What does the law of conservation say about matter?

solid

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Answer:

Figure A depicts dissolution, B and F depict straining. Figure C depicts the use of filter paper. Figure D shows the evaporation process. Figure E shows separation with the help of a magnet.

Explanation:

The techniques mentioned in the images are separation techniques.

Straining is the separation process in which the particles are separated on the basis of size with the help of a filter. The filter will set the cut-off value and the particles are separated.

In Figure B with the help of a strainer, the water from the spaghetti is removed. So figure B possesses straining.

In figure F the tea leaves are separated from the tea with a strainer. Thus Figure F also depicts the straining technique.

The use of filter paper is made to differentiate the particles of very small size. In figure C, filter paper is used to separate the solute in the solution.

The separation of iron is made with the use of a magnet. Magnet has the ability to attract iron towards it.

In figure E, iron nails are being separated with the help of a magnet.

Dissolving is the process of making two solutes miscible in a solution. In figure A, sugar was made to dissolve in water making a miscible solution. Sand is allowed to dissolve in water making an immiscible solution.

Evaporation is the process of converting liquid to vapor form.

Figure D posses the evaporation process in which water is evaporated in the form of vapor, leaving the salt behind.

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Well to solve this problem, we must remember that Oxygen in ionic form is Oxide O2- (an electric charge of negative 2). Hence the correct formulas and names taking into account the charge of Oxygen are:

c) Co2O3, cobalt(III) oxide

f) CoO, cobalt(II) oxide

The correct formulas and names for the oxides of cobalt are CoO, cobalt(II) oxide and Co2O3, cobalt(III) oxide based on the different oxidation states of Cobalt ions.

The correct formulas and names for the oxides formed by cobalt's two different ions, Co2+ and Co3+, are CoO, cobalt(II) oxide and Co2O3, cobalt(III) oxide.

These names are determined by the oxidation state of the cobalt ion in the compound. For cobalt(II), the oxidation state is +2, which when combined with the -2 charge from the single oxygen atom, gives a neutral compound of CoO. For cobalt(III), the oxidation state is +3, which with the -2 charge from each of the three oxygen atoms, again gives a neutral compound - this time of Co2O3.

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Answer is: c. It must lose two electrons and become an ion.

Magnesium (Mg) is metal from 2. group of Periodic table of elements and has low ionisation energy and electronegativity, which means it easily lose valence electons (two valence electrons).

Magnesium has atomic number 12, which means it has 12 protons and 12 electrons. It lost two electrons to form magnesium cation (Mg²⁺) with stable electron configuration like closest noble gas neon (Ne) with 10 electrons.

Electron configuration of magnesium ion: ₁₂Mg²⁺ 1s² 2s² 2p⁶.

4Fe + 3O2 → 2Fe2O3 

observe that you were given the amounts of each substance in moles

Final answer:

To produce 28.7 grams of H₂, 1394.26 grams of H₂SO4 and 255.6 grams of Al are required, based on the stoichiometry of the balanced chemical equation.

Explanation:

To determine the amounts of H₂SO4 and Al needed to produce 28.7 grams of H₂, we start with the balanced chemical equation: 2 Al + 3 H₂SO4 → Al₂(SO4)₃ + 3 H₂.

First, we calculate the moles of H₂ produced using its molar mass (2.02 g/mol). For 28.7 grams of H₂, that's 28.7g / 2.02 g/mol = 14.21 mol of H₂. Based on the reaction stoichiometry, for every 3 moles of H₂ produced, 3 moles of H₂SO4 are needed, and 2 moles of Al are required.

Therefore, we require 14.21 mol of H₂SO4 and 9.47 mol of Al. The molar mass of H₂SO4 is 98.09 g/mol, so we need 14.21 mol × 98.09 g/mol = 1394.26 grams of H₂SO4.

The molar mass of Al is 26.98 g/mol, hence 9.47 mol × 26.98 g/mol = 255.6 grams of Al.

Earth scientists study the physical aspects, processes, and history of the Earth through disciplines like geology, oceanography, meteorology, environmental science, and even astronomy. They address important questions regarding natural resources, geological hazards, and environmental impacts. The study of Earth science is crucial for understanding climate change, managing natural disasters, and guiding the sustainable use of resources.

What Do Earth Scientists Study?

Earth scientists are concerned with understanding the various aspects of the Earth and its processes. They investigate fields such as geology, which is the study of Earth's material and structures, oceanography, focusing on the oceans, and meteorology, which deals with the atmosphere, climate, and weather. Additionally, environmental science looks at the effects of human activities on the environment, and astronomy extends beyond Earth to study the solar system, galaxy, and universe.

Relevant Questions in Earth Science

Earth scientists ask a variety of critical questions, such as how do geological events like earthquakes and volcanoes impact human society? What can the rock cycle tell us about Earth materials? They also explore how climate is changing and the mechanisms of seismic activity. Their work can involve developing models to understand Earth's processes and determining geologic time through the analysis of rock formations.

Importance of Studying Earth Science

Studying Earth Science is vital for several reasons: to satisfy human curiosity, understand the evolution of life, search for resources, assess geological hazard risks, and analyze past environmental and climate changes to understand current human impacts. Furthermore, insights from Earth science are indispensable for addressing some of the biggest problems we face today, such as climate change, natural disasters, and the sustainable management of natural resources.

Interdisciplinary Connections

Earth science is inherently interdisciplinary, connecting with other fields such as biology, physics, chemistry, and various societal domains. Collaboration with these disciplines helps Earth scientists to deepen their understanding and address complex challenges.

It is Shale And Sandstone

The options that give two examples of clastic sedimentary rock are Shale and Sandstone. The correct option is D.

Sedimentary rocks are those rocks that are formed by the accumulation of minerals and organic particles at the surface of the earth. These rocks are made by the heat and pressure of the earth, which convert the organic material and minerals into rocks.

There are different types of sedimentary rocks. These are sandstone, limestone, and shale. They are mainly formed by the accumulation of minerals from rivers.

Clastic sedimentary rock is formed by fragments or pieces of sedimentary rocks. These are formed when the pieces are broken or fragmented by forces and are present in the basin of the earth's surface.

Thus, the correct option is D. Shale and Sandstone.

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Answer;

C. seafloor spreading

Explanation;

The theory of seafloor spreading states that new ocean crust is continually being formed, and that this crust is slowly carried away from its point of origin over a period of time.

Paleomagnetism helped explain an unusual observation from the 1950s. Magnetic studies revealed that the ocean floor was comprised of parallel bands of crust having alternating magnetic polarity.These magnetic bands were symmetric about the mid-oceanic ridge.

Answer: B. temperature, acidity, mineral composition and surface area

Independent variables are those which can be changed and manipulated in the experiment the effect of which can be observed on the changes that occur in the dependent variable. For example the effect of quantity of manure and water on the height of the plant. Here, quantity of manure and water are the independent variables and the height is the dependent variable.

The temperature is the independent variable because the level of temperature can be increased or lowered down manually.

The acidity is the independent variable because the acidity can be manipulated by addition of chemicals that exhibit more hydrogen ions.

Mineral composition can be manipulated and it is an independent variable by treating a mineral with a suitable chemical this will bring a change in the chemical composition of the mineral.

Surface area is the independent variable because  it is the total area required for the conduction of the experiment . The surface area can be increased or decreased.

Answer:

The correct answer is option C.

Explanation:

Atomic symbol of nitrogen = N

Atomic symbol of oxygen = O

In the chemical formula = [tex]NO_2[/tex]

The given molecular formula of compound indicate its one molecule is made up of 1 nitrogen atom and 2 oxygen atoms.

Answer: 1962.513u

Explanation:

Ca3(PO3)4

Ca = 40.078u

P = 30.97u

O = 16u

1 mole of Ca3(PO3)4 =(3*40.078) + 4[(16*3) + 30.97]

1 mole = 120.234 + 315.88 = 436.114g/mol

If 1 mole = 436.114g/mole

4.5 mole = x?

Cross multiply and make x the subject,

x = 4.5*436.114/1

= 1962.513g/mol

Therefore, 4.5 moles of Ca(PO3)4 equals 1962.513g/mole

Metals are supposed to give electron easily  so their ionization energy is low as compared to metals. Third ionization energy of Titanium is 2652.5KJ/mole

Ionization energy is the amount of energy that is required to take out the electron from the outermost shell of an atom. Since energy is given to the element, process is endothermic and the given energy is positive

Ti belongs to D block of periodic table. It is metal so its ionization energy will be not so high as metals release electron very easily.

Electronic configuration of Titanium is [Ar]3d²4s²

The first ionization energy is  [Ar]3d²4s¹

The second ionization energy is  [Ar]3d²

The third ionization energy is  [Ar]3d1

Thus value of third ionization energy comes out to be 2652.5KJ/mole

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The answer is AlF3. Hopes this helps.

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Answer : An atom with 7 protons, 6 neutrons, and 7 electrons has an atomic mass of 13 amu.

Explanation :

As we are give that,

Number of protons = 7

Number of electrons = 7

Number of neutrons = 6

As we know that,

Atomic number =Number of protons = Number of electrons = 7

Atomic mass = Number of neutrons + Atomic number

Atomic mass = 6 + 7 = 13 amu

Therefore, the atomic mass is, 13 amu

Answer:

There are 0.006 moles of Cl- in the solution.

Explanation:

To solve this problem you should think in te concept of molar mass, the molar mass of Cl- is 35.45 grs/mol (it has the same mass as Cl, because electrons doesn´t contribute with significant mass). So,

35.45 grs --------- 1 mol Cl-

0.213 grs  --------- x = 0.006 moles Cl-

There are 0.006 moles of Cl- in the solution.

Final answer:

The Law of Conservation of Energy states that energy cannot be created or destroyed but can only change form. This law is fundamental to understanding the behavior of energy in various systems.

Explanation:

The question pertains to the basic laws that govern energy behavior in physics. The main law that defines what happens to energy is known as the Law of Conservation of Energy. This pivotal law asserts that energy cannot be created or destroyed, but can only change from one form to another.

For instance, electrical energy can be converted into thermal energy, kinetic energy can be transformed into potential energy, and so forth.

In a physical process, energy may seem to 'disappear' as it changes form, such as when friction converts kinetic energy into heat energy that is dispersed into the environment. However, the total energy before and after the process remains the same, affirming that energy is conserved.

Furthermore, looking at the broader perspective, the energy within a closed system remains constant over time. The only changes that occur are the forms of energy; for example, within an ecosystem, the chemical energy in food is converted into kinetic energy by animals, and ultimately into heat energy when it is used by organisms.

Ultimately, energy might leave the planet in the form of heat radiating into space, but overall, it stays within the Earth-sun system, converting and moving from one place to another.