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_0963	neutrons	T_4649	FIGURE 1.1	image	textbook_images/neutrons_22969.png
L_0963	neutrons	T_4651	FIGURE 1.2	image	textbook_images/neutrons_22970.png
L_0964	newtons first law	T_4653	FIGURE 1.1	image	textbook_images/newtons_first_law_22971.png
L_0964	newtons first law	T_4653	FIGURE 1.2	image	textbook_images/newtons_first_law_22972.png
L_0964	newtons first law	T_4655	FIGURE 1.3	image	textbook_images/newtons_first_law_22973.png
L_0965	newtons law of gravity	T_4658	FIGURE 1.1	image	textbook_images/newtons_law_of_gravity_22975.png
L_0966	newtons second law	T_4659	FIGURE 1.1	image	textbook_images/newtons_second_law_22976.png
L_0967	newtons third law	T_4662	FIGURE 1.1	image	textbook_images/newtons_third_law_22977.png
L_0968	noble gases	T_4664	FIGURE 1.1	image	textbook_images/noble_gases_22978.png
L_0968	noble gases	T_4667	FIGURE 1.2 Q: How does argon prevent the problems of early light bulbs?	image	textbook_images/noble_gases_22979.png
L_0968	noble gases	T_4667	FIGURE 1.3	image	textbook_images/noble_gases_22980.png
L_0969	nonmetals	T_4670	FIGURE 1.1	image	textbook_images/nonmetals_22982.png
L_0969	nonmetals	T_4670	FIGURE 1.2 such as the metal lithium or sodium. As a result, fluorine is highly reactive. In fact, reactions with fluorine are often explosive. Neon, on the other hand, already has a full outer energy level. It is already very stable and never reacts with other elements. It neither accepts nor gives up electrons. Neon doesnt even react with fluorine, which reacts with all other elements except helium.	image	textbook_images/nonmetals_22983.png
L_0970	nuclear fission	T_4672	FIGURE 1.1	image	textbook_images/nuclear_fission_22984.png
L_0970	nuclear fission	T_4673	FIGURE 1.2	image	textbook_images/nuclear_fission_22985.png
L_0970	nuclear fission	T_4675	FIGURE 1.3	image	textbook_images/nuclear_fission_22986.png
L_0970	nuclear fission	T_4675	FIGURE 1.4	image	textbook_images/nuclear_fission_22987.png
L_0971	nuclear fusion	T_4677	FIGURE 1.1 Nuclear Fusion	image	textbook_images/nuclear_fusion_22988.png
L_0971	nuclear fusion	T_4678	FIGURE 1.2	image	textbook_images/nuclear_fusion_22989.png
L_0971	nuclear fusion	T_4679	FIGURE 1.3	image	textbook_images/nuclear_fusion_22990.png
L_0972	nucleic acid classification	T_4681	FIGURE 1.1	image	textbook_images/nucleic_acid_classification_22991.png
L_0972	nucleic acid classification	T_4683	FIGURE 1.2	image	textbook_images/nucleic_acid_classification_22992.png
L_0972	nucleic acid classification	DD_0270	The diagram shows the structure of deoxyribonucleic acid (DNA) which carries the genetic information of organisms. DNA is made up of a double helix of two complementary strands. The strands of the double helix are anti-parallel with one being 5' to 3', and the opposite strand 3' to 5'. Each single strand of DNA is a chain of four types of nucleotides. The four types of nucleotide correspond to the four nucleobases adenine, cytosine, guanine, and thymine, commonly abbreviated as A,C, G and T. Adenine pairs with thymine (two hydrogen bonds), and guanine pairs with cytosine (three hydrogen bonds). During DNA replication, the parent DNA unwinds and each parental strand serves as a template for replication of new strands. Nucleobases are matched to synthesize the new daughter strands.	image	teaching_images/dna_6763.png
L_0972	nucleic acid classification	DD_0271	This diagram shows the structure of a DNA or deoxyribonucleic acid . Deoxyribonucleic acid is a molecule that carries the genetic instructions used in the growth, development, functioning and reproduction of all known living organisms and many viruses. Most DNA molecules consist of two strands coiled around each other to form a double helix.The two DNA strands are composed of simpler units called nucleotides. Each nucleotide is composed of one of four nitrogen-containing compoundsâeither cytosine (C), guanine (G), adenine (A), or thymine (T). The nucleotides are joined to one another in a chain by covalent bonds between the sugar of one nucleotide and the phosphate of the next, resulting in an alternating sugar-phosphate backbone.	image	teaching_images/dna_8052.png
L_0976	optical instruments	T_4692	FIGURE 1.1	image	textbook_images/optical_instruments_22996.png
L_0976	optical instruments	T_4693	FIGURE 1.2	image	textbook_images/optical_instruments_22997.png
L_0976	optical instruments	T_4694	FIGURE 1.3	image	textbook_images/optical_instruments_22998.png
L_0976	optical instruments	T_4695	FIGURE 1.4	image	textbook_images/optical_instruments_22999.png
L_0976	optical instruments	T_4695	FIGURE 1.5	image	textbook_images/optical_instruments_23000.png
L_0976	optical instruments	T_4696	FIGURE 1.6	image	textbook_images/optical_instruments_23001.png
L_0977	orbital motion	T_4698	FIGURE 1.1	image	textbook_images/orbital_motion_23002.png
L_0977	orbital motion	T_4698	FIGURE 1.2	image	textbook_images/orbital_motion_23003.png
L_0979	ph concept	T_4705	FIGURE 1.1	image	textbook_images/ph_concept_23007.png
L_0979	ph concept	T_4706	FIGURE 1.2	image	textbook_images/ph_concept_23008.png
L_0979	ph concept	T_4706	FIGURE 1.3	image	textbook_images/ph_concept_23009.png
L_0980	photosynthesis reactions	T_4708	FIGURE 1.1	image	textbook_images/photosynthesis_reactions_23010.png
L_0980	photosynthesis reactions	T_4708	FIGURE 1.2 The green streaks on this very blue lake are photosynthetic bacteria called cyanobacteria.	image	textbook_images/photosynthesis_reactions_23011.png
L_0985	position time graphs	T_4726	FIGURE 1.1	image	textbook_images/position_time_graphs_23020.png
L_0985	position time graphs	T_4726	FIGURE 1.2	image	textbook_images/position_time_graphs_23021.png
L_0986	potential energy	T_4729	FIGURE 1.1	image	textbook_images/potential_energy_23022.png
L_0986	potential energy	T_4731	FIGURE 1.2	image	textbook_images/potential_energy_23023.png
L_0986	potential energy	T_4731	FIGURE 1.3	image	textbook_images/potential_energy_23024.png
L_0987	power	T_4732	FIGURE 1.1	image	textbook_images/power_23025.png
L_0987	power	T_4735	FIGURE 1.2	image	textbook_images/power_23026.png
L_0987	power	T_4735	FIGURE 1.3	image	textbook_images/power_23027.png
L_0989	projectile motion	T_4742	FIGURE 1.1	image	textbook_images/projectile_motion_23031.png
L_0989	projectile motion	T_4742	FIGURE 1.2	image	textbook_images/projectile_motion_23032.png
L_0989	projectile motion	T_4742	FIGURE 1.3	image	textbook_images/projectile_motion_23033.png
L_0990	properties of acids	T_4744	FIGURE 1.1 Hydrochloric acid reacting with the metal zinc.	image	textbook_images/properties_of_acids_23034.png
L_0990	properties of acids	T_4745	FIGURE 1.2	image	textbook_images/properties_of_acids_23035.png
L_0990	properties of acids	T_4747	FIGURE 1.3 Nitric acid and Phosphoric acid: Both nitric acid and phosphoric acid are used to make fertilizer. Hydrochloric acid: Hy- drochloric acid is used to clean swimming pools, bricks, and concrete. Sulfuric acid: Sulfuric Acid is an important component of car batteries.	image	textbook_images/properties_of_acids_23036.png
L_0991	properties of bases	T_4750	FIGURE 1.1	image	textbook_images/properties_of_bases_23037.png
L_0991	properties of bases	T_4752	FIGURE 1.2	image	textbook_images/properties_of_bases_23038.png
L_0992	properties of electromagnetic waves	T_4754	FIGURE 1.1	image	textbook_images/properties_of_electromagnetic_waves_23039.png
L_0994	protein classification	T_4760	FIGURE 1.1	image	textbook_images/protein_classification_23042.png
L_0994	protein classification	T_4761	FIGURE 1.2 The blood protein hemoglobin binds with oxygen and carries it from the lungs to all the bodys cells. Heme is a small molecule containing iron that is part of the larger hemoglobin molecule. Oxygen binds to the iron in heme.	image	textbook_images/protein_classification_23043.png
L_0997	radio waves	T_4769	FIGURE 1.1	image	textbook_images/radio_waves_23045.png
L_0997	radio waves	T_4770	FIGURE 1.2	image	textbook_images/radio_waves_23046.png
L_0999	radioactivity	T_4778	FIGURE 1.1	image	textbook_images/radioactivity_23048.png
L_1000	radioisotopes	T_4780	FIGURE 1.1	image	textbook_images/radioisotopes_23049.png
L_1002	reactants and products	T_4788	FIGURE 1.1	image	textbook_images/reactants_and_products_23051.png
L_1003	recognizing chemical reactions	T_4790	FIGURE 1.1	image	textbook_images/recognizing_chemical_reactions_23052.png
L_1003	recognizing chemical reactions	T_4790	FIGURE 1.2	image	textbook_images/recognizing_chemical_reactions_23053.png
L_1003	recognizing chemical reactions	T_4790	FIGURE 1.3	image	textbook_images/recognizing_chemical_reactions_23054.png
L_1007	rutherfords atomic model	T_4800	FIGURE 1.1	image	textbook_images/rutherfords_atomic_model_23057.png
L_1007	rutherfords atomic model	T_4800	FIGURE 1.2	image	textbook_images/rutherfords_atomic_model_23058.png
L_1007	rutherfords atomic model	T_4802	FIGURE 1.3	image	textbook_images/rutherfords_atomic_model_23059.png
L_1009	saturated hydrocarbons	T_4807	FIGURE 1.1	image	textbook_images/saturated_hydrocarbons_23060.png
L_1009	saturated hydrocarbons	T_4808	FIGURE 1.2 4. Compare and contrast straight-chain, branched-chain, and cyclic alkanes.	image	textbook_images/saturated_hydrocarbons_23061.png
L_1019	scope of chemistry	T_4837	FIGURE 1.1	image	textbook_images/scope_of_chemistry_23071.png
L_1021	scope of physics	T_4841	FIGURE 1.1	image	textbook_images/scope_of_physics_23073.png
L_1022	screw	T_4842	FIGURE 1.1	image	textbook_images/screw_23074.png
L_1022	screw	T_4843	FIGURE 1.2	image	textbook_images/screw_23075.png
L_1025	simple machines	T_4853	FIGURE 1.1	image	textbook_images/simple_machines_23076.png
L_1025	simple machines	T_4856	FIGURE 1.2	image	textbook_images/simple_machines_23077.png
L_1025	simple machines	T_4856	FIGURE 1.3	image	textbook_images/simple_machines_23078.png
L_1025	simple machines	T_4856	FIGURE 1.4	image	textbook_images/simple_machines_23079.png
L_1032	sound waves	T_4876	FIGURE 1.1	image	textbook_images/sound_waves_23092.png
L_1033	sources of visible light	T_4880	FIGURE 1.1	image	textbook_images/sources_of_visible_light_23094.png
L_1033	sources of visible light	T_4882	FIGURE 1.2	image	textbook_images/sources_of_visible_light_23095.png
L_1033	sources of visible light	T_4882	FIGURE 1.3	image	textbook_images/sources_of_visible_light_23096.png
L_1035	speed	T_4887	FIGURE 1.1	image	textbook_images/speed_23098.png
L_1038	static electricity and static discharge	T_4897	FIGURE 1.1	image	textbook_images/static_electricity_and_static_discharge_23101.png
L_1040	surface wave	T_4901	FIGURE 1.1	image	textbook_images/surface_wave_23103.png
L_1041	synthesis reactions	T_4904	FIGURE 1.1	image	textbook_images/synthesis_reactions_23105.png
L_1045	technology and society	T_4914	FIGURE 1.1 This is a museum model similar to the steam engine invented by James Watt.	image	textbook_images/technology_and_society_23110.png
L_1048	thermal conductors and insulators	T_4920	FIGURE 1.1	image	textbook_images/thermal_conductors_and_insulators_23114.png
L_1048	thermal conductors and insulators	T_4921	FIGURE 1.2	image	textbook_images/thermal_conductors_and_insulators_23115.png
L_1048	thermal conductors and insulators	T_4921	FIGURE 1.3	image	textbook_images/thermal_conductors_and_insulators_23116.png
L_1049	thermal energy	T_4923	FIGURE 1.1	image	textbook_images/thermal_energy_23117.png
L_1050	thermal radiation	T_4925	FIGURE 1.1	image	textbook_images/thermal_radiation_23118.png
L_1051	thomsons atomic model	T_4927	FIGURE 1.1	image	textbook_images/thomsons_atomic_model_23120.png
L_1051	thomsons atomic model	T_4927	FIGURE 1.2	image	textbook_images/thomsons_atomic_model_23121.png
L_1051	thomsons atomic model	T_4928	FIGURE 1.3	image	textbook_images/thomsons_atomic_model_23122.png
L_1052	transfer of electric charge	T_4929	FIGURE 1.1	image	textbook_images/transfer_of_electric_charge_23124.png
L_1052	transfer of electric charge	T_4932	FIGURE 1.2	image	textbook_images/transfer_of_electric_charge_23125.png
L_1052	transfer of electric charge	T_4933	FIGURE 1.3 A: Electrons are transferred from the wall to the balloon, making the balloon negatively charged and the wall positively charged. The balloon sticks to the wall because opposite charges attract.	image	textbook_images/transfer_of_electric_charge_23126.png
L_1053	transition metals	T_4935	FIGURE 1.1	image	textbook_images/transition_metals_23127.png
L_1053	transition metals	T_4935	FIGURE 1.2 Other properties of the transition metals are unique. They are the only elements that may use electrons in the next to highestas well as the highestenergy level as valence electrons. Valence electrons are the electrons that form bonds with other elements in compounds and that generally determine the properties of elements. Transition metals are unusual in having very similar properties even with different numbers of valence electrons. The transition metals also include the only elements that produce a magnetic field. Three of them have this property: iron (Fe), cobalt (Co), and nickel (Ni).	image	textbook_images/transition_metals_23128.png
L_1054	transverse wave	T_4937	FIGURE 1.1	image	textbook_images/transverse_wave_23129.png

L_0963

neutrons

T_4649

FIGURE 1.1

image

textbook_images/neutrons_22969.png

L_0963

neutrons

T_4651

FIGURE 1.2

image

textbook_images/neutrons_22970.png

L_0964

newtons first law

T_4653

FIGURE 1.1

image

textbook_images/newtons_first_law_22971.png

L_0964

newtons first law

T_4653

FIGURE 1.2

image

textbook_images/newtons_first_law_22972.png

L_0964

newtons first law

T_4655

FIGURE 1.3

image

textbook_images/newtons_first_law_22973.png

L_0965

newtons law of gravity

T_4658

FIGURE 1.1

image

textbook_images/newtons_law_of_gravity_22975.png

L_0966

newtons second law

T_4659

FIGURE 1.1

image

textbook_images/newtons_second_law_22976.png

L_0967

newtons third law

T_4662

FIGURE 1.1

image

textbook_images/newtons_third_law_22977.png

L_0968

noble gases

T_4664

FIGURE 1.1

image

textbook_images/noble_gases_22978.png

L_0968

noble gases

T_4667

FIGURE 1.2 Q: How does argon prevent the problems of early light bulbs?

image

textbook_images/noble_gases_22979.png

L_0968

noble gases

T_4667

FIGURE 1.3

image

textbook_images/noble_gases_22980.png

L_0969

nonmetals

T_4670

FIGURE 1.1

image

textbook_images/nonmetals_22982.png

L_0969

nonmetals

T_4670

FIGURE 1.2 such as the metal lithium or sodium. As a result, fluorine is highly reactive. In fact, reactions with fluorine are often explosive. Neon, on the other hand, already has a full outer energy level. It is already very stable and never reacts with other elements. It neither accepts nor gives up electrons. Neon doesnt even react with fluorine, which reacts with all other elements except helium.

image

textbook_images/nonmetals_22983.png

L_0970

nuclear fission

T_4672

FIGURE 1.1

image

textbook_images/nuclear_fission_22984.png

L_0970

nuclear fission

T_4673

FIGURE 1.2

image

textbook_images/nuclear_fission_22985.png

L_0970

nuclear fission

T_4675

FIGURE 1.3

image

textbook_images/nuclear_fission_22986.png

L_0970

nuclear fission

T_4675

FIGURE 1.4

image

textbook_images/nuclear_fission_22987.png

L_0971

nuclear fusion

T_4677

FIGURE 1.1 Nuclear Fusion

image

textbook_images/nuclear_fusion_22988.png

L_0971

nuclear fusion

T_4678

FIGURE 1.2

image

textbook_images/nuclear_fusion_22989.png

L_0971

nuclear fusion

T_4679

FIGURE 1.3

image

textbook_images/nuclear_fusion_22990.png

L_0972

nucleic acid classification

T_4681

FIGURE 1.1

image

textbook_images/nucleic_acid_classification_22991.png

L_0972

nucleic acid classification

T_4683

FIGURE 1.2

image

textbook_images/nucleic_acid_classification_22992.png

L_0972

nucleic acid classification

DD_0270

The diagram shows the structure of deoxyribonucleic acid (DNA) which carries the genetic information of organisms. DNA is made up of a double helix of two complementary strands. The strands of the double helix are anti-parallel with one being 5' to 3', and the opposite strand 3' to 5'. Each single strand of DNA is a chain of four types of nucleotides. The four types of nucleotide correspond to the four nucleobases adenine, cytosine, guanine, and thymine, commonly abbreviated as A,C, G and T. Adenine pairs with thymine (two hydrogen bonds), and guanine pairs with cytosine (three hydrogen bonds). During DNA replication, the parent DNA unwinds and each parental strand serves as a template for replication of new strands. Nucleobases are matched to synthesize the new daughter strands.

image

teaching_images/dna_6763.png

L_0972

nucleic acid classification

DD_0271

This diagram shows the structure of a DNA or deoxyribonucleic acid . Deoxyribonucleic acid is a molecule that carries the genetic instructions used in the growth, development, functioning and reproduction of all known living organisms and many viruses. Most DNA molecules consist of two strands coiled around each other to form a double helix.The two DNA strands are composed of simpler units called nucleotides. Each nucleotide is composed of one of four nitrogen-containing compoundsâeither cytosine (C), guanine (G), adenine (A), or thymine (T). The nucleotides are joined to one another in a chain by covalent bonds between the sugar of one nucleotide and the phosphate of the next, resulting in an alternating sugar-phosphate backbone.

image

teaching_images/dna_8052.png

L_0976

optical instruments

T_4692

FIGURE 1.1

image

textbook_images/optical_instruments_22996.png

L_0976

optical instruments

T_4693

FIGURE 1.2

image

textbook_images/optical_instruments_22997.png

L_0976

optical instruments

T_4694

FIGURE 1.3

image

textbook_images/optical_instruments_22998.png

L_0976

optical instruments

T_4695

FIGURE 1.4

image

textbook_images/optical_instruments_22999.png

L_0976

optical instruments

T_4695

FIGURE 1.5

image

textbook_images/optical_instruments_23000.png

L_0976

optical instruments

T_4696

FIGURE 1.6

image

textbook_images/optical_instruments_23001.png

L_0977

orbital motion

T_4698

FIGURE 1.1

image

textbook_images/orbital_motion_23002.png

L_0977

orbital motion

T_4698

FIGURE 1.2

image

textbook_images/orbital_motion_23003.png

L_0979

ph concept

T_4705

FIGURE 1.1

image

textbook_images/ph_concept_23007.png

L_0979

ph concept

T_4706

FIGURE 1.2

image

textbook_images/ph_concept_23008.png

L_0979

ph concept

T_4706

FIGURE 1.3

image

textbook_images/ph_concept_23009.png

L_0980

photosynthesis reactions

T_4708

FIGURE 1.1

image

textbook_images/photosynthesis_reactions_23010.png

L_0980

photosynthesis reactions

T_4708

FIGURE 1.2 The green streaks on this very blue lake are photosynthetic bacteria called cyanobacteria.

image

textbook_images/photosynthesis_reactions_23011.png

L_0985

position time graphs

T_4726

FIGURE 1.1

image

textbook_images/position_time_graphs_23020.png

L_0985

position time graphs

T_4726

FIGURE 1.2

image

textbook_images/position_time_graphs_23021.png

L_0986

potential energy

T_4729

FIGURE 1.1

image

textbook_images/potential_energy_23022.png

L_0986

potential energy

T_4731

FIGURE 1.2

image

textbook_images/potential_energy_23023.png

L_0986

potential energy

T_4731

FIGURE 1.3

image

textbook_images/potential_energy_23024.png

L_0987

power

T_4732

FIGURE 1.1

image

textbook_images/power_23025.png

L_0987

power

T_4735

FIGURE 1.2

image

textbook_images/power_23026.png

L_0987

power

T_4735

FIGURE 1.3

image

textbook_images/power_23027.png

L_0989

projectile motion

T_4742

FIGURE 1.1

image

textbook_images/projectile_motion_23031.png

L_0989

projectile motion

T_4742

FIGURE 1.2

image

textbook_images/projectile_motion_23032.png

L_0989

projectile motion

T_4742

FIGURE 1.3

image

textbook_images/projectile_motion_23033.png

L_0990

properties of acids

T_4744

FIGURE 1.1 Hydrochloric acid reacting with the metal zinc.

image

textbook_images/properties_of_acids_23034.png

L_0990

properties of acids

T_4745

FIGURE 1.2

image

textbook_images/properties_of_acids_23035.png

L_0990

properties of acids

T_4747

FIGURE 1.3 Nitric acid and Phosphoric acid: Both nitric acid and phosphoric acid are used to make fertilizer. Hydrochloric acid: Hy- drochloric acid is used to clean swimming pools, bricks, and concrete. Sulfuric acid: Sulfuric Acid is an important component of car batteries.

image

textbook_images/properties_of_acids_23036.png

L_0991

properties of bases

T_4750

FIGURE 1.1

image

textbook_images/properties_of_bases_23037.png

L_0991

properties of bases

T_4752

FIGURE 1.2

image

textbook_images/properties_of_bases_23038.png

L_0992

properties of electromagnetic waves

T_4754

FIGURE 1.1

image

textbook_images/properties_of_electromagnetic_waves_23039.png

L_0994

protein classification

T_4760

FIGURE 1.1

image

textbook_images/protein_classification_23042.png

L_0994

protein classification

T_4761

FIGURE 1.2 The blood protein hemoglobin binds with oxygen and carries it from the lungs to all the bodys cells. Heme is a small molecule containing iron that is part of the larger hemoglobin molecule. Oxygen binds to the iron in heme.

image

textbook_images/protein_classification_23043.png

L_0997

radio waves

T_4769

FIGURE 1.1

image

textbook_images/radio_waves_23045.png

L_0997

radio waves

T_4770

FIGURE 1.2

image

textbook_images/radio_waves_23046.png

L_0999

radioactivity

T_4778

FIGURE 1.1

image

textbook_images/radioactivity_23048.png

L_1000

radioisotopes

T_4780

FIGURE 1.1

image

textbook_images/radioisotopes_23049.png

L_1002

reactants and products

T_4788

FIGURE 1.1

image

textbook_images/reactants_and_products_23051.png

L_1003

recognizing chemical reactions

T_4790

FIGURE 1.1

image

textbook_images/recognizing_chemical_reactions_23052.png

L_1003

recognizing chemical reactions

T_4790

FIGURE 1.2

image

textbook_images/recognizing_chemical_reactions_23053.png

L_1003

recognizing chemical reactions

T_4790

FIGURE 1.3

image

textbook_images/recognizing_chemical_reactions_23054.png

L_1007

rutherfords atomic model

T_4800

FIGURE 1.1

image

textbook_images/rutherfords_atomic_model_23057.png

L_1007

rutherfords atomic model

T_4800

FIGURE 1.2

image

textbook_images/rutherfords_atomic_model_23058.png

L_1007

rutherfords atomic model

T_4802

FIGURE 1.3

image

textbook_images/rutherfords_atomic_model_23059.png

L_1009

saturated hydrocarbons

T_4807

FIGURE 1.1

image

textbook_images/saturated_hydrocarbons_23060.png

L_1009

saturated hydrocarbons

T_4808

FIGURE 1.2 4. Compare and contrast straight-chain, branched-chain, and cyclic alkanes.

image

textbook_images/saturated_hydrocarbons_23061.png

L_1019

scope of chemistry

T_4837

FIGURE 1.1

image

textbook_images/scope_of_chemistry_23071.png

L_1021

scope of physics

T_4841

FIGURE 1.1

image

textbook_images/scope_of_physics_23073.png

L_1022

screw

T_4842

FIGURE 1.1

image

textbook_images/screw_23074.png

L_1022

screw

T_4843

FIGURE 1.2

image

textbook_images/screw_23075.png

L_1025

simple machines

T_4853

FIGURE 1.1

image

textbook_images/simple_machines_23076.png

L_1025

simple machines

T_4856

FIGURE 1.2

image

textbook_images/simple_machines_23077.png

L_1025

simple machines

T_4856

FIGURE 1.3

image

textbook_images/simple_machines_23078.png

L_1025

simple machines

T_4856

FIGURE 1.4

image

textbook_images/simple_machines_23079.png

L_1032

sound waves

T_4876

FIGURE 1.1

image

textbook_images/sound_waves_23092.png

L_1033

sources of visible light

T_4880

FIGURE 1.1

image

textbook_images/sources_of_visible_light_23094.png

L_1033

sources of visible light

T_4882

FIGURE 1.2

image

textbook_images/sources_of_visible_light_23095.png

L_1033

sources of visible light

T_4882

FIGURE 1.3

image

textbook_images/sources_of_visible_light_23096.png

L_1035

speed

T_4887

FIGURE 1.1

image

textbook_images/speed_23098.png

L_1038

static electricity and static discharge

T_4897

FIGURE 1.1

image

textbook_images/static_electricity_and_static_discharge_23101.png

L_1040

surface wave

T_4901

FIGURE 1.1

image

textbook_images/surface_wave_23103.png

L_1041

synthesis reactions

T_4904

FIGURE 1.1

image

textbook_images/synthesis_reactions_23105.png

L_1045

technology and society

T_4914

FIGURE 1.1 This is a museum model similar to the steam engine invented by James Watt.

image

textbook_images/technology_and_society_23110.png

L_1048

thermal conductors and insulators

T_4920

FIGURE 1.1

image

textbook_images/thermal_conductors_and_insulators_23114.png

L_1048

thermal conductors and insulators

T_4921

FIGURE 1.2

image

textbook_images/thermal_conductors_and_insulators_23115.png

L_1048

thermal conductors and insulators

T_4921

FIGURE 1.3

image

textbook_images/thermal_conductors_and_insulators_23116.png

L_1049

thermal energy

T_4923

FIGURE 1.1

image

textbook_images/thermal_energy_23117.png

L_1050

thermal radiation

T_4925

FIGURE 1.1

image

textbook_images/thermal_radiation_23118.png

L_1051

thomsons atomic model

T_4927

FIGURE 1.1

image

textbook_images/thomsons_atomic_model_23120.png

L_1051

thomsons atomic model

T_4927

FIGURE 1.2

image

textbook_images/thomsons_atomic_model_23121.png

L_1051

thomsons atomic model

T_4928

FIGURE 1.3

image

textbook_images/thomsons_atomic_model_23122.png

L_1052

transfer of electric charge

T_4929

FIGURE 1.1

image

textbook_images/transfer_of_electric_charge_23124.png

L_1052

transfer of electric charge

T_4932

FIGURE 1.2

image

textbook_images/transfer_of_electric_charge_23125.png

L_1052

transfer of electric charge

T_4933

FIGURE 1.3 A: Electrons are transferred from the wall to the balloon, making the balloon negatively charged and the wall positively charged. The balloon sticks to the wall because opposite charges attract.

image

textbook_images/transfer_of_electric_charge_23126.png

L_1053

transition metals

T_4935

FIGURE 1.1

image

textbook_images/transition_metals_23127.png

L_1053

transition metals

T_4935

FIGURE 1.2 Other properties of the transition metals are unique. They are the only elements that may use electrons in the next to highestas well as the highestenergy level as valence electrons. Valence electrons are the electrons that form bonds with other elements in compounds and that generally determine the properties of elements. Transition metals are unusual in having very similar properties even with different numbers of valence electrons. The transition metals also include the only elements that produce a magnetic field. Three of them have this property: iron (Fe), cobalt (Co), and nickel (Ni).

image

textbook_images/transition_metals_23128.png

L_1054

transverse wave

T_4937

FIGURE 1.1

image

textbook_images/transverse_wave_23129.png