Hessa/tqa-multimodalContext-all2 · Datasets at Hugging Face

lessonID stringlengths 6 6	lessonName stringlengths 3 52	ID stringlengths 6 21	content stringlengths 10 6.57k	media_type stringclasses 2 values	path stringlengths 28 76 ⌀
L_0811	bohrs atomic model	T_4170	FIGURE 1.1	image	textbook_images/bohrs_atomic_model_22681.png
L_0811	bohrs atomic model	T_4172	FIGURE 1.2	image	textbook_images/bohrs_atomic_model_22682.png
L_0813	bond polarity	T_4176	FIGURE 1.1	image	textbook_images/bond_polarity_22683.png
L_0813	bond polarity	T_4176	FIGURE 1.2	image	textbook_images/bond_polarity_22684.png
L_0813	bond polarity	T_4177	FIGURE 1.3	image	textbook_images/bond_polarity_22685.png
L_0815	buoyancy	T_4183	FIGURE 1.1	image	textbook_images/buoyancy_22689.png
L_0815	buoyancy	T_4183	FIGURE 1.2 Because of buoyant force, objects seem lighter in water. You may have noticed this when you went swimming and could easily pick up a friend or sibling under the water. Some of the persons weight was countered by the buoyant force of the water.	image	textbook_images/buoyancy_22690.png
L_0815	buoyancy	T_4184	FIGURE 1.3	image	textbook_images/buoyancy_22691.png
L_0816	calculating acceleration from force and mass	T_4187	FIGURE 1.1 A: It would take only 32 N of force (40 kg 0.8 m/s2 ).	image	textbook_images/calculating_acceleration_from_force_and_mass_22692.png
L_0817	calculating acceleration from velocity and time	T_4189	FIGURE 1.1	image	textbook_images/calculating_acceleration_from_velocity_and_time_22694.png
L_0819	calculating work	T_4197	FIGURE 1.1	image	textbook_images/calculating_work_22695.png
L_0820	carbohydrate classification	T_4199	FIGURE 1.1 Note: Each unlettered point where lines intersect represents a carbon atom.	image	textbook_images/carbohydrate_classification_22696.png
L_0820	carbohydrate classification	T_4201	FIGURE 1.2	image	textbook_images/carbohydrate_classification_22697.png
L_0820	carbohydrate classification	T_4201	FIGURE 1.3	image	textbook_images/carbohydrate_classification_22698.png
L_0821	carbon bonding	T_4203	FIGURE 1.1	image	textbook_images/carbon_bonding_22699.png
L_0821	carbon bonding	T_4204	FIGURE 1.2	image	textbook_images/carbon_bonding_22700.png
L_0821	carbon bonding	T_4205	FIGURE 1.3	image	textbook_images/carbon_bonding_22701.png
L_0822	carbon monomers and polymers	T_4207	FIGURE 1.1	image	textbook_images/carbon_monomers_and_polymers_22702.png
L_0822	carbon monomers and polymers	T_4207	FIGURE 1.2	image	textbook_images/carbon_monomers_and_polymers_22703.png
L_0822	carbon monomers and polymers	T_4208	FIGURE 1.3	image	textbook_images/carbon_monomers_and_polymers_22704.png
L_0822	carbon monomers and polymers	T_4208	FIGURE 1.4	image	textbook_images/carbon_monomers_and_polymers_22705.png
L_0823	catalysts	T_4210	FIGURE 1.1	image	textbook_images/catalysts_22706.png
L_0823	catalysts	T_4211	FIGURE 1.2 Q: If you chew a starchy food such as a soda cracker for a couple of minutes, you may notice that it starts to taste slightly sweet. Why does this happen?	image	textbook_images/catalysts_22707.png
L_0824	cellular respiration reactions	T_4212	FIGURE 1.1	image	textbook_images/cellular_respiration_reactions_22708.png
L_0828	chemical bond	T_4221	FIGURE 1.1	image	textbook_images/chemical_bond_22714.png
L_0830	chemical equations	T_4227	FIGURE 1.1	image	textbook_images/chemical_equations_22717.png
L_0833	chemical reaction overview	T_4235	FIGURE 1.1	image	textbook_images/chemical_reaction_overview_22719.png
L_0833	chemical reaction overview	T_4236	FIGURE 1.2	image	textbook_images/chemical_reaction_overview_22720.png
L_0834	chemical reaction rate	T_4240	FIGURE 1.1	image	textbook_images/chemical_reaction_rate_22721.png
L_0834	chemical reaction rate	T_4241	FIGURE 1.2	image	textbook_images/chemical_reaction_rate_22722.png
L_0834	chemical reaction rate	T_4242	FIGURE 1.3	image	textbook_images/chemical_reaction_rate_22723.png
L_0835	chemistry of compounds	T_4244	FIGURE 1.1 All water molecules have two hydrogen atoms (gray) and one oxygen atom (blue).	image	textbook_images/chemistry_of_compounds_22724.png
L_0835	chemistry of compounds	T_4245	FIGURE 1.2 Water: Water is odorless and colorless. We drink it, bathe in it, and use it to wash our clothes. In fact, we cant live without it. Hydrogen Peroxide: Hydrogen peroxide is also odorless and colorless. Its used as an antiseptic to kill germs on cuts. Its also used as bleach to remove color form hair. A: You can tell that they are different compounds from their very different properties. Carbon dioxide is a harmless gas that living things add to the atmosphere during respiration. Carbon monoxide is a deadly gas that can quickly kill people if it becomes too concentrated in the air.	image	textbook_images/chemistry_of_compounds_22725.png
L_0835	chemistry of compounds	T_4245	FIGURE 1.3	image	textbook_images/chemistry_of_compounds_22726.png
L_0836	color	T_4248	FIGURE 1.1	image	textbook_images/color_22727.png
L_0836	color	T_4248	FIGURE 1.2	image	textbook_images/color_22728.png
L_0836	color	T_4249	FIGURE 1.3 light of different colors.	image	textbook_images/color_22729.png
L_0836	color	T_4249	FIGURE 1.4	image	textbook_images/color_22730.png
L_0836	color	T_4250	FIGURE 1.5	image	textbook_images/color_22731.png
L_0837	combining forces	T_4253	FIGURE 1.1	image	textbook_images/combining_forces_22733.png
L_0838	combustion reactions	T_4254	FIGURE 1.1	image	textbook_images/combustion_reactions_22734.png
L_0838	combustion reactions	T_4255	FIGURE 1.2	image	textbook_images/combustion_reactions_22735.png
L_0840	compound machine	T_4260	FIGURE 1.1	image	textbook_images/compound_machine_22737.png
L_0840	compound machine	T_4260	FIGURE 1.2	image	textbook_images/compound_machine_22738.png
L_0841	compounds	T_4263	FIGURE 1.1	image	textbook_images/compounds_22740.png
L_0841	compounds	T_4265	FIGURE 1.2	image	textbook_images/compounds_22741.png
L_0841	compounds	T_4265	FIGURE 1.3	image	textbook_images/compounds_22742.png
L_0843	conservation of energy in chemical reactions	T_4270	FIGURE 1.1	image	textbook_images/conservation_of_energy_in_chemical_reactions_22746.png
L_0846	conservation of mass in chemical reactions	T_4277	FIGURE 1.1 Antoine Lavoisier.	image	textbook_images/conservation_of_mass_in_chemical_reactions_22748.png
L_0847	convection	T_4279	FIGURE 1.1	image	textbook_images/convection_22749.png
L_0847	convection	T_4280	FIGURE 1.2	image	textbook_images/convection_22750.png
L_0848	cooling systems	T_4283	FIGURE 1.1	image	textbook_images/cooling_systems_22751.png
L_0849	covalent bonding	T_4285	FIGURE 1.1	image	textbook_images/covalent_bonding_22752.png
L_0849	covalent bonding	T_4285	FIGURE 1.2	image	textbook_images/covalent_bonding_22753.png
L_0850	crystalline carbon	T_4288	FIGURE 1.1	image	textbook_images/crystalline_carbon_22754.png
L_0850	crystalline carbon	T_4288	FIGURE 1.2	image	textbook_images/crystalline_carbon_22755.png
L_0850	crystalline carbon	T_4289	FIGURE 1.3	image	textbook_images/crystalline_carbon_22756.png
L_0850	crystalline carbon	T_4290	FIGURE 1.4	image	textbook_images/crystalline_carbon_22757.png
L_0851	daltons atomic theory	T_4292	FIGURE 1.1	image	textbook_images/daltons_atomic_theory_22758.png
L_0851	daltons atomic theory	T_4294	FIGURE 1.2	image	textbook_images/daltons_atomic_theory_22759.png
L_0852	dangers and uses of radiation	T_4297	FIGURE 1.1	image	textbook_images/dangers_and_uses_of_radiation_22760.png
L_0853	decomposition reactions	T_4300	FIGURE 1.1	image	textbook_images/decomposition_reactions_22762.png
L_0854	democrituss idea of the atom	T_4302	FIGURE 1.1	image	textbook_images/democrituss_idea_of_the_atom_22763.png
L_0854	democrituss idea of the atom	T_4304	FIGURE 1.2	image	textbook_images/democrituss_idea_of_the_atom_22764.png
L_0859	direction	T_4316	FIGURE 1.1	image	textbook_images/direction_22769.png
L_0861	distance	T_4324	FIGURE 1.1	image	textbook_images/distance_22772.png
L_0862	doppler effect	T_4326	FIGURE 1.1	image	textbook_images/doppler_effect_22773.png
L_0863	earth as a magnet	T_4328	FIGURE 1.1	image	textbook_images/earth_as_a_magnet_22774.png
L_0863	earth as a magnet	T_4328	FIGURE 1.2 needle point instead? It points to Earths north magnetic pole, which is located at about 80 north latitude. Earth also has two south poles: a south geographic pole and a south magnetic pole.	image	textbook_images/earth_as_a_magnet_22775.png
L_0863	earth as a magnet	T_4329	FIGURE 1.3	image	textbook_images/earth_as_a_magnet_22776.png
L_0864	efficiency	T_4331	FIGURE 1.1	image	textbook_images/efficiency_22777.png
L_0865	einsteins concept of gravity	T_4335	FIGURE 1.1 This diagram shows how Earths mass bends the fabric of space and time around it, causing smaller objects such as satellites to move toward Earth.	image	textbook_images/einsteins_concept_of_gravity_22778.png
L_0866	elastic force	T_4337	FIGURE 1.1 And like stretchy materials, they return to their original shape when the stretching or compressing force is released. Springs are used in scales to measure weight. They also cushion the ride in a car.	image	textbook_images/elastic_force_22779.png
L_0866	elastic force	T_4337	FIGURE 1.2	image	textbook_images/elastic_force_22780.png
L_0881	electromagnetic spectrum	T_4380	FIGURE 1.1	image	textbook_images/electromagnetic_spectrum_22802.png
L_0882	electromagnetic waves	T_4382	FIGURE 1.1	image	textbook_images/electromagnetic_waves_22803.png
L_0882	electromagnetic waves	T_4383	FIGURE 1.2	image	textbook_images/electromagnetic_waves_22804.png
L_0882	electromagnetic waves	T_4383	FIGURE 1.3	image	textbook_images/electromagnetic_waves_22805.png
L_0884	electron cloud atomic model	T_4391	FIGURE 1.1	image	textbook_images/electron_cloud_atomic_model_22807.png
L_0884	electron cloud atomic model	T_4391	FIGURE 1.2	image	textbook_images/electron_cloud_atomic_model_22808.png
L_0884	electron cloud atomic model	T_4392	FIGURE 1.3	image	textbook_images/electron_cloud_atomic_model_22809.png
L_0888	electrons	T_4405	FIGURE 1.1	image	textbook_images/electrons_22817.png
L_0888	electrons	T_4406	FIGURE 1.2	image	textbook_images/electrons_22818.png
L_0888	electrons	T_4407	FIGURE 1.3	image	textbook_images/electrons_22819.png
L_0889	elements	T_4409	FIGURE 1.1	image	textbook_images/elements_22820.png
L_0889	elements	T_4410	FIGURE 1.2 The red lights in this sign contain the element neon.	image	textbook_images/elements_22821.png
L_0889	elements	T_4411	FIGURE 1.3 substance?	image	textbook_images/elements_22822.png
L_0890	endothermic reactions	T_4413	FIGURE 1.1	image	textbook_images/endothermic_reactions_22823.png
L_0891	energy	T_4416	FIGURE 1.1	image	textbook_images/energy_22825.png
L_0893	energy level	T_4423	FIGURE 1.1	image	textbook_images/energy_level_22826.png
L_0893	energy level	T_4424	FIGURE 1.2	image	textbook_images/energy_level_22827.png
L_0893	energy level	T_4425	FIGURE 1.3	image	textbook_images/energy_level_22828.png
L_0893	energy level	T_4425	FIGURE 1.4 hold only eight electrons. This means that is outermost energy level is full. Therefore, a neon atom is very stable.	image	textbook_images/energy_level_22829.png
L_0894	enzymes as catalysts	T_4427	FIGURE 1.1	image	textbook_images/enzymes_as_catalysts_22830.png
L_0894	enzymes as catalysts	T_4428	FIGURE 1.2	image	textbook_images/enzymes_as_catalysts_22831.png
L_0897	exothermic reactions	T_4436	FIGURE 1.1	image	textbook_images/exothermic_reactions_22835.png
L_0898	external combustion engines	T_4439	FIGURE 1.1	image	textbook_images/external_combustion_engines_22837.png
L_0899	ferromagnetic material	T_4440	FIGURE 1.1 Magnetic domains must be lined up by an outside magnetic field for most ferromag- netic materials to become magnets.	image	textbook_images/ferromagnetic_material_22838.png
L_0899	ferromagnetic material	T_4441	FIGURE 1.2	image	textbook_images/ferromagnetic_material_22839.png
L_0899	ferromagnetic material	T_4441	FIGURE 1.3 A: Jarring or heating a magnet moves the magnetic domains out of alignment. When the magnetic domains no longer line up in the same direction, the material is no longer magnetic.	image	textbook_images/ferromagnetic_material_22840.png

L_0811

bohrs atomic model

T_4170

FIGURE 1.1

image

textbook_images/bohrs_atomic_model_22681.png

L_0811

bohrs atomic model

T_4172

FIGURE 1.2

image

textbook_images/bohrs_atomic_model_22682.png

L_0813

bond polarity

T_4176

FIGURE 1.1

image

textbook_images/bond_polarity_22683.png

L_0813

bond polarity

T_4176

FIGURE 1.2

image

textbook_images/bond_polarity_22684.png

L_0813

bond polarity

T_4177

FIGURE 1.3

image

textbook_images/bond_polarity_22685.png

L_0815

buoyancy

T_4183

FIGURE 1.1

image

textbook_images/buoyancy_22689.png

L_0815

buoyancy

T_4183

FIGURE 1.2 Because of buoyant force, objects seem lighter in water. You may have noticed this when you went swimming and could easily pick up a friend or sibling under the water. Some of the persons weight was countered by the buoyant force of the water.

image

textbook_images/buoyancy_22690.png

L_0815

buoyancy

T_4184

FIGURE 1.3

image

textbook_images/buoyancy_22691.png

L_0816

calculating acceleration from force and mass

T_4187

FIGURE 1.1 A: It would take only 32 N of force (40 kg 0.8 m/s2 ).

image

textbook_images/calculating_acceleration_from_force_and_mass_22692.png

L_0817

calculating acceleration from velocity and time

T_4189

FIGURE 1.1

image

textbook_images/calculating_acceleration_from_velocity_and_time_22694.png

L_0819

calculating work

T_4197

FIGURE 1.1

image

textbook_images/calculating_work_22695.png

L_0820

carbohydrate classification

T_4199

FIGURE 1.1 Note: Each unlettered point where lines intersect represents a carbon atom.

image

textbook_images/carbohydrate_classification_22696.png

L_0820

carbohydrate classification

T_4201

FIGURE 1.2

image

textbook_images/carbohydrate_classification_22697.png

L_0820

carbohydrate classification

T_4201

FIGURE 1.3

image

textbook_images/carbohydrate_classification_22698.png

L_0821

carbon bonding

T_4203

FIGURE 1.1

image

textbook_images/carbon_bonding_22699.png

L_0821

carbon bonding

T_4204

FIGURE 1.2

image

textbook_images/carbon_bonding_22700.png

L_0821

carbon bonding

T_4205

FIGURE 1.3

image

textbook_images/carbon_bonding_22701.png

L_0822

carbon monomers and polymers

T_4207

FIGURE 1.1

image

textbook_images/carbon_monomers_and_polymers_22702.png

L_0822

carbon monomers and polymers

T_4207

FIGURE 1.2

image

textbook_images/carbon_monomers_and_polymers_22703.png

L_0822

carbon monomers and polymers

T_4208

FIGURE 1.3

image

textbook_images/carbon_monomers_and_polymers_22704.png

L_0822

carbon monomers and polymers

T_4208

FIGURE 1.4

image

textbook_images/carbon_monomers_and_polymers_22705.png

L_0823

catalysts

T_4210

FIGURE 1.1

image

textbook_images/catalysts_22706.png

L_0823

catalysts

T_4211

FIGURE 1.2 Q: If you chew a starchy food such as a soda cracker for a couple of minutes, you may notice that it starts to taste slightly sweet. Why does this happen?

image

textbook_images/catalysts_22707.png

L_0824

cellular respiration reactions

T_4212

FIGURE 1.1

image

textbook_images/cellular_respiration_reactions_22708.png

L_0828

chemical bond

T_4221

FIGURE 1.1

image

textbook_images/chemical_bond_22714.png

L_0830

chemical equations

T_4227

FIGURE 1.1

image

textbook_images/chemical_equations_22717.png

L_0833

chemical reaction overview

T_4235

FIGURE 1.1

image

textbook_images/chemical_reaction_overview_22719.png

L_0833

chemical reaction overview

T_4236

FIGURE 1.2

image

textbook_images/chemical_reaction_overview_22720.png

L_0834

chemical reaction rate

T_4240

FIGURE 1.1

image

textbook_images/chemical_reaction_rate_22721.png

L_0834

chemical reaction rate

T_4241

FIGURE 1.2

image

textbook_images/chemical_reaction_rate_22722.png

L_0834

chemical reaction rate

T_4242

FIGURE 1.3

image

textbook_images/chemical_reaction_rate_22723.png

L_0835

chemistry of compounds

T_4244

FIGURE 1.1 All water molecules have two hydrogen atoms (gray) and one oxygen atom (blue).

image

textbook_images/chemistry_of_compounds_22724.png

L_0835

chemistry of compounds

T_4245

FIGURE 1.2 Water: Water is odorless and colorless. We drink it, bathe in it, and use it to wash our clothes. In fact, we cant live without it. Hydrogen Peroxide: Hydrogen peroxide is also odorless and colorless. Its used as an antiseptic to kill germs on cuts. Its also used as bleach to remove color form hair. A: You can tell that they are different compounds from their very different properties. Carbon dioxide is a harmless gas that living things add to the atmosphere during respiration. Carbon monoxide is a deadly gas that can quickly kill people if it becomes too concentrated in the air.

image

textbook_images/chemistry_of_compounds_22725.png

L_0835

chemistry of compounds

T_4245

FIGURE 1.3

image

textbook_images/chemistry_of_compounds_22726.png

L_0836

color

T_4248

FIGURE 1.1

image

textbook_images/color_22727.png

L_0836

color

T_4248

FIGURE 1.2

image

textbook_images/color_22728.png

L_0836

color

T_4249

FIGURE 1.3 light of different colors.

image

textbook_images/color_22729.png

L_0836

color

T_4249

FIGURE 1.4

image

textbook_images/color_22730.png

L_0836

color

T_4250

FIGURE 1.5

image

textbook_images/color_22731.png

L_0837

combining forces

T_4253

FIGURE 1.1

image

textbook_images/combining_forces_22733.png

L_0838

combustion reactions

T_4254

FIGURE 1.1

image

textbook_images/combustion_reactions_22734.png

L_0838

combustion reactions

T_4255

FIGURE 1.2

image

textbook_images/combustion_reactions_22735.png

L_0840

compound machine

T_4260

FIGURE 1.1

image

textbook_images/compound_machine_22737.png

L_0840

compound machine

T_4260

FIGURE 1.2

image

textbook_images/compound_machine_22738.png

L_0841

compounds

T_4263

FIGURE 1.1

image

textbook_images/compounds_22740.png

L_0841

compounds

T_4265

FIGURE 1.2

image

textbook_images/compounds_22741.png

L_0841

compounds

T_4265

FIGURE 1.3

image

textbook_images/compounds_22742.png

L_0843

conservation of energy in chemical reactions

T_4270

FIGURE 1.1

image

textbook_images/conservation_of_energy_in_chemical_reactions_22746.png

L_0846

conservation of mass in chemical reactions

T_4277

FIGURE 1.1 Antoine Lavoisier.

image

textbook_images/conservation_of_mass_in_chemical_reactions_22748.png

L_0847

convection

T_4279

FIGURE 1.1

image

textbook_images/convection_22749.png

L_0847

convection

T_4280

FIGURE 1.2

image

textbook_images/convection_22750.png

L_0848

cooling systems

T_4283

FIGURE 1.1

image

textbook_images/cooling_systems_22751.png

L_0849

covalent bonding

T_4285

FIGURE 1.1

image

textbook_images/covalent_bonding_22752.png

L_0849

covalent bonding

T_4285

FIGURE 1.2

image

textbook_images/covalent_bonding_22753.png

L_0850

crystalline carbon

T_4288

FIGURE 1.1

image

textbook_images/crystalline_carbon_22754.png

L_0850

crystalline carbon

T_4288

FIGURE 1.2

image

textbook_images/crystalline_carbon_22755.png

L_0850

crystalline carbon

T_4289

FIGURE 1.3

image

textbook_images/crystalline_carbon_22756.png

L_0850

crystalline carbon

T_4290

FIGURE 1.4

image

textbook_images/crystalline_carbon_22757.png

L_0851

daltons atomic theory

T_4292

FIGURE 1.1

image

textbook_images/daltons_atomic_theory_22758.png

L_0851

daltons atomic theory

T_4294

FIGURE 1.2

image

textbook_images/daltons_atomic_theory_22759.png

L_0852

dangers and uses of radiation

T_4297

FIGURE 1.1

image

textbook_images/dangers_and_uses_of_radiation_22760.png

L_0853

decomposition reactions

T_4300

FIGURE 1.1

image

textbook_images/decomposition_reactions_22762.png

L_0854

democrituss idea of the atom

T_4302

FIGURE 1.1

image

textbook_images/democrituss_idea_of_the_atom_22763.png

L_0854

democrituss idea of the atom

T_4304

FIGURE 1.2

image

textbook_images/democrituss_idea_of_the_atom_22764.png

L_0859

direction

T_4316

FIGURE 1.1

image

textbook_images/direction_22769.png

L_0861

distance

T_4324

FIGURE 1.1

image

textbook_images/distance_22772.png

L_0862

doppler effect

T_4326

FIGURE 1.1

image

textbook_images/doppler_effect_22773.png

L_0863

earth as a magnet

T_4328

FIGURE 1.1

image

textbook_images/earth_as_a_magnet_22774.png

L_0863

earth as a magnet

T_4328

FIGURE 1.2 needle point instead? It points to Earths north magnetic pole, which is located at about 80 north latitude. Earth also has two south poles: a south geographic pole and a south magnetic pole.

image

textbook_images/earth_as_a_magnet_22775.png

L_0863

earth as a magnet

T_4329

FIGURE 1.3

image

textbook_images/earth_as_a_magnet_22776.png

L_0864

efficiency

T_4331

FIGURE 1.1

image

textbook_images/efficiency_22777.png

L_0865

einsteins concept of gravity

T_4335

FIGURE 1.1 This diagram shows how Earths mass bends the fabric of space and time around it, causing smaller objects such as satellites to move toward Earth.

image

textbook_images/einsteins_concept_of_gravity_22778.png

L_0866

elastic force

T_4337

FIGURE 1.1 And like stretchy materials, they return to their original shape when the stretching or compressing force is released. Springs are used in scales to measure weight. They also cushion the ride in a car.

image

textbook_images/elastic_force_22779.png

L_0866

elastic force

T_4337

FIGURE 1.2

image

textbook_images/elastic_force_22780.png

L_0881

electromagnetic spectrum

T_4380

FIGURE 1.1

image

textbook_images/electromagnetic_spectrum_22802.png

L_0882

electromagnetic waves

T_4382

FIGURE 1.1

image

textbook_images/electromagnetic_waves_22803.png

L_0882

electromagnetic waves

T_4383

FIGURE 1.2

image

textbook_images/electromagnetic_waves_22804.png

L_0882

electromagnetic waves

T_4383

FIGURE 1.3

image

textbook_images/electromagnetic_waves_22805.png

L_0884

electron cloud atomic model

T_4391

FIGURE 1.1

image

textbook_images/electron_cloud_atomic_model_22807.png

L_0884

electron cloud atomic model

T_4391

FIGURE 1.2

image

textbook_images/electron_cloud_atomic_model_22808.png

L_0884

electron cloud atomic model

T_4392

FIGURE 1.3

image

textbook_images/electron_cloud_atomic_model_22809.png

L_0888

electrons

T_4405

FIGURE 1.1

image

textbook_images/electrons_22817.png

L_0888

electrons

T_4406

FIGURE 1.2

image

textbook_images/electrons_22818.png

L_0888

electrons

T_4407

FIGURE 1.3

image

textbook_images/electrons_22819.png

L_0889

elements

T_4409

FIGURE 1.1

image

textbook_images/elements_22820.png

L_0889

elements

T_4410

FIGURE 1.2 The red lights in this sign contain the element neon.

image

textbook_images/elements_22821.png

L_0889

elements

T_4411

FIGURE 1.3 substance?

image

textbook_images/elements_22822.png

L_0890

endothermic reactions

T_4413

FIGURE 1.1

image

textbook_images/endothermic_reactions_22823.png

L_0891

energy

T_4416

FIGURE 1.1

image

textbook_images/energy_22825.png

L_0893

energy level

T_4423

FIGURE 1.1

image

textbook_images/energy_level_22826.png

L_0893

energy level

T_4424

FIGURE 1.2

image

textbook_images/energy_level_22827.png

L_0893

energy level

T_4425

FIGURE 1.3

image

textbook_images/energy_level_22828.png

L_0893

energy level

T_4425

FIGURE 1.4 hold only eight electrons. This means that is outermost energy level is full. Therefore, a neon atom is very stable.

image

textbook_images/energy_level_22829.png

L_0894

enzymes as catalysts

T_4427

FIGURE 1.1

image

textbook_images/enzymes_as_catalysts_22830.png

L_0894

enzymes as catalysts

T_4428

FIGURE 1.2

image

textbook_images/enzymes_as_catalysts_22831.png

L_0897

exothermic reactions

T_4436

FIGURE 1.1

image

textbook_images/exothermic_reactions_22835.png

L_0898

external combustion engines

T_4439

FIGURE 1.1

image

textbook_images/external_combustion_engines_22837.png

L_0899

ferromagnetic material

T_4440

FIGURE 1.1 Magnetic domains must be lined up by an outside magnetic field for most ferromag- netic materials to become magnets.

image

textbook_images/ferromagnetic_material_22838.png

L_0899

ferromagnetic material

T_4441

FIGURE 1.2

image

textbook_images/ferromagnetic_material_22839.png

L_0899

ferromagnetic material

T_4441

FIGURE 1.3 A: Jarring or heating a magnet moves the magnetic domains out of alignment. When the magnetic domains no longer line up in the same direction, the material is no longer magnetic.

image

textbook_images/ferromagnetic_material_22840.png