what's going on all of my healthcare brothers and sisters i hope that you are having a wonderful day the atit's science portion of the test is one of the most important portions of the version seven atits because it discusses a lot of different things that were not on version six so this in-depth guy looking specifically at chemistry is going to help you pass your test the first time we'll discuss the type of questions that you're going to see on the test and offer distance strategies on how to pass them let's get started so let's take a closer look at the objectives for chemistry on the test there is going to be a total of eight questions out of the 44 questions for the science portion and what you will need to know is the basic atomic structure physical properties and changes of matter chemical reactions conditions that affect chemical reactions properties of solutions as well as acids and bases so we begin by looking at our first objective and that is recognizing basic atomic structure and what better way to kick it off than looking at the different parts of an atom atoms consist of structures within the nucleus containing protons and neutrons electrons orbit around the nucleus and shells so as we begin a proton is a particle with a single positive charge when you're trying to remember it think proton positive positive charge whereas our neutral our neutron actually has a neutral charge right it has no electrical charge at all so proton positive positive charge neutron neutral no charge those little tiny circles that are orbiting around our nucleus is known as electrons and they have a negative charge and what's interesting about them is they are about 2 000 times smaller than our proton so when we're looking at different types of elements we can determine what kind of element it is based on the number within a protons found within the nucleus so for example carbon has six protons as we move forward isotopes are atoms of the same element that have a different number of neutrons so for example carbon 12 would have six neutrons because we know that there's six protons right in carbon and carbon 14 would have eight neutrons because again that proton number doesn't change so carbon 12 and carbon 14 are considered isotopes of carbon something else that you're going to need to know is atomic mass and the atomic mass of an atom is the total number of protons and neutrons as electrons are so small they really don't make up any determination when it comes to the atomic mass so if we add our protons and our neutrons together we can get the atomic mass so for example carbon 12 is 12 right we have six protons and six neutrons making the atomic mass 12. when you're looking for the atomic number that's the number of protons in an atom so again as we know carbon has six protons making the atomic number six lastly atoms can be positively charged negatively charged or they can be neutral this is determined again by the number of protons that are found within the atom if there are more electrons than protons then the atom is going to be negative right we have more negative charge than we have positive charge whereas if we have more protons than electrons the atom is going to be more positively charged right we have more positive charge than negative charge if the number of protons and electrons are equal then the atom will be neutral so let's talk about some good old-fashioned ions ions are atoms that have gained or lost electrons and as a result have a charge either positive or negative so for example traditionally sodium is made up of 11 protons 12 neutrons and 11 electrons so as we know we have 11 protons 11 electrons this is a neutral atom right they're the same number when sodium loses one of its valence electrons in its outermost shell then it becomes a cation because it has a positive charge remember there's more protons than there are electrons making it more positive cations are atoms that have lost one or more electrons and have a resulting positive charge whereas anions are atoms that have gained one or more electrons and have resulting in a negative charge when an atom gains electrons it usually happens within its most outer shell so for example chlorine has 17 protons 18 neutrons and 17 electrons when chlorine gains an electron it becomes an an ion because now it is more negatively charged now we're going to take a closer look at something that mixes everybody up on the atits and that is the periodic table of elements the periodic table of elements is a chart that shows how elements are related to one another so as we take a look at the chart behind me the elements are organized by increasing atomic number the columns that you're found the up and down are considered groups on the periodic table so each column is considered a group whereas the rows that's your horizontal lines your rows are considered periods there are a few elements that don't fit perfectly into the periodic table and these are called transition elements or melatoids you can actually see them down here at the bottom the first two rows of the periodic table way at the top are the alkali and alkaline earth metals these are considered the active metals the middle of the periodic table are considered the reactive metals okay so first two rows you've got your active metals and then everything in the middle is considered your reactive metals the elements on the far right way up here above my head of the column are the uh noble gases of the periodic table they are considered the inactive gases there are types of elements that are determined by the protons that are found within the nucleus the groups on the periodic table represent how many valence electrons are found within the atom so the columns of the periodic table go from left to right in order of increasing atomic number so the first group way way over there on the left only have one valence electron the second column group two has two valence electrons and so on the rows go from top to bottom in order of increasing atomic number the first row way at the top has two valence electrons and the second row period two has eight valence electrons and so on actually included a little table way over here on the end where it shows you how that's broken down to identify the number of electrons or protons of an element you must look at the integer shown on the periodic table the integer is the element's atomic number which is usually shown as a whole number without a decimal the atomic mass of the periodic table is shown as a decimal to account for the element's various forms of isotopes so let's take a closer look at orbitals orbitals are areas where electrons are likely to be found and are different to accommodate the different electron numbers so we begin by looking at our s orbital that is more of a spherical area that surrounds the nucleus the orbital is allowed to have a maximum of two electrons at a time that's it that's the max that it can have then we have p orbitals and these are more of like a dumbbell shaped type of orbital and with these they can have a max of six electrons at a time next we have d orbitals and that's more of kind of like a flower shape type of orbital that surrounds the nucleus and these orbitals are allowed to have a max of 10 electrons at a time and then we have f orbitals these are really irregularly shaped areas that surround the nucleus and these particular orbitals can have 14 electrons at a time so when you're looking at this just think 2 6 10 14. that's kind of how i remember it when i am trying to remember the types of orbitals and how many electrons that they have the number of orbitals an element has is the same as the period number it has on the periodic table so for the first period remember periods are arose they have one orbital the second period has two orbitals and so on the orbitals are filled in order of increasing energy so the s orbital is always filled first then the p and so on so we've been talking a lot about electrons and we've been using the word valence electrons what the heck does that mean right so valence electrons are located on the outermost shell of an atom readily available to participate in chemical reactions elements are the most stable when they have a full valance shell so again i included that that orbital shell down here in the bottom of your screen to let you know each orbital should have these many things in their shells right these many electrons so elements such as helium have a full valence shell and they are extremely stable other elements such as sodium has only one valence electron in that shell these types of atoms are less stable and they're readily able to give up their electron in order to achieve stability for that particular atom next we're going to talk about ionic and covalent bonds ionic bonds are formed when atoms trade electrons in order to achieve that stability so for example when sodium and chlorine form an ionic bond sodium gives up one valence electron to chlorine and you can see that in my little chart that i have down here see how sodium had this one little valence electron it gave it up so now sodium is more of a positively charged because we gave up our electron we have more protons and electrons and chlorine is now more negatively charged because we gave up our electron from sodium to chlorine so now it has more electrons than protons making it more negatively charged whereas with covalent bonds these are formed when atoms share electrons in order to achieve stability so for example when two hydrogen atoms form a covalent bond they share that one valence electron in order to achieve that stability in order to determine if a bond is ionic covalent or compound you must look at the electronegativity that the atom has and what it's involved in the electronegativity of an atom is measured of how strongly it attracts electrons to its shell the higher the electron negativity the greater the atom's attraction to electrons right so atoms with high electronegativities such as chlorine tend to be more ionic bonds whereas atoms with low electronegativity such as hydrogen tend to form more covalent bonds next we're going to start looking at physical properties of matter and we're going to look at mass volume and density so matter is anything that has mass and occupies space physical properties refers to the different properties of a substance that can change their state without changing the identity of that particular substance so for example water can exist in three different states it can be solid it can be liquid and it can be a gas the states of matter are determined by the physical properties of a substance so for example mass is the amount of matter in an object it is measured by the inertia of an object and is measured in grams so for example a paper clip has a mass of about 0.01 grams volume is the amount of space an object occupies and is usually measured in liters and density is the mass of an object divided by its volume it is measured of how much matter is packed into a given space and is measured by grams per liter see we just kind of combine them there not too that's too hard the density of a substance can be affected by its temperature so for example water has a density of a thousand kilograms per meter at room temperature however when water is heated its density decreases and it expands when a substance matter changes the physical properties also change so states of matter the most common states of matter are solid liquids gas and plasma solids have a definite shape and volume they are the least compressible state of matter as molecules are tightly packed together in that type pattern liquids have a definite volume but they take the shape of whatever container that they're in they are more compressible than solids as molecules are not packed together as tightly gases are neither a definitive shape nor a volume they are the most compressible states of matter as molecules are fall farther apart from each other and plasma is the state of matter that is often found in the stars that is the gas that is ionized meaning that electrons have been stripped from the atom the phase of a substance is dependent on two conditions temperature and pressure temperature is the measure of the average kinetic energy of the molecules in a substance the higher the temperature the more energy the molecules have more particles of matter move apart and the more space that they're going to take up pressure is the measure of force exerted on an object by the surrounding atmosphere the higher the pressure the more the molecules are forced to come together the physical properties of a substance can be affected by the changes of temperature and pressure so for example water can exist in three states we talked about it solid liquid or gas the state of water is determined by the temperature and the pressure if the temperature is increased the molecule of water will move faster and take up more space this will cause the water to change from a solid to a liquid whereas if the temperature is decreased the molecules of water will move slower and take up less space this will cause the water to change from a liquid to a solid if the pressure is increased the molecule water will be forced together this will cause the water to change from a gas to a liquid and then lastly if the pressure is decreased the molecules of water will be forced further apart this will cause the water to change from a liquid to a gas so chemical properties of matter refer to the ability of a substance to change its identity this can happen when the substance undergoes a chemical reaction these changes can include condensation evaporation sublimation deposition melting and freezing so beginning with condensation this is the process of a gas changing to a liquid this happens when the molecules of the gas slow down and move closer together evaporation is the process of a liquid changing to a gas this happens when the molecules of a liquid gain more energy and then they break away from the surface of a liquid with sublimation this is the process of a solid changing to a gas this happens when the molecules of a solid gain enough energy to break away from the surface of that solid with deposition this is the process of gas changing to a solid this happens when the molecules of the gas slow down and then they start to move closer together whereas with melting again this is the process of that solid changing to a liquid that's probably one of the most easiest ones to remember this happens when the molecule of the solid gains enough energy and breaks away from each other and then lastly freezing another good one to remember that you already know in real life situations freezing is the process of a liquid changing to a solid right this happens when the molecules of a liquid lose enough energy and they they tend to stay together these changes between states of matters are reversible this means that the process can be reversed and the substance will change back to the original state so for example water can be evaporated and then condensed back to a liquid or a substance can be melted and then frozen back into a solid now we're going to move on to another objective and that is describing chemical reactions and we're going to kind of go over some things that we had already discussed to help you understand what's happening with chemical reactions so beginning with balanced electrons in order to understand them it's really important to know these things valence electrons are the electrons in the outermost energy level of the atom right they sit on those outermost shells they are the electrons that are involved in chemical reactions the number of valence electrons in an atom determines how it is going to react to other atoms so atoms can gain or lose electrons in order to achieve that full outer energy level and stability right that's what these atoms always want is they want to be stable when this happens the atom will form a chemical bond with another atom so for example when two chlorine atoms form a bond each atom will have gained one valence electron this is because chlorine has only seven valence electrons when they should have eight and just a reminder in regards to ionic and covalent bonds these are the two different types of bonds that you are going to see ionic bonds are formed when atoms gain or lose valence electrons they are either taken or they're given away and covalent bonds are formed when atoms share valence electrons ionic bonds are usually formed between a metal and a non-metal so for example sodium and chlorine form ionic bonds whereas covalent bonds are usually formed between two nonmetals so for example carbon and oxygen form a covalent bond so now we're going to get into the nitty gritty and we're going to start looking at chemical reactions so chemical reactions can be represented by chemical equations chemical equations are written using symbols and formulas and the symbols represent the elements that are going to be found in that reaction so the formulas represented in the compounds of reactions are reactants arrow to the right products so the reactants are the substances that are involved in that reaction and then the products is the new substances that were formed because of that reaction so for example let's take a closer look at a combustion reaction combustion is the type of reaction that happens when a substance reacts to oxygen to form either carbon dioxide or water so the chemical equation that we have here on our slide is c6 h12 o6 that is the substance of sugar plus we have six oxygen 602 you see our little arrow so on the left hand side we have our reactants and on the right hand side we have our product okay so these two reactants when put together are going to create a product of six co2 so we're gonna have six carbon dioxide atoms and we're going to have two h2o two water atoms in this equation like i said c is the element of carbon o is the element of oxygen we talked about the element of sugar and we talked about the element of oxygen that we found on the reactant side we also talked about what it created the arrow in the equation means react to form that is what that arrow means so in this equation the reactants are carbon and oxygen and the products are carbon dioxide and water now we need to understand how we're going to balance chemical reactions a chemical equation has to be balanced on both sides this means that there needs to be the same amount of atoms on the left side as there is on the right side so for example the equation for combustion of methane is ch4 plus co2 and then our product on the other side co2 plus 2 h2o in order to balance this equation we need to add a coefficient in front of each compound a coefficient is the number that is placed in front of a symbol or formula in order to multiply it let's take a closer look at a different chemical balance and break it down on how this is specifically done now let's take a closer look at our own equation and what we have here is we have h2o yields h2 plus o2 now when you're taking a look at this it doesn't make a whole lot of sense and i'm going to show you why when you read it it's going to read as the compound of water is broken down by hydrolysis to yield hydrogen gas and oxygen gas so on our reactant side we have two hydrogen atoms right that's where we get the h2 and we have one oxygen atom right that's that one lonely little o that's right there this is supposedly going to yield that's our yield here two hydrogen atoms right we know that makes sense we have two on the left two on the right but we have two oxygen on our product side right one oxygen and another oxygen so when we're looking at this equation it is not balanced how do we balance it by adding a coefficient so the coefficient is the number that is placed in front of the symbol of a formula in order to multiply it so we need to get two oxygens on our reactant side in order to make our product side make sense so we do this by adding the number two in front of our reactant now this makes a little bit more sense right we're gonna have two oxygens on our reactant side and two oxygens on our product side however by adding that two we have also doubled our hydrogen ions so now we have a total of four h2s right or we have a total of four hydrogens two oxygens on the reactant side but now we only have two hydrogens and two oxygens on our product side so again how do we balance this out by adding our coefficient to make it make sense so our oxygen is good we don't have to do anything else with our oxygen however our hydrogen is not and we are going to add the coefficient 2 in front of our h2 for it to make sense by adding that we have now added two more hydrogen ions and we take a look at this we can see that our left is equal to our right so now we have a balanced equation of 2 h2o yields 2 h2 plus o2 so moles moles are the unit that is used to measure the amount of a substance the mole could be measured by the number of atoms the number of molecules or the mass of a substance the mole is used in a chemical reaction because it allows us to calculate the amount of each substance that is needed in order to complete the reaction so for example let's say we want to know how many moles of oxygen we have in order to react one molecule of methane you can see our equation down here for the combustion of methane see ch4 plus o2 yields co2 plus h2o the equation for the combustion of methane as you can see has one mole of methane ch4 and we need one mole of oxygen o2 this is because there are four atoms of carbon and methane that's at ch4 and for every one atom of carbon we need at least two atoms of oxygen so in order to react one mole of methane we need to have two moles of oxygen so now we're going to move on to conditions that affect chemical reactions and there are many many different factors that influence reaction rates the rate of a chemical reaction is the speed at which the reactant is converted into products so a catalyst will speed up a reaction there are several factors that can influence the rate of chemical reactions including endothermic reactions and exothermic reactions so to begin with our endothermic reactions these are reactions that absorb heat these are the factors that influence the rate of reaction in the temperature so for example higher temperatures will increase the rate of the reaction because it provides the energy that is needed for the reaction to occur so when you're thinking about this think about increasing temperatures when you're cooking an egg the heat is absorbed from the pan to cook the egg whereas with exothermic reactions these are the reactions that release heat the factor that influences the rate of exothermic reactions is the concentration of the reactant so higher concentrations will increase the rate of the reaction because there are there is a greater chance that the molecules are going to collide so for example the concentration of reactants causing combustion or rain condensation of water vapor into rain releases energy in the form of heat so really the best way to think about this is endothermic reactions absorb heat and exothermic reactions release heat chemical equilibria a chemical reaction is said to be at equilibrium when the rate of the forward reaction is equal to the rate of the reverse reaction at equilibrium the concentration of the reactants and products remain constant there are two different types of equilibrium we have dynamic equilibrium and static equilibrium so when it comes to dynamic equilibrium this is the forward and reverse reactions that are occurring at the exact same time so a good example to think about this is soda when it's inside a sealed bottle carbon dioxide is present in both liquid and gaso gaseous phases they're like those are the bubbles that are happening within the soda these two types are considered dynamic equilibrium because the carbon dioxide is dissolved into the liquid form at the same rate as the liquid form is being converted into gas static equilibrium is when the concentration of the reactants and products are not changing right they're static an example of this is the weight of the body the weight of the body is nothing but the amount of gravitational force that is being acted upon it the gravitational constant is the same as all objects therefore this the body doesn't change when it becomes repositioned right we still are within that static equilibrium the position of equilibrium can be shifted by adding and removing reactants and products if you add a reactant the position of the equilibrium will shift to the right whereas if you remove the reactant the position of the equilibrium will remove to the left so we talked a little bit before about catalysts but now we're going to take a little bit closer look at them now the catalyst is a substance that increases the rate of reaction without being used up in that particular reaction they do this with activation energy that is the minimum amount of energy that is used for a chemical reaction to occur in the first place catalysts lower the activation energy by providing an alternative pathway for the reaction to occur so for example enzymes are proteins that act as catalysts in biochemical reactions enzymes are specific to the reaction that they catalyze and are usually named after the substrate that they act upon amylase is an enzyme that catalyzes the breakdown of starch polymers and glucose monomers now we're going to start taking a closer look at properties of solutions beginning with polarity of water water is really truly incredible water is a polar molecule that means that water molecules have a slight negative charge at the atom of oxygen level and a slight positive charge at the atom of hydrogen level the polarity of water allows it to form hydrogen bonds with other molecules hydrogen bonds are really weak attractions between molecules this can either be through cohesion or adhesion when it comes to cohesion this is the process of similar molecules surrounding and binding to another molecule so water molecules can surround and bind with other molecules because of that polarity of water water is going to attract water whereas with adhesions this is the process of dissimilar molecules binding with another molecule so water molecules combine with other molecules because of that polarity and water is considered really the universal solvent when it comes to a lot of different kinds of reactants and products meaning that many substances are going to be able to dissolve in water so solvents and solutes a solvent is a substance that dissolves in another substance water is the most universal solvent right we talked about that before whereas a solute is a substance that dissolves in a solvent so sugar is the most common solute that can dissolve in water so for example a solution is formed when liquid mixes contains one or more solutes that dissolve in a solvent solutes can either be classified as one of two things they're either hydrophilic meaning that they are water loving or hydrophobic meaning that they are water fearing so for example a hydrophilic salt is an example of hydrophilic whereas hydrophobic when it comes to water is oil salt will dissolve it's hydrophilic oil will not it's hydrophobic solubility is the ability of a solute to dissolve in a solvent the amount of the solute that can dissolve in the given amount of solvent is called the solubility limit the solubility limit is also dependent on temperature so for example hot water can dissolve more sugar than cold water so what is the concentration and dilution of solutions the concentration of a solution is the amount of solute that is dissolved in a given amount of solvent dilution is that process of adding solvent to a solution to decrease the concentration of that particular solution so different units of measures that can be used to express concentration of solution is depending on that particular application the most common that they use though is called molarity molarity is the unit of measure that describes the concentration of a solute in a solvent molarity is expressed as moles of a solute per liter of solution so that is mol dash or slash capital l moles of solute slash liters of solution let's talk about a topic you're going to hear in nursing school all the time and that is osmosis and diffusion osmosis is the process of water molecules moving from a higher area of water concentration to a lower area of water concentration through a semi-permeable membrane a semipermeable membrane is a barrier that allows some molecules to pass through but not others diffusion is the process of molecules moving from a higher area of concentration to a lower area of concentration osmosis and diffusion are both considered passive transport processes so when you're trying to remember this remember osmosis specifically refers to the water aspect whereas diffusion specifically refers to molecule aspects so we talked about before osmosis and diffusion are both passive transport processes however there are also active transport processes so we're going to take a closer look at both passive transport processes do not require energy they only require that the molecule is within motion right it's moving so for example osmosis is when a plant takes up water from the soil through its roots whereas with diffusion is when perfume molecules spread throughout a room these are both passive transport processes however some things need a little bit more energy they need to be more actively moved active transport is a process of molecules moving from a area of low concentration to a high concentration but they are going to require energy because molecules are moving against a concentration gradient so an example of active transport is when a cell takes in glucose from the blood that's going to require energy to make that particular molecule move so now we're going to talk about one of my favorite subjects and that is acids and bases and how those two work together an acid is a molecule that increases the concentration of hydrogen ions in a solution whereas a base is a molecule that decreases the concentration of hydrogen ions in a solution so those hydrogen ions are extremely acidic and if you have too many of them or not enough of them that can cause a lot of problems so ph that is the strength of an acid or base is going to be measured on a ph scale as you can see here in the slide the ph scale ranges between 0 to 14. the ph of 0 is going to be the most acidic whereas the ph of 14 is going to be the most basic and the ph of 7 is really the most neutral ph is a unit of measurement that describes the concentration of those hydrogen ions that are going to be found in a solution the higher the concentration of hydrogen ions the more acidic the solution whereas if you don't have a whole lot the lower that concentration is the more basic the solution is going to be now in order to balance out solutions right to make them more neutral as more or acidic or more basic we're going to need to have buffers and a buffer is a solution that can resist changes in ph buffers are important because they help maintain the ph of a solution within a certain range an example of a buffer is blood blood has a ph between 7.35 and 7.45 which is maintained by that buffer system the buffer system is made up of carbonic acid and bicarbonate carbonic acid is really a weak acid and bicarbonate is really a weak base so by working together they help maintain the ph of blood within that certain range and lastly we're going to take a look at neutralization of reactions a neutralization reaction is a chemical reaction between a acid and a base the products of a neutralization reaction is usually water and salt neutralization reactions are important because they help maintain the ph of a solution within a certain range so for example a neutralization reaction is the reaction between stomach acid and an antacid stomach acids ph is around 0.75 which is really really low right that's very very acidic whereas the antacid has a ph of around 11. that's extremely high it's extremely basic when the stomach acid and antacid react they neutralize one another and the ph of the solution is brought back more to a more neutral value as opposed to more acidic value i hope that this information was helpful in understanding chemistry that is going to be on atit's version 7. if you have any additional questions make sure you leave them down below i love answering your questions head over to www.nurstrong.com where there are a ton of additional resources available for you when it comes to your atits and as always i will see you in the next video bye