CHEMISTRY HIGH SCHOOL

Positrons are spontaneously emitted from the nuclei of(1) potassium-37 (3) nitrogen-16
(2) radium-226 (4) thorium-232

Answers

Answer 1

Answer:

Answer: Option (1) is the correct answer.

Explanation:

A positron is a small particle which contains a +1 charge and its mass is equal to the mass of an electron, that is, $9.109 * 10^(-31)$ kg.

A positron is represent by the symbol $^(0)_(+1)\beta$ .

For example, $^(37)_(19)K \rightarrow ^(37)_(18)Ar + ^(0)_(+1)\beta$

Whereas nitrogen-16 does not decay to give a positron because nitrogen-16 is the daughter isotope formed due to decay of oxygen-16.

The decay reaction is as follows.

$^(16)_(8)O \rightarrow ^(16)_(7)N + ^(0)_(+1)\beta$

And, on radioactive decay of thorium-232 there will be formation of radium-228 along with emission of an alpha particle.

The reaction will be as follows.

$^(232)_(90)Th \rightarrow ^(228)_(88)Ra + ^(4)_(2)\alpha$

Therefore, we can conclude that out of the given options positrons are spontaneously emitted from the nuclei of potassium-37.

Answer 2

Answer: Positrons are spontaneously emitted from the nuclei of potassium -37.

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I need help with this molecular formula problem really quick!!

The heat of combustion of propane, C3H8, is 2220 kJ/mol. The specific heat of copper is 0.385 J/g°C. How many grams of propane must be burned to raise the temperature of a 10.0 kg block of copper from 25.0°C to 65.0°C, assuming none of the heat is lost to the surroundings?

Answers

The heat of combustion ( $\Delta$ Hc0) is the amount of energy released as heat when a compound completely burns with oxygen under standard conditions.

3.05988g. grams of propane must be burned to raise the temperature of a 10.0 kg block of copper from 25.0°C to 65.0°C.

What is meant by heat of combustion?

The heat of combustion ( $\Delta$ Hc0) is the amount of energy released as heat when a compound completely burns with oxygen under standard conditions. In most cases, a hydrocarbon reacts with oxygen to produce carbon dioxide, water, and heat.
The heat of combustion of a substance is the amount of energy released when a specific amount (e.g., 1 mol, 1g, 1 L) of the substance completely burns in oxygen. The heat of combustion is typically measured at 298K (25 C) and 101.3kPa.
The energy released when a substance X completely burns with an excess of oxygen under standard conditions (25°C and 1 bar). It is the inverse of the enthalpy change for the combustion reaction in thermodynamic terms.

q=m*c*(change of T)

q=10000g(0.385J/g*c)*(65.0C-25.0C)or (338.2 K-298.2K)

q=154000J

154000J*(1 mol/2220 KJ)=69.36936 x $10 ^-3$ mol

here's where I'm stuck

0.069369 mol

and i know that for every 1 mol there is 44.11g of C3H8.

0.069369 mol* (44.11g C3H8)/1mol = 3.05988g.

To learn more about : Heat of combustion

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Answer:

Explanation:

q = (mass) (temp change) (specific heat)

q = (10000 g) (40 °C) (0.385 J/g⋅°C) = 154000 J = 154 kJ

154 kJ / 2220 kJ/mol = 0.069369369 mol

0.069369369 mol times 44.0962 g/mol = 3.06 g (to three sig figs)

answer choice 4

How do you tell if a reaction is endothermic or exothermic using only the written formula

Answers

You know if it's endothermic or exothermic by doing the enthalpy reaction. If the change of temperature is negative then it is exothermic, while positive is endothermic. If you get -22K then its exothermic, but if you get +22 its endothermic.

51 Draw a Lewis electron-dot diagram for a molecule of bromomethane, CH3Br.

Answers

See attachment for the answer

Each line represents a single bond (two electrons), and the lone pairs of electrons are shown as dots. Carbon forms single bonds with three hydrogen atoms and one bromine atom, resulting in a stable Lewis structure that satisfies the octet rule for each element and minimizes formal charges.

To draw the Lewis electron-dot diagram for bromomethane (CH3Br), follow these steps:

Determine the total number of valence electrons for each element in the molecule:

Carbon (C) has 4 valence electrons.

Hydrogen (H) has 1 valence electron.

Bromine (Br) has 7 valence electrons.

Calculate the total number of valence electrons by adding the contributions from each element:

Carbon: 4 electrons x 1 atom = 4 electrons.

Hydrogen: 1 electron x 3 atoms = 3 electrons.

Bromine: 7 electrons x 1 atom = 7 electrons.

Total = 4 + 3 + 7 = 14 electrons.

Determine the central atom. In CH3Br, carbon is the central atom.

Connect the central carbon atom to the surrounding hydrogen and bromine atoms using single bonds (each bond consists of two electrons).

Distribute the remaining valence electrons as lone pairs on the outer atoms to satisfy the octet rule. Hydrogen can only accommodate two electrons (a duet), and bromine can expand its octet.

Calculate the formal charges to ensure that the Lewis structure represents the most stable arrangement of electrons. In CH3Br, the formal charges should ideally be as close to zero as possible.

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What are the intermolecular forces that exist between molecules of NH3, H2O and HF called ?

Answers

I think, is HYDROGEN BOND!
This is some kind of is the electrostatic attraction between polar molecules that occurs when a hydrogen (H) atom bound to a highly electronegative atom such as nitrogen (N), oxygen (O) or fluorine (F)... see image below! ;-)

Final answer:

The intermolecular forces that exist between molecules of NH3, H2O, and HF are hydrogen bonding, dipole-dipole interactions, and London dispersion forces.

Explanation:

The intermolecular forces that exist between molecules of NH3, H2O, and HF are called hydrogen bonding, dipole-dipole interactions, and London dispersion forces. Hydrogen bonding occurs between a hydrogen atom bonded to a highly electronegative atom (such as O, N, or F) and a lone pair of electrons on a nearby molecule. Dipole-dipole interactions occur between molecules with permanent dipole moments, while London dispersion forces occur due to the temporary formation of induced dipoles in adjacent molecules.

Which the following accurately describes a trade-off of using nuclear energy to produce electricity?A. The energy source is renewable, but the power plant disturbs natural ecosystems by stopping the flow of rivers
B. This energy source causes no pollution, but the fuel is a nonrenewable resource
C. Very little fuel is necessary to produce a large amount of energy but the waste materials are harmful to the environment.
D. The fuel is inexpensive , but using the energy produces air pollution.

Answers

Final answer:

Option C accurately depicts a trade-off of nuclear energy. It is highly efficient in generating power from a small quantity of fuel but generates harmful radioactive waste.

Explanation:

The correct statement which accurately describes a trade-off of using nuclear energy to produce electricity is: C. Very little fuel is necessary to produce a large amount of energy but the waste materials are harmful to the environment.

Nuclear power plants generate a significant amount of energy from a small amount of fuel (nuclear fission). This makes them a highly effective source of power. However, one of the key trade-offs is the radioactive waste produced, which needs careful management and disposal to ensure it doesn’t harm the environment or human health.

Learn more about Nuclear Energy Trade-off here:

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Answer:

Your answer is B here is your lucky day

The proper technique used to obtain a liquid sample using a pipette involves: Group of answer choices your mouth on one end of the pipette to suction the sample. a suction bulb or pipette pump to suction the sample. a funnel on one end of the pipette to add the sample. a small glassware to pour the liquid in one end of the pipette. the vacuum hose on one end of the pipette to suction the sample.

Answers

Answer:

A suction bulb or pipette pump to suction the sample.

Explanation:

There are different types of pipettes that can be used in a laboratory:

Volumetric pipette-used to transfer a specific calculated amount of liquid
Graduated pipettes-used to transfer different calculated amounts of liquid from one container to another.
Micropipettes-used to transfer small amounts of liquids
Pasteur pipettes- just like micropipettes, pasteur pipettes are used to transfer small amounts of liquids, but manually. They are also called droppers.

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