Which of the following animals would be found in the tropical rainforest? snake jaguar frog monkey bison

Answer:

The molar heat capacity of water 75.24 J/mol °C.

Explanation:

Specific heat is defined as amount of energy required to raise by the temperature of 1 g of substance by 1 degree Celsius.

Molar eat capacity as amount of energy required to raise by the temperature of 1 mole of substance by 1 degree Celsius.

Specific heat and molar heat capacities can be written:

Molar heat capacity = Specific heat × Molar mass of the substance

Specific heat of water = 4.18 J/g °C

Molar mass of water = 18 g/mol

Molar heat capacity of the water :

[tex] 4.18 J/g ^oC\times 18 g/mol= 75.24 J /mol^oC[/tex]

The molar heat capacity of water 75.24 J/mol °C.

The molar heat capacity of water that has a specific heat of 4.18 J/g°c is 75.24J/mol°C.

MOLAR HEAT CAPACITY:

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Answer:

The correct answer is the disposal procedure.

Explanation:

As we are considering the termination of an experiment, thus, the most essential information will be the disposal procedure. Not all the substances can be disposed of as the usual materials, many chemical components need to get properly disposed of as it can influence the animals, ambiance, and even human beings.  

MSDS or the Material Safety Data Sheet refers to a document, which comprises data on the potential hazards and how to handle them with caution, especially with the chemical product.  

Final answer:

To calculate the grams of iron oxide formed, you need to calculate the moles of iron and moles of oxygen in the reaction and use the mole ratio from the balanced chemical equation. From the given information, the moles of iron and oxygen are 0.894 mol and 1.3125 mol, respectively. Using the mole ratio of 4 moles of iron to 2 moles of iron oxide, we can calculate that 0.447 mol of iron oxide is formed. Finally, converting moles to grams, we find that 71.26 g of iron oxide is produced.

Explanation:

To determine the grams of iron oxide formed, you need to calculate the moles of iron and moles of oxygen in the reaction and use the balanced chemical equation to determine the mole ratio. From the given information, the molar mass of iron is 55.845 g/mol and the molar mass of oxygen is 16.00 g/mol. The balanced chemical equation for the reaction is:

4Fe + 3O₂ → 2Fe₂O₃

Using stoichiometry, we can calculate the moles of iron and oxygen:

Moles of iron = (50 g iron) / (55.845 g/mol) = 0.894 mol

Moles of oxygen = (21 g oxygen) / (16.00 g/mol) = 1.3125 mol

From the balanced chemical equation, we can see that the mole ratio of iron to iron oxide is 4:2. Therefore, for every 4 moles of iron, we get 2 moles of iron oxide. So, the moles of iron oxide formed in the reaction is:

Moles of iron oxide = (0.894 mol iron) / (4 mol iron) * (2 mol iron oxide) = 0.447 mol iron oxide

Finally, we can calculate the grams of iron oxide:

Grams of iron oxide = (0.447 mol iron oxide) * (159.69 g/mol) = 71.26 g iron oxide

Limestone is the most prevalent type of chemical sedimentary rock. Calcite, also known as calcium carbonate, is the main component of limestone and has the chemical formula CaCO3.

The formation of sedimentary rocks involves the accumulation or deposition of mineral or organic particles at the Earth's surface, followed by cementation. The processes that lead to the accumulation of these particles are collectively referred to as sedimentation.

Clastic, organic (biological), and chemical sedimentary rocks are the three different types of sedimentary rocks. Sandstone is a type of clast sedimentary rock, which is formed from fragments of other rocks.

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Final answer:

Atoms of the same element always have the same number of protons but can have different numbers of neutrons, which leads to the formation of isotopes. Lighter elements often have a neutron-to-proton ratio close to 1:1, while heavier elements tend to have higher ratios. The chemical properties are dictated by the number of protons and electrons, not by the number of neutrons.

Explanation:

In chemistry, the relationship between the number of protons, neutrons, and electrons defines the structure of an atom's nucleus and its place in the periodic table. All atoms of the same element have the same number of protons and electrons, which accounts for the element's chemical properties. However, the number of neutrons can vary even within atoms of the same element, leading to different isotopes. Isotopes have the same number of protons but differ in their number of neutrons, affecting their atomic mass but not their chemical properties.

The neutron-to-proton ratio increases as we look at heavier elements. The lightest element, hydrogen, can have zero, one, or two neutrons while maintaining its identity as hydrogen. For heavier elements, this ratio tends to increase, and it varies from one isotope to another. For instance, isotopes of carbon can have six, seven, or eight neutrons but always have six protons.

Stable isotopes tend to have a neutron-to-proton ratio close to 1:1 for lighter elements, increasing to 1.5:1 for heavier elements. Notably, all elements with atomic numbers greater than 83 are unstable and radioactive regardless of their number of neutrons. This peninsula of stability helps define the limits of stable existence for atomic nuclei in the sea of instability where radioactive decay occurs.

To calculate the mass of precipitate formed when highly concentrated Pb(ClO3)2 is mixed with 0.350 L of 0.170 M NaI, first determine the limiting reactant and use stoichiometry. Calculate the moles of Pb(ClO3)2 using its concentration and volume, then use the balanced equation to find the moles of PbI2 formed and finally calculate the mass of PbI2 using its molar mass.

To calculate the mass of precipitate formed when highly concentrated Pb(ClO3)2 is mixed with 0.350 L of 0.170 M NaI, we need to determine the limiting reactant and use stoichiometry.

First, calculate the moles of Pb(ClO3)2 using its concentration and volume.

Moles = concentration x volume = 0.170 M x 0.350 L = 0.0595 moles

The balanced equation for the reaction is:

Pb(ClO3)2 + 2NaI -> PbI2 + 2NaClO3

From the equation, we can see that 1 mole of Pb(ClO3)2 reacts with 1 mole of PbI2.

Therefore, the mass of PbI2 formed can be calculated using its molar mass and the moles of Pb(ClO3)2.

Mass of PbI2 = moles of Pb(ClO3)2 x molar mass of PbI2 = 0.0595 moles x 461.0 g/mol = 27.44 g

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To find the mass of MgI2 produced in the reaction between Mg and I2, you need to calculate the moles of Mg and I2 and use the mole ratio from the balanced equation. Finally, convert the moles of MgI2 to grams using the molar mass of MgI2.

In this reaction, the balanced equation is 2Mg + I2 → 2MgI2. From the balanced equation, we can see that 2 moles of Mg react with 1 mole of I2 to produce 2 moles of MgI2. To find the mass of MgI2 produced, we need to calculate the moles of Mg and I2 and then use the mole ratio to determine the moles of MgI2. Finally, we can convert the moles of MgI2 to grams using the molar mass of MgI2.

Given: m(Mg) = 5.15 g, m(I2) = 50.0 g

Molar mass of MgI2 = 278.113 g/mol

Using these steps, you can determine the mass of MgI2 that can be produced from the given masses of Mg and I2.

Answer:

Option (D)

Explanation:

The relative scale is used to compare two objects or models, in terms of its scale. This enables to understand the relation between the scale of one model that is directly measurable and the other that is too large to measure. Here the direct measurable model is the globe-balloon system and the non-measurable large model is the earth-moon system.

According to the provided condition, Lewis knew that the earth's diameter is four times bigger than that of the moon. He constructed a model of its own by taking a globe of diameter 16 inches and a balloon of diameter 4 inches. He compares this globe to the earth and the balloon to the moon. His model completely satisfies the condition maintaining their relative sizes.  

So the property of relative scale of earth and the moon system is appropriately shown in this model.

Thus, the correct answer is option (D).

Answer:

C

Explanation:

All elements in Group 2 of the periodic table are characterized as alkaline earth metals. They share the common characteristic of having two valence electrons in their outermost energy level. These elements tend to lose these electrons to reach stability, making them typically reactive.

In the periodic table, all elements in Group 2 have some key similarities. The most significant common characteristic is that each element in this group is an alkaline earth metal. This means that they have two valence electrons in their outermost energy level. They tend to lose these two electrons to reach a stable state, so they are typically reactive.

It is incorrect to say that an atom of each element can hold up to eight or six electrons in its outer energy level. This description fits more with Group 16 and Group 18 elements, respectively. Also, these elements are not halogens (Group 17 elements), which have seven valence electrons, nor are they necessarily dull, brittle, or break easily, as these are generally more descriptive of non-metals than metals.

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The correct statement about the law of gravity is that it can be contradicted by valid data. Newton's law of gravitation, which has been expanded upon by Einstein's Theory of General Relativity, remains a well-tested hypothesis, and scientific laws are subject to ongoing testing and revision.

The force of gravity is a fundamental principle in physics, described by Newton's law of gravitation, which states there is a force of attraction between masses. This law is supported by copious observations and is considered a scientific law because it consistently describes what happens under certain conditions in nature.

When evaluating the statement, "The force of gravity pulls all objects downwards," the correct choice would be option b, as scientific laws can be contradicted by new, valid data, which may lead to their modification or replacement.

For instance, Albert Einstein's Theory of General Relativity provided new insights into gravity that go beyond Newton's law, particularly in extreme conditions involving massive objects like the sun. Additionally, all scientific laws, including the law of gravity, are subject to continued examination and testing; they are well-tested hypotheses rather than absolute truths. To help understand this concept, one can perform a take-home experiment by dropping objects of different masses from the same height to observe that they hit the ground simultaneously, which is a demonstration of Galileo's observation that all masses fall with the same acceleration, explained by the law of gravitation.

From left to right in periodic table the atomic or ionic radius decreases. Thus, Mg is right to sodium and it is smaller than sodium.

Atomic radius is the distance from the nucleus to the valence shell containing electrons. The same can be defined for ionic radius. The elements in the periodic table are classified into different groups and periods.

Along a period the atomic radius increases and down a group the atomic or ionic radius increases. The atomic radius decreases because of the nuclear pulling to the electrons.

As the charge increases for a cation the smaller it will be. Mg2+ ions are formed by donation of two electrons from Mg and Na+ is formed by donation of one electron from it. Both are having 10 electrons.

However, the charge is higher for magnesium and it is smaller than sodium ion. Hence, ionic radius is smaller for magnesium ion.

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Final answer:

The Mg²⁺ ion is expected to be smaller than the Na⁺ ion because it has a higher effective nuclear charge and a lower principal quantum number, which results in a tighter electron shell arrangement.

Explanation:

The Mg²⁺ and Na⁺ ions each have ten electrons. The size of an ion depends on both its nuclear charge and the electron shell arrangement. In this case, the Mg²⁺ ion is expected to be smaller than the Na⁺ ion. This is because the Mg²⁺ ion has a higher effective nuclear charge than the Na⁺ ion, which causes a greater electrostatic attraction between the electrons and the nucleus, thereby pulling the electron cloud closer and resulting in a smaller ionic radius. Furthermore, the principal quantum number for Mg²⁺ is n=2, while for Na⁺ it is n=3, indicating closer and more tightly held electron shells in Mg²⁺.

The element with electron configuration 2-8-18-1 is potassium (K), which is in the first column of the s-block of the periodic table and has an atomic number of 19.

An element whose atoms have the electron configuration 2-8-18-1 is likely a member of the alkali metals which reside in the first column of the s-block. The mentioned configuration suggests that this element has 29 electrons. Referring to the periodic table and electron configurations chart, we can determine that the element with this configuration is potassium (K), which has an atomic number of 19. Potassium typically has the electron configuration of 1s² 2s² 2p¶ 3s² 3p¶ 4s¹, which is the same as having the configuration 2-8-8-1 when considering each shell's capacity without specifying subshell orbitals.

Explanation:

It is known that an atom consists of protons, neutrons and electrons. Both protons and neutrons are located inside the nucleus of an atom whereas electrons revolve around the nucleus.

Atomic number is the total number of protons present in an atom. On the other hand, atomic mass is the sum of total number of protons and neutrons present in an atom.

That is,     Atomic mass = no. of protons + no. of neutrons

                 no. of neutrons = atomic mass - no. of protons

Therefore, we can conclude that to find the number of neutrons in an atom, subtract its number of protons from atomic mass.

Final answer:

Mars is approximately 227.5 million kilometers from the Sun.

Explanation:

Mars is approximately 1.52 astronomical units (AU) from the Sun. Given that the average distance between the Earth and the Sun is about 149.6 million kilometers, we can calculate the distance from Mars to the Sun. Since 1 AU is equivalent to about 149.6 million kilometers, we can multiply 1.52 AU by 149.6 million kilometers to find that Mars is approximately 227.5 million kilometers from the Sun.

Final answer:

The combination of Fe(NO3)2 (aq) and KOH (aq) is the one that will produce a precipitate, as Fe(OH)2 is generally insoluble in water.

Explanation:

To determine which combination will produce a precipitate, we need to consider the solubility rules and look for a product in each reaction that forms an insoluble solid, known as a precipitate. We can predict precipitate formation by looking at possible products of a double displacement reaction and referencing a solubility chart.

Analysis of Combinations

AgNO3 (aq) and Ca(C2H3O2)2 (aq): No precipitate is expected because all nitrates (NO3-) and acetates (C2H3O2-) are soluble.

NaOH (aq) and HCl (aq): No precipitate forms, instead, you get NaCl (aqueous) and water (H2O).

NaCl (aq) and HC2H3O2 (aq): Again, no precipitate is expected because all chlorides (except those with Ag+, Pb2+, Hg2 2+) are soluble, as are all acetates.

NH4OH (aq) and HCl (aq): This combination results in the formation of NH4Cl (aqueous) and water, so no precipitate forms here either.

Fe(NO3)2 (aq) and KOH (aq): This combination will likely result in an insoluble hydroxide precipitate, specifically Fe(OH)2.

Based on this analysis, the combination that will produce a precipitate is Fe(NO3)2 (aq) and KOH (aq), as iron(II) hydroxide is generally insoluble in water.

The combination of B. NaOH and Fe(NO₃)₃ will produce a precipitate of Fe(OH)₃.

Other combinations either do not react or form soluble products.

To determine which combination of solutions will produce a precipitate, we can use solubility rules. Let's analyze each option:

Therefore, the correct answer is option B, where the reaction produces the precipitate Fe(OH)₃.

Correct question is: Which combination will produce a precipitate?
A. AgNO₃ (aq) and Ca(C₂H₃O₂) (aq)

B. NaOH (aq) and Fe(NO₃)₃ (aq)

C. NaCl (aq) and HC₂H₃O₂ (aq)

D. NH₄OH (aq) and HCl (aq)

E. NaOH (aq) and HCl (aq)

The element with a valence electron configuration of 4s2 4p3 is Phosphorus.

The element with a valence electron configuration of 4s24p3 is Phosphorus, with the atomic number 15. Its electron configuration is 1s22s22p63s23p3. In the last column of the p block, the valence shell electron configurations are 3p6 for silicon, 3p5 for phosphorus, 3p4 for sulfur, 3p3 for chlorine, and 3p2 for argon.

Specific heat equation is given as

[tex]Q =m\times c\times \Delta T[/tex]

where, Q = energy required

m = mass

c = specific heat

[tex]\Delta T[/tex] = change in temperature

Specific heat of silver ([tex]Ag[/tex]) is [tex]0.245 J/^{o}C g[/tex]

Mass of silver  = 350 g

[tex]\Delta T =T_{final}-T_{intital}[/tex]

Convert 400 K to degree Celsius = 400-273 = 127 K

Convert 293 K to degree Celsius = 293-273 = 20 K

Thus, [tex]\Delta T =127 K-20 K[/tex]

=   [tex]107^{o}C[/tex]

Put the values,

[tex]Q =m\times c\times \Delta T[/tex]

[tex]Q = 350 g\times 0.245 J/^{o}C g\times(107^{o}C)[/tex]

= 9175.25 J

Hence, energy required to raise the temperature is 9175.25 J

Final answer:

Evaporation as a physical property and chemical properties explained with examples and distinctions.

Explanation:

Evaporation is a physical property as it is a characteristic of a substance that can be observed or measured without changing the substance's identity. For molecules to evaporate, they must be located near the surface, moving in the right direction, and have sufficient kinetic energy to overcome intermolecular forces, which relates to physical properties.

Chemical properties, on the other hand, describe how matter changes its chemical structure or composition. An example is flammability - a material's ability to burn, which results in a chemical change, highlighting the distinction between physical and chemical properties.

In summary, physical properties are observable characteristics like color and boiling points, while chemical properties relate to changes in chemical structure and composition, such as the ability to undergo a chemical reaction or change.

Accurate data refers to measurements close to the true value, while precise data refers to measurements that yield similar results when repeated.

Accuracy and precision are both important concepts in scientific measurements. Accurate data refers to measurements that are close to the true or accepted value, while precise data refers to measurements that yield similar results when repeated. For example, if you weigh an object on a scale multiple times and get the same or very similar results, your measurements are precise. If your measurements are also close to the actual weight of the object, they are accurate.

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