test_pid stringlengths 6 8 | query stringlengths 208 739 | question stringlengths 39 453 | options sequencelengths 0 7 | image_1 imagewidth (px) 78 7.44k | image_2 imagewidth (px) 112 6.85k ⌀ | image_3 imagewidth (px) 156 554 ⌀ | image_4 imagewidth (px) 144 582 ⌀ | image_5 imagewidth (px) 153 506 ⌀ | solution stringclasses 1
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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
test_1 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_82 | ||||||||
test_2 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_15 | ||||||||
test_3 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_4 | ||||||||
test_4 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_95 | ||||||||
test_5 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_36 | ||||||||
test_6 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_32 | ||||||||
test_7 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_29 | ||||||||
test_8 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_18 | ||||||||
test_9 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_14 | ||||||||
test_10 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_87 | ||||||||
test_11 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_70 | ||||||||
test_12 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_12 | ||||||||
test_13 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_76 | ||||||||
test_14 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_55 | ||||||||
test_15 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_5 | ||||||||
test_16 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_28 | ||||||||
test_17 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_30 | ||||||||
test_18 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_65 | ||||||||
test_19 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_78 | ||||||||
test_20 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_72 | ||||||||
test_21 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: /C=C(\O)Nc1ccccc1C(=O)C
B: /C=C(\[O-])Nc1ccccc1C(=O)C
C: */C=C(\[O-])Nc1ccccc1C(=O)C*
D: c1ccccc1C(=O)N=C[O-]
Answer with the option's letter from the given choices and put the letter in one "\b... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"/C=C(\\O)Nc1ccccc1C(=O)C",
"/C=C(\\[O-])Nc1ccccc1C(=O)C",
"*/C=C(\\[O-])Nc1ccccc1C(=O)C*",
"c1ccccc1C(=O)N=C[O-]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_690 | ||||
test_22 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: *C(=O)NCC(O)c1ccccc1.O=P(=O)OP(=O)=O
B: C(=O)NCC(O)c1ccccc1.O=P(=O)OP(O)=O
C: C(=O)NCC(O)c1ccccc1.O=P(O)(O)P(=O)O
D: C1=CC=C(C=C1)C(C(=O)N)O[P](=O)(O)[O]P(=O)(O)O
Answer with the option's letter... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"*C(=O)NCC(O)c1ccccc1.O=P(=O)OP(=O)=O",
"C(=O)NCC(O)c1ccccc1.O=P(=O)OP(O)=O",
"C(=O)NCC(O)c1ccccc1.O=P(O)(O)P(=O)O",
"C1=CC=C(C=C1)C(C(=O)N)O[P](=O)(O)[O]P(=O)(O)O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_955 | ||||
test_23 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CC(=O)O[P+](c1ccccc1)(c1ccccc1)c1ccccc1.CC(=O)[O-]
B: O=[C-]OC(=O)
C: C1=CC=C(C=C1)P(C2=CC=CC=C2)C3=CC=CC=C3
D: CC(=O)O[P+](c1ccccc1)(c1ccccc1)c1ccccc1.CC(=O)O
E: CC(=O)O[P+](c1ccccc1)(c1ccccc1)c... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CC(=O)O[P+](c1ccccc1)(c1ccccc1)c1ccccc1.CC(=O)[O-]",
"O=[C-]OC(=O)",
"C1=CC=C(C=C1)P(C2=CC=CC=C2)C3=CC=CC=C3",
"CC(=O)O[P+](c1ccccc1)(c1ccccc1)c1ccccc1.CC(=O)O",
"CC(=O)O[P+](c1ccccc1)(c1ccccc1)c1ccccc1.CC(=O)OC"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_921 | ||||
test_24 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C1=CC=C(C=C1)OC(=O)C(O)OC[O+]
B: C(=O)C(C(=O)Oc1ccccc1)O.[H+]
C: C(=O)OC(C(=O)Oc1ccccc1).[H+]
D: *C(=O)CC(=O)Oc1ccccc1.[H+]
Answer with the option's letter from the given choices and put the let... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C1=CC=C(C=C1)OC(=O)C(O)OC[O+]",
"C(=O)C(C(=O)Oc1ccccc1)O.[H+]",
"C(=O)OC(C(=O)Oc1ccccc1).[H+]",
"*C(=O)CC(=O)Oc1ccccc1.[H+]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_948 | ||||
test_25 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C[C@]12CCC(O)(N3CCC[C@H]3C(=O)[O-])C[C@@]1(O)CCC2=O
B: C[C@]12CCC(O)(N3CCCC[C@H]3C(=O)[O-])C[C@@]1(O)CCC2=O
C: C1CCN(C1)[C@@H]2C[C@H](C(=O)C3CCCCC3O2)C(=O)[O-]
D: C[C@]12CCC(O)(N3CCC[C@@H]3C(=O)[... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C[C@]12CCC(O)(N3CCC[C@H]3C(=O)[O-])C[C@@]1(O)CCC2=O",
"C[C@]12CCC(O)(N3CCCC[C@H]3C(=O)[O-])C[C@@]1(O)CCC2=O",
"C1CCN(C1)[C@@H]2C[C@H](C(=O)C3CCCCC3O2)C(=O)[O-]",
"C[C@]12CCC(O)(N3CCC[C@@H]3C(=O)[O-])C[C@@]1(O)CC2=O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_868 | ||||
test_26 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: OCN1CC2CC(C1)c1cc3nccnc3cc12
B: C1CC2=C3C(=CC=CN3C1)C(=NC2)C4CN(C5CC4C5)C6CO6
C: OCN1CC2CC(C1)c1ccc3nccnc3c12
D: OCN1CC2CC(C1)c1cc3ncccc3cc12
Answer with the option's letter from the given choic... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"OCN1CC2CC(C1)c1cc3nccnc3cc12",
"C1CC2=C3C(=CC=CN3C1)C(=NC2)C4CN(C5CC4C5)C6CO6",
"OCN1CC2CC(C1)c1ccc3nccnc3c12",
"OCN1CC2CC(C1)c1cc3ncccc3cc12"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_803 | ||||
test_27 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: *CC(N)O.N
B: CC(O)N.N
C: CC(N)O.O
D: based on the specific structure of the molecule shown
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please sol... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"*CC(N)O.N",
"CC(O)N.N",
"CC(N)O.O",
"based on the specific structure of the molecule shown"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_701 | ||||
test_28 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C([R])#O.[Cl-].[Al+3]([Cl-])([Cl-])([Cl-])
B: *C(=O)C1C=CC=[CH+]C1.Cl[Al-](Cl)(Cl)Cl
C: *C(=O)C1=CC=C[CH+]C1.Cl[Al-](Cl)ClCl
D: *C(=O)C1C=CC=C[CH+]1.Cl[Al-](Cl)(Cl)Cl
Answer with the option's le... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C([R])#O.[Cl-].[Al+3]([Cl-])([Cl-])([Cl-])",
"*C(=O)C1C=CC=[CH+]C1.Cl[Al-](Cl)(Cl)Cl",
"*C(=O)C1=CC=C[CH+]C1.Cl[Al-](Cl)ClCl",
"*C(=O)C1C=CC=C[CH+]1.Cl[Al-](Cl)(Cl)Cl"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_818 | ||||
test_29 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CC(=O)OC(C)(O)Oc1ccccc1C(=O)C
B: CC(=O)OC(O)(C)Oc1cccc(C)c1C(=O)C
C: *CC(=O)OC(O)(C*)Oc1ccccc1C(C)=O
D: O=C1OC(CO1)C(=O)OC
Answer with the option's letter from the given choices and put the lett... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CC(=O)OC(C)(O)Oc1ccccc1C(=O)C",
"CC(=O)OC(O)(C)Oc1cccc(C)c1C(=O)C",
"*CC(=O)OC(O)(C*)Oc1ccccc1C(C)=O",
"O=C1OC(CO1)C(=O)OC"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_890 | ||||
test_30 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C(=O)C(C)=[OH+].Nc1ccccc1
B: *C(=O)CC(*)=[OH+].Nc1ccccc1
C: c1ccccc1N=C([R1])[O+H]C(=O)[R2]
D: C(=O)CC()=[O+].Nc1ccccc1
Answer with the option's letter from the given choices and put the letter ... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C(=O)C(C)=[OH+].Nc1ccccc1",
"*C(=O)CC(*)=[OH+].Nc1ccccc1",
"c1ccccc1N=C([R1])[O+H]C(=O)[R2]",
"C(=O)CC()=[O+].Nc1ccccc1"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_731 | ||||
test_31 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: *C(=O)NC(*)C(*)=O
B: C1[NH]OC1
C: *C(=O)NC(*)C(=O)O*
D: *C(=O)OC(*)C(*)=O
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem st... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"*C(=O)NC(*)C(*)=O",
"C1[NH]OC1",
"*C(=O)NC(*)C(=O)O*",
"*C(=O)OC(*)C(*)=O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_1003 | ||||
test_32 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1.[O]Cl
B: CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1O.[O]Cl
C: CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1O.[O-]Cl
D: CC1(C)CCN(C1(C)C)[O]
Answer with the option's l... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1.[O]Cl",
"CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1O.[O]Cl",
"CC1(C)CCCC(C)(C)N1O.CC1(C)CCCC(C)(C)N1O.[O-]Cl",
"CC1(C)CCN(C1(C)C)[O]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_1034 | ||||
test_33 |
The structure of D-(+)-glucose is <image_1>. The structure of L-(-)-glucose is <image_2>. <image_1> <image_2>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | The structure of D-(+)-glucose is <image_1>. The structure of L-(-)-glucose is <image_2>. <image_1> <image_2> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | EXAMS-V | Multiple choice | chem_115 | |||||
test_34 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CS(=O)(=O)[N-][N+]#N.O=C1CCCC/C1=C\O
B: C1CCCCC1C(=O)N=[N+][O-]S(=O)(=O)C
C: CS(=O)(=O)[N-][N+]=N.O=C1CCCC1=CO
D: CS(=O)(=O)N=[N+]=[N-].OC1=CCCC\C1=O
Answer with the option's letter from the giv... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CS(=O)(=O)[N-][N+]#N.O=C1CCCC/C1=C\\O",
"C1CCCCC1C(=O)N=[N+][O-]S(=O)(=O)C",
"CS(=O)(=O)[N-][N+]=N.O=C1CCCC1=CO",
"CS(=O)(=O)N=[N+]=[N-].OC1=CCCC\\C1=O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_977 | ||||
test_35 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CN.O=CCCC=O
B: CN.C=OCCC=O
C: N1CCC(C=O)C1N
D: CN.O=C(C)CC=O
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CN.O=CCCC=O",
"CN.C=OCCC=O",
"N1CCC(C=O)C1N",
"CN.O=C(C)CC=O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_1001 | ||||
test_36 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C1=CC=C2C(=C1)C(C=C(C2)OS(=O)(=O)O)N=NC1=CC=CC=C1
B: NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)O)C1.[H+]
C: NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)O)C1
D: NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)OH)C1.[H+]
Answer with t... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C1=CC=C2C(=C1)C(C=C(C2)OS(=O)(=O)O)N=NC1=CC=CC=C1",
"NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)O)C1.[H+]",
"NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)O)C1",
"NNc1ccccc1.O=C1Cc2ccccc2C(OS(=O)OH)C1.[H+]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_670 | ||||
test_37 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: *[C@@H]1O[C@@H]1C[O-]
B: `[C@H]1O[C@@H]1CO`
C: `C1OC1C[O-]`
D: C1COC(O1)CO
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem s... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"*[C@@H]1O[C@@H]1C[O-]",
"`[C@H]1O[C@@H]1CO`",
"`C1OC1C[O-]`",
"C1COC(O1)CO"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_946 | ||||
test_38 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: `O=C1CCCCC(C1)Cl.[O-]`
B: *[O-].O=C1CCCCCC1Cl
C: `[O-]C1=CCCCCC1Cl`
D: C1CCCC(C(=O)[C-]1)Cl
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please so... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"`O=C1CCCCC(C1)Cl.[O-]`",
"*[O-].O=C1CCCCCC1Cl",
"`[O-]C1=CCCCCC1Cl`",
"C1CCCC(C(=O)[C-]1)Cl"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_805 | ||||
test_39 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CC(C)=O.CC(C)O=O
B: CC(C)=O.CC(C)O[O]
C: CC(C)=O.CC(C)=[O+][O-]
D: CC(=O)OC
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem ... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CC(C)=O.CC(C)O=O",
"CC(C)=O.CC(C)O[O]",
"CC(C)=O.CC(C)=[O+][O-]",
"CC(=O)OC"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_763 | ||||
test_40 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CCB().[O-]O[O-]
B: *CCB(*)*.[O-]O
C: [R][CH][B](R)(R)O[O-]
D: CCB().[O-]O[H]
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CCB().[O-]O[O-]",
"*CCB(*)*.[O-]O",
"[R][CH][B](R)(R)O[O-]",
"CCB().[O-]O[H]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_668 | ||||
test_41 |
One mole of a monoatomic real gas satisfies the equation $p(V-b)=RT$ where $b$ is a constant. The relationship of interatomic potential $V(r)$ and interatomic distance $r$ for the gas is given by <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}".... | One mole of a monoatomic real gas satisfies the equation $p(V-b)=RT$ where $b$ is a constant. The relationship of interatomic potential $V(r)$ and interatomic distance $r$ for the gas is given by <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | EXAMS-V | Multiple choice | chem_133 | ||||
test_42 |
<image_1> Which points correspond to a melting/freezing equilibrium?
A: 1 and 5
B: 1 and 3
C: 2 and 4
D: 6 and 7
E: 7 and 8
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | <image_1> Which points correspond to a melting/freezing equilibrium? | [
"1 and 5",
"1 and 3",
"2 and 4",
"6 and 7",
"7 and 8"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | MMMU | Multiple choice | chem_1159 | ||||
test_43 |
P is the probability of finding the 1s electron of hydrogen atom in a spherical shell of infinitesimal thickness, dr, at a distance r from the nucleus. The volume of this shell is 4$\pi r^2$dr. The qualitative sketch of the dependence of P on r is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the... | P is the probability of finding the 1s electron of hydrogen atom in a spherical shell of infinitesimal thickness, dr, at a distance r from the nucleus. The volume of this shell is 4$\pi r^2$dr. The qualitative sketch of the dependence of P on r is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | EXAMS-V | Multiple choice | chem_108 | ||||
test_44 |
<image_1> Figure 29-1: Titration curve. Which of the following matches the titration curve shown in Figure 29-1?
A: A strong acid is titrated into a weak base.
B: A strong acid is titrated into a strong base.
C: A strong base is titrated into a weak acid.
D: A strong base is titrated into a strong acid.
E: A weak base... | <image_1> Figure 29-1: Titration curve. Which of the following matches the titration curve shown in Figure 29-1? | [
"A strong acid is titrated into a weak base.",
"A strong acid is titrated into a strong base.",
"A strong base is titrated into a weak acid.",
"A strong base is titrated into a strong acid.",
"A weak base is titrated into a weak acid."
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | MMMU | Multiple choice | chem_1162 | ||||
test_45 |
<image_1> Which point corresponds to the critical point?
A: 1
B: 2
C: 5
D: 7
E: 9
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | <image_1> Which point corresponds to the critical point? | [
"1",
"2",
"5",
"7",
"9"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | MMMU | Multiple choice | chem_1174 | ||||
test_46 |
The \%yield of ammonia as a function of time in the reaction N_2(g) + 3H_2(g) \rightleftharpoons 2NH_3(g), \Delta H < 0 at (P, T_1) is given below. If this reaction is conducted at (P, T_2), with T_2 > T_1, the \%yield of ammonia as a function of time is represented by <image_1> <image_2>
A: A
B: B
C: C
D: D
Answer w... | The \%yield of ammonia as a function of time in the reaction N_2(g) + 3H_2(g) \rightleftharpoons 2NH_3(g), \Delta H < 0 at (P, T_1) is given below. If this reaction is conducted at (P, T_2), with T_2 > T_1, the \%yield of ammonia as a function of time is represented by <image_1> <image_2> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | EXAMS-V | Multiple choice | chem_119 | |||||
test_47 |
The qualitative sketches I, II and III given below show the variation of surface tension with molar concentration of three different aqueous solutions of KCl, CH$_3$OH and CH$_3$(CH$_2$)$_{11}$OSO$_3^-$Na$^+$ at room temperature. The correct assignment of the sketches is <image_1>
A: I: KCl $\quad$ II: CH$_3$OH $\quad... | The qualitative sketches I, II and III given below show the variation of surface tension with molar concentration of three different aqueous solutions of KCl, CH$_3$OH and CH$_3$(CH$_2$)$_{11}$OSO$_3^-$Na$^+$ at room temperature. The correct assignment of the sketches is <image_1> | [
"I: KCl $\\quad$ II: CH$_3$OH $\\quad$ III: CH$_3$(CH$_2$)$_{11}$OSO$_3^-$Na$^+$",
"I: CH$_3$(CH$_2$)$_{11}$OSO$_3^-$Na$^+$ $\\quad$ II: CH$_3$OH $\\quad$ III: KCl",
"I: KCl $\\quad$ II: CH$_3$(CH$_2$)$_{11}$OSO$_3^-$Na$^+$ $\\quad$ III: CH$_3$OH",
"I: CH$_3$OH $\\quad$ II: KCl $\\quad$ III: CH$_3$(CH$_2$)$_{... | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | EXAMS-V | Multiple choice | chem_126 | ||||
test_48 |
AgNO_3 (aq.) was added to an aqueous KCl solution gradually and the conductivity of the solution was measured. The plot of conductance ($\Lambda$) versus the volume of AgNO_3 is <image_1>
A: (P)
B: (Q)
C: (R)
D: (S)
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please so... | AgNO_3 (aq.) was added to an aqueous KCl solution gradually and the conductivity of the solution was measured. The plot of conductance ($\Lambda$) versus the volume of AgNO_3 is <image_1> | [
"(P)",
"(Q)",
"(R)",
"(S)"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Graph Reasoning | EXAMS-V | Multiple choice | chem_140 | ||||
test_49 |
KI in acetone, undergoes S_N2 reaction with each of P, Q, R and S. The rates of the reaction vary as <image_1>
A: P > Q > R > S
B: S > P > R > Q
C: P > R > Q > S
D: R > P > S > Q
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | KI in acetone, undergoes S_N2 reaction with each of P, Q, R and S. The rates of the reaction vary as <image_1> | [
"P > Q > R > S",
"S > P > R > Q",
"P > R > Q > S",
"R > P > S > Q"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_130 | ||||
test_50 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: O=N=NO
B: O=NON=O
C: O=N-N=O
D: ON=N=O
Answer with the option'... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"O=N=NO",
"O=NON=O",
"O=N-N=O",
"ON=N=O"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1143 | ||||
test_51 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: [O-]c1cc(C(CC(c2ccccc2)=O)=O)ccc1
B: [O-]c1c(C(CC(c2ccccc2)=O)=... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"[O-]c1cc(C(CC(c2ccccc2)=O)=O)ccc1",
"[O-]c1c(C(CC(c2ccccc2)=O)=O)ccnc1",
"[O-]c1c(C(CC(c2ccccc2)=O)C(=O))cccc1",
"[O-]c1c(C(CC(c2ccccc2)=O)=O)cccc1"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1057 | ||||
test_52 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: [*]C#[C-]
B: [*]C#C
C: [*]C#[CH]
D: [*]C=C
Answer with the opt... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"[*]C#[C-]",
"[*]C#C",
"[*]C#[CH]",
"[*]C=C"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1122 | ||||
test_53 |
In the following reactions, the product S is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | In the following reactions, the product S is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_142 | ||||
test_54 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: ClCCl
B: Cl[C-]Cl
C: [Cl][C][Cl]
D: Cl[C]Cl
Answer with the op... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"ClCCl",
"Cl[C-]Cl",
"[Cl][C][Cl]",
"Cl[C]Cl"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1101 | ||||
test_55 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: C=CCC/C=C(O[Si]([*])([*])[*])[*]
B: C=CCC/C=C(O[Si]([*])([*])[*... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"C=CCC/C=C(O[Si]([*])([*])[*])[*]",
"C=CCC/C=C(O[Si]([*])([*])[*])\\[*]",
"C=CCC/C=C(O[Si]([*])([*])[*])/[*]",
"C=CCC/C=C(O[Si]([*])[*][*])\\[*]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1118 | ||||
test_56 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: [C@H]1(C2)CCC2C3[C@@]1(N4CCCC4)[C@H]5N=C[C@@H]3N=N5
B: [C@H]1(C... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"[C@H]1(C2)CCC2C3[C@@]1(N4CCCC4)[C@H]5N=C[C@@H]3N=N5",
"[C@H]1(C2)CCC2C3[C@]1(N4CCCC4)[C@H]5N=C[C@@H]3N=N5",
"[C@@H]1(C2)CCC2C3[C@@]1(N4CCCC4)[C@H]5N=C[C@@H]3N=N5",
"[C@H]1(C2)CCC2C3[C@@]1(N4CCCC4)[C@H]5N=C[C@H]3N=N5"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1075 | ||||
test_57 |
The compounds P, Q and S were separately subjected to nitration using HNO_3/H_2SO_4 mixture. The major product formed in each case respectively, is <image_1> <image_2>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step... | The compounds P, Q and S were separately subjected to nitration using HNO_3/H_2SO_4 mixture. The major product formed in each case respectively, is <image_1> <image_2> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_138 | |||||
test_58 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: [*]C1=CC=CC=C2C2=CC3=CC=CC=C31
B: [*]C1=CC2=CC=CC=C3C3=CC=CC12
... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"[*]C1=CC=CC=C2C2=CC3=CC=CC=C31",
"[*]C1=CC2=CC=CC=C3C3=CC=CC12",
"[*]C1=CC=CC2=CC3=CC=CC=C3C12",
"[*]C1=C(C=CC=C2)C2=CC3=CC=CC=C31"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1084 | ||||
test_59 |
In the following reaction, <image_1> the structure of the major product 'X' is <image_2>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | In the following reaction, <image_1> the structure of the major product 'X' is <image_2> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_147 | |||||
test_60 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: O=C(CC1)[N-]C1=O.C[S+](Br)C
B: O=C(CC1)[N-]C1=O.C[S+](Cl)C
C: O... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"O=C(CC1)[N-]C1=O.C[S+](Br)C",
"O=C(CC1)[N-]C1=O.C[S+](Cl)C",
"O=C(CC1)[N]C1=O.C[S+](Cl)C",
"O=C(CC1)[N-]C1=O.C[S](Cl)C"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1123 | ||||
test_61 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: */C=C/NC(C*)C(*)C(C)=O.[NH4+]
B: */C=C/NC(C*)C(C*)C(C)=O.[NH4+]... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"*/C=C/NC(C*)C(*)C(C)=O.[NH4+]",
"*/C=C/NC(C*)C(C*)C(C)=O.[NH4+]",
"*/C=C/NC(C*)C(*)C(C)=O.NH4+",
"\\*/C=C\\NC(C*)C(*)C(C)=O.[NH4+]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1097 | ||||
test_62 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: [*][B@-]1(/[O+]=C(c2ccccc2)\C)OC(c3ccccc3)(c4ccccc4)[C@@H]5CCC[... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"[*][B@-]1(/[O+]=C(c2ccccc2)\\C)OC(c3ccccc3)(c4ccccc4)[C@@H]5CCC[N@@+]51[BH2-][H]",
"[*][B@-]1(/[O+]=C(c2ccccc2)\\C)OC(c3ccccc3)(c4ccccc4)[C@H]5CCC[N@+]51[BH2-][H]",
"[*][B@]1(/[O+]=C(c2ccccc2)\\C)OC(c3ccccc3)(c4ccccc4)[C@@H]5CCC[N@@+]51[BH2-][H]",
"[*][B@-]1(/[O+]=C(c2ccccc2)\\C)OC(c3ccccc3)(c4ccccc4)[C@@H]5... | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1119 | ||||
test_63 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: O=C(C(c1ccccc1)O)c2ccccc2.[C-]#N
B: O=C(C(c1ccccc1)O)c2ccccc2C#... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"O=C(C(c1ccccc1)O)c2ccccc2.[C-]#N",
"O=C(C(c1ccccc1)O)c2ccccc2C#N",
"O=C(C(c1ccccc1)O)c2ccccc2.[C#N]",
"O=C(C(c1ccccc1)O)c2ccccc2C(=[C-])N"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1067 | ||||
test_64 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: ON1CCC[C@H]1COCC(C)=
B: C=C=C#N
C: ON1CCC[C@H]1COCC(C)=
D: C=CC... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"ON1CCC[C@H]1COCC(C)=",
"C=C=C#N",
"ON1CCC[C@H]1COCC(C)=",
"C=CC#N",
"ON1CCC[C@H]1COCC(C)=",
"C#CC=C",
"ON1CCC[C@H]1COCC(C)=O.C=CC#N"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1116 | ||||
test_65 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_254 | ||||
test_66 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_490 | ||||
test_67 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_283 | ||||
test_68 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_506 | ||||
test_69 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_496 | ||||
test_70 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_478 | ||||
test_71 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_183 | ||||
test_72 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_458 | ||||
test_73 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_472 | ||||
test_74 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_234 | ||||
test_75 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_420 | ||||
test_76 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_520 | ||||
test_77 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_272 | ||||
test_78 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_230 | ||||
test_79 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_383 | ||||
test_80 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_341 | ||||
test_81 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_285 | ||||
test_82 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_474 | ||||
test_83 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_499 | ||||
test_84 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_432 | ||||
test_85 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: CC#[N+]C(C)(C)C
B: CC#N(C)(C)C
C: CC#[N+]C(C)C(C)
D: C[C+](C)C#N
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by ste... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"CC#[N+]C(C)(C)C",
"CC#N(C)(C)C",
"CC#[N+]C(C)C(C)",
"C[C+](C)C#N"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_969 | ||||
test_86 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_160 | ||||
test_87 |
Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1>
A: C1=CC=C(C=C1)C2=CC(=C(C=C2)C(=O)O)N[N+](=O)[O-]
B: Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=N(=O)N=O
C: Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=NON=O
D: Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=NO[O]
Answer with the o... | Please choose the SMILES expression of the transition-state structure shown in the image, ignoring the arrows. <image_1> | [
"C1=CC=C(C=C1)C2=CC(=C(C=C2)C(=O)O)N[N+](=O)[O-]",
"Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=N(=O)N=O",
"Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=NON=O",
"Nc1ccccc1/C=C(/C(=O)O)c1ccccc1.O=NO[O]"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | new_annotated | Multiple choice | chem_990 | ||||
test_88 |
<image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arro... | <image_1> An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. The transition-state structure undergoes changes after the electron has been relocated or reacted. Which of the following options shows the structure after the change? Note: Disregard the arrow... | [
"<image_2>",
"<image_3>",
"<image_4>",
"<image_5>"
] | Chemistry | Reaction Simulation Pro | new_annotated | Multiple choice | chem_84 | ||||||||
test_89 |
An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1>
A: O=C(O)C1=CC(c2ccccc2)Nc3ccccc13
B: O=C(O)C1=C(C2=CC=CC=C2)Nc3cc... | An 'arrow-pushing' diagram is a common type of chemical image used to illustrate electron flow in mechanistic steps. Please choose the SMILES expression for the molecules(state) after the electron has been relocated, as depicted in the image. <image_1> | [
"O=C(O)C1=CC(c2ccccc2)Nc3ccccc13",
"O=C(O)C1=C(C2=CC=CC=C2)Nc3ccccc13",
"O=C(O)C1=CC(c2ccccc2)N=C3C=CC=CC13",
"O=C(O)C1=CC(c2ccccc2)Nc3ccccc31"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | new_annotated | Multiple choice | chem_1153 | ||||
test_90 |
<image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image.
Answer ... | <image_1> In the transition-state structure shown in the image, calculate the total number of bonds in the structure, including single, double, and triple bonds but excluding those involving hydrogen.
Note: Disregard arrows. Consider all components present in the transition-state structure shown in the image. | [] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Knowledge-based counting | new_annotated | Open-ended | chem_324 | ||||
test_91 |
In the following reactions, the major product W is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | In the following reactions, the major product W is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_128 | ||||
test_92 |
The correct statement about the following disaccharide is <image_1>
A: Ring (a) is pyranose with $\alpha$-glycosidic link
B: Ring (a) is furanose with $\alpha$-glycosidic link
C: Ring (b) is furanose with $\alpha$-glycosidic link
D: Ring (b) is pyranose with $\beta$-glycosidic link
Answer with the option's letter fro... | The correct statement about the following disaccharide is <image_1> | [
"Ring (a) is pyranose with $\\alpha$-glycosidic link",
"Ring (a) is furanose with $\\alpha$-glycosidic link",
"Ring (b) is furanose with $\\alpha$-glycosidic link",
"Ring (b) is pyranose with $\\beta$-glycosidic link"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | EXAMS-V | Multiple choice | chem_106 | ||||
test_93 |
The following carbohydrate is <image_1>
A: a ketohexose
B: an aldohexose
C: an $\alpha$-furanose
D: an $\alpha$-pyranose
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | The following carbohydrate is <image_1> | [
"a ketohexose",
"an aldohexose",
"an $\\alpha$-furanose",
"an $\\alpha$-pyranose"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | EXAMS-V | Multiple choice | chem_111 | ||||
test_94 |
Among the following, the least stable resonance structure is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | Among the following, the least stable resonance structure is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | EXAMS-V | Multiple choice | chem_125 | ||||
test_95 |
<image_1> The structural formula of the glycinium cation is shown above. Arrows indicate the $pK_a$ values for the labile protons in the molecule. Which of the following is true about the geometry of the glycinium cation?
A: The leftmost C atom and all the atoms directly bonded to it lie in the same plane.
B: Both C ... | <image_1> The structural formula of the glycinium cation is shown above. Arrows indicate the $pK_a$ values for the labile protons in the molecule. Which of the following is true about the geometry of the glycinium cation? | [
"The leftmost C atom and all the atoms directly bonded to it lie in the same plane. ",
"Both C atoms and both O atoms lie in the same plane. ",
"The N-C-C bond angle is 180°.",
"The geometry around the N atom is planar."
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Structure Recognition | MMMU | Multiple choice | chem_1168 | ||||
test_96 |
The major product H of the given reaction sequence is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | The major product H of the given reaction sequence is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_109 | ||||
test_97 |
In the following reaction sequence, the correct structures of E, F and G are <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | In the following reaction sequence, the correct structures of E, F and G are <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_112 | ||||
test_98 |
Cyclohexene on ozonolysis followed by reaction with zinc dust and water gives compound E. Compound E on further treatment with aqueous KOH yields compound F. Compound F is <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the proble... | Cyclohexene on ozonolysis followed by reaction with zinc dust and water gives compound E. Compound E on further treatment with aqueous KOH yields compound F. Compound F is <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_121 | ||||
test_99 |
Match each coordination compound in List-I with an appropriate pair of characteristics from List-II and select the correct answer using the code given below the lists. $\{en = H_2NCH_2CH_2NH_2; atomic numbers: Ti = 22; Cr = 24; Co = 27; Pt = 78\}$ <image_1>
A: A
B: B
C: C
D: D
Answer with the option's letter from the... | Match each coordination compound in List-I with an appropriate pair of characteristics from List-II and select the correct answer using the code given below the lists. $\{en = H_2NCH_2CH_2NH_2; atomic numbers: Ti = 22; Cr = 24; Co = 27; Pt = 78\}$ <image_1> | [
"A",
"B",
"C",
"D"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_127 | ||||
test_100 |
The major product(s) of the following reaction is(are) <image_1>
A: P
B: Q
C: R
D: S
Answer with the option's letter from the given choices and put the letter in one "\boxed{}". Please solve the problem step by step. | The major product(s) of the following reaction is(are) <image_1> | [
"P",
"Q",
"R",
"S"
] | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Not supported with pagination yet | Chemistry | Reaction Simulation | EXAMS-V | Multiple choice | chem_132 |
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