because in precipitation reactions, cations and anions from two different reactants exchange partners to form two new products, and typically one of these products is an insoluble solid that precipitates.

The products are liquids. This is not necessarily true as the defining characteristic of a precipitation reaction is the formation of a solid precipitate.

All of the solids are removed from the solution. While a solid precipitate forms and is often removed from the reaction mixture, this statement doesn't accurately describe the chemical nature of the reaction itself.

They are also redox reactions. Not all precipitation reactions are redox reactions; redox reactions involve the transfer of electrons, whereas precipitation reactions involve the exchange of ions without necessarily involving a change in oxidation state.

Hence, A. is the correct option.

Final answer:

In static friction between solids, friction is proportional to the normal force rather than object size, and dependent on microscopic surface interactions. In fluid friction, the frictional force depends on the object's size, particularly its cross-sectional area, and velocity, affecting aerodynamics and energy efficiency.

Explanation:

The relationship between the size of an object and the amount of friction that is present depends on the type of friction involved. When considering static friction between two solid surfaces, the frictional force is generally proportional to the normal force, and not directly to the size or contact area of the object. Microscopic interactions such as the deformation of surface irregularities play a role in how much of the surface area actually comes into contact and contribute to friction. This means that as the normal force increases, such as with a heavier object, so does the frictional force up to the maximum static friction limit.

On the other hand, when considering fluid friction - such as air resistance or water resistance - the frictional force does indeed depend on the size of the object, particularly its cross-sectional area. Fluid friction increases with velocity and larger objects often experience more drag due to a larger area facing the flow, which is why streamlined designs are often used to minimize this effect. The increase in fluid friction with cross-sectional area can significantly affect the performance and energy efficiency of moving vehicles.

Skeleton equation   [tex]C_6H_12O_6 + O_2[/tex] → [tex]CO_2 + H_2O[/tex]

Balanced equation [tex]C_6H_12O_6 + 6O_2[/tex] →  [tex]6CO_2 + H_2O[/tex]

A balanced equation is an equation for a chemical reaction in which the number of atoms for each element in the reaction and the total charge is the same for both the reactants and the products.

Skeleton equation -A skeletal chemical equation is a representation of a chemical reaction using chemical formulae of reactants and products.  

Skeleton equation   [tex]C_6H_12O_6 + O_2[/tex] → [tex]CO_2 + H_2O[/tex]

Balanced equation-A balanced chemical equation tells you the amounts of reactants and products needed to satisfy the Law of Conservation of Mass.

Balanced equation [tex]C_6H_12O_6 + 6O_2[/tex] →  [tex]6CO_2 + H_2O[/tex]

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Answer: The correct statements are it is primarily composed of hydrogen and helium and its surface gases form into colorful bands.

Explanation:

There re two types of planets in Our solar system:

1. Inner planets: There are 4 inner planets which are Mercury, Venus, Earth and Mars. These planets have a rocky surface. They revolve in less time around the Sun. The number of satellites that these planets have are less (at max two). As, these planets lie close to Sun, thus they are hotter than the outer ones.

2. Outer planets: There are 4 inner planets which are Jupiter, Saturn, Uranus and Neptune. These planets have a gaseous surface. They take more time to revolve around the Sun. These planets have many satellites. As, these planets lie far from the Sun, thus they are colder than the inner ones.

Jupiter is the 5th planet in Our solar system. The atmosphere of Jupiter is the mostly made up of Hydrogen and Helium with trace amounts of ammonia, water, methane and other carbon compounds. The clouds of ammonia present in Jupiter's atmosphere are carried by the jet streams. This results in the formation of Jupiter's colored bands, which are shades of white, red, orange, brown and yellow.

Hence, the correct statements are it is primarily composed of hydrogen and helium and its surface gases form into colorful bands.

The two pieces of data indicate that Jupiter resides in the outer region of the solar system is A. It is primarily composed of hydrogen and helium and D. Its surface gases form into colorful bands.

Jupiter's composition of hydrogen and helium, and its colorful bands indicate that it resides in the outer region of the solar system.

To determine which two pieces of data indicate that Jupiter resides in the outer region of the solar system, the correct options are:

Additionally, Jupiter's colorful bands are a result of its atmospheric conditions, which are different from the rocky surfaces of inner planets.

Correct question is: Which two pieces of data indicate that Jupiter resides in the outer region of the solar system?
A. It is primarily composed of hydrogen and helium.
B. t contains one natural satellite, the Moon.
C. It is the hottest planet in the solar system.
D. Its surface gases form into colorful bands.
E. It has a metal surface upon which one can stand.

Solar energy offers environmental benefits, reduces electricity bills, and creates jobs, but comes with high initial costs and requires sunlight consistency. Technological improvements may decrease costs over time, but solar still requires subsidies to compete with conventional energies. Storage technology is critical for solar's future reliability and cost-effectiveness.

Solar energy is a renewable energy source with numerous benefits, such as the fact that it does not produce pollution and can reduce electricity bills over time. However, the initial cost of solar panels, installation, and maintenance can be quite high, and it requires a consistent supply of sunlight to be effective.

Technological advances are making solar energy more cost-effective, but it is still more expensive compared to fossil fuel-generated power in many regions. Moreover, despite the abundance of solar energy, the technology to store it, such as batteries, requires further development to make solar energy a more reliable source.

The necessity for a consistent supply of sunlight means that solar energy systems may still need conventional backup systems, adding to the overall cost. Nonetheless, solar panels offer the advantage of working during power grid outages, and solar energy can create jobs and positively impact economies. Over time, thanks to technological progress and economies of scale, solar energy is becoming more affordable and competitive with conventional energy sources.

The debate around subsidies stems from the high cost of solar energy, as even with government incentives, solar power is not yet as economical as fossil fuels in certain countries. However, many proponents argue that these subsidies are required to foster the development of renewable energy systems for a sustainable future.

Answer:

The maximum number of electrons in a p sub-level is 6.

Explanation:

The Electronic Configuration of the elements is the arrangement of all electrons of an element in energy levels and sub-levels (orbitals).  

There are 7 energy levels, numbered from 1 to 7, and in which electrons are distributed in order according to their energy level. Electrons with less energy will be spinning at level 1.

Each level is divided into sub-levels. These sub-levels into which each level is divided can be up to 4 and these are called: s, p, d, f. In the sub-level s there can only be a maximum of 2 electrons, in p there can be a maximum of 6 electrons, in the sub-level d 10 electrons and finally in the sub-level f there can be a maximum of 14 electrons.

In level 1 there is only one sub-level, which will be the s. In level 2 there are 2 sub-levels, the s and the p. At level 3 there are 3 sub-levels s, p and d. And at level 4 there are 4 sub-levels, the s, the p, the d and the f.

So, the maximum number of electrons in a p sub-level is 6.

Nitrogen fixation is the conversion of atmospheric nitrogen into biologically useful chemicals by microorganisms. Denitrification is the process by which bacteria convert nitrates into nitrogen gas. These processes have different functions in the nitrogen cycle.

Nitrogen fixation is the process where organisms convert atmospheric nitrogen into biologically useful chemicals. To date, the only known kind of biological organisms capable of nitrogen fixation are microorganisms. These organisms employ enzymes called nitrogenases, which contain iron and molybdenum. Many of these microorganisms live in a symbiotic relationship with plants, with the best-known example being the presence of rhizobia in the root nodules of legumes.

In contrast, denitrification is the process by which denitrifying bacteria convert nitrates (NO3) into nitrogen gas (N₂). Denitrifying bacteria utilize nitrate as an electron acceptor and break it down into nitrogen gas through an anaerobic respiration process. This process happens in anaerobic environments, like waterlogged soils or wetlands.

Explanation:

A saturated hydrocarbon is defined as the hydrocarbon in which there are only single bonds between the combining atoms.

On the other hand, a cyclic hydrocarbon is a ring structure in which hydrogen and carbon atoms are joined together.

Hence, a saturated cyclic hydrocarbon is a ring structure of hydrogen and carbon atoms joined together through single bonds only.

In a saturated cyclic hydrocarbon molecule, each carbon atom is bonded with two hydrogen atoms.

Therefore, we can conclude that the ratio of carbon atoms to hydrogen atoms in a saturated cyclic hydrocarbon is 1:2.

that's wrong. I'm not sure but I think it might be ultraviolet.

Answer:

Ultraviolet

Explanation:

Given the options:  Infrared, Radio waves, Ultraviolet and Visible light, ordering them by frequency (for highest to lowest) we get:

Ultraviolet

Visible light

Infrared

Radio waves

Knowing that high-frequency radiations are likely to cause harm to astronauts landing on Mars, then the detector of Ultraviolet is most suitable

The average atomic mass for lithium, given that Lithium-6 has a mass of 6.0151 amu and lithium-7 has a mass of 7.0160 amu, is 6.9417 amu

From the question given above, the following data were obtained?

Average atomic mass = [(Mass of 1st × 1st%) / 100] + [(Mass of 2nd × 2nd%) / 100]

= [(6.0151 × 7.42) / 100] + [(7.0160 × 92.58) / 100]

= 0.4463 + 6.4954

= 6.9417 amu

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Final answer:

The IUPAC name for the bromine-substituted organic compound depends on its structure; for the compound given, it is 2-bromobutanoic acid. Other examples include 2-bromopentane and 4-bromo-2-methylhexane. Hydroboration and radical addition reactions are key concepts related to the reactivity of compounds with bromine.

Explanation:

The student's question seems to focus on organic chemistry, specifically on the naming and reactivity of organic compounds with bromine ([tex]Br_{2}[/tex]).

The IUPAC name for the compound with a bromine atom at the alpha-carbon ([tex]C_{2}[/tex]) in the IUPAC system is 2-bromobutanoic acid, also known as alpha-bromobutyric acid in the common system. An example of a reaction with diborane and ethene is hydroboration, which leads to the synthesis of organoboron compounds. The organic reaction between ethene and bromine forms 1,2-dibromoethane, whereas ethane does not react with bromine under normal conditions.

In the case of 3-Bromobut-1-ene reacting with hydrogen gas, the product is butane. Radical addition reactions, such as the addition of HBr to 1-butene, can produce different products depending on the presence of peroxides. This phenomenon is an example of conflicting regioselectivity in organic chemistry.

When determining the IUPAC names of compounds, multiple examples are demonstrated ranging from 2-bromopentane to 4-bromo-2-methylhexane, highlighting the importance of the longest carbon chain and correct placement of substituents in naming.

Answer:

True

Explanation:

Polymer is made up of monomers. Monomers are the building block of polymers.  

For example, formation of polyethylene from ethylene  

H₂C=CH₂ + H₂C=CH₂ → - CH₂-CH₂-CH₂-CH₂-

Ethylene molecules add to one another through addition reaction.  

The final pressure inside a scuba tank after cooling from 100 °C to 25.0 °C and an initial pressure of 130.0 atm is 103.82 atm.

Given:
Initial temperature, T1 = 100 °C = 373 K
Final temperature, T2 = 25.0 °C = 298 K
Initial pressure, P1 = 130.0 atm

Using the Combined Gas Law:
P1V1/T1 = P2V2/T2
130.0 atm x V1 / 373 K = P2 x V1 / 298 K

Calculating:
130.0 atm / 373 K = P2 / 298 K
P2 = (130.0 atm x 298 K) / 373 K
P2 = 103.82 atm

Therefore, the final pressure inside the scuba tank after cooling to 25.0 °C is 103.82 atm.