LF
L. Feng
3 records found
1
Ceramic nanofiltration membranes
Rejection of salts and NOM at high ionic strength and modification of pore size by atomic layer deposition
Master thesis
(2018)
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L.
Feng
(author),
L.C.
Rietveld
(mentor),
Sebastiaan
Heijman
(mentor),
I.
Caltran
(mentor),
R.
Shang
(mentor),
F.
Dirne
(mentor)
Natural Organic Matter (NOM) is always present in the drinking water sources such as rivers, lakes and reservoirs. It causes several problems, including the unfavourable colour and odour of water, formation of disinfectant by-products and harmful microbial growth. In drinking wat
...
Natural Organic Matter (NOM) is always present in the drinking water sources such as rivers, lakes and reservoirs. It causes several problems, including the unfavourable colour and odour of water, formation of disinfectant by-products and harmful microbial growth. In drinking water treatment, anion exchange (anion-IEX) is used for NOM removal. However, the regeneration of anion-IEX produces a brine, which is a high saline waste stream containing the desorbed NOM and anions (i.e. sulphate) as well as the residual sodium chloride added during the regeneration process.
One possible approach to manage the waste brine is to recover the valuable compounds from the brine, and consequently, reduce the brine volume that has to be disposed. The separation could be done by ceramic nanofiltration (NF) membranes. However, the separation performance of ceramic NF membranes at high salinity conditions is still not fully understood. Therefore, the use of ceramic NF membranes to treat the brine-like wastes that contain NOM and high salt concentrations were investigated.
Commercial 500 Dalton(Da) ceramic NF membranes were used in the salt experiments. Several experimental conditions such as pH and ionic strength were investigated to understand their influence on the rejection of sulphate (SO42-) and chloride (Cl-). The results show that the salt rejection was governed by charge effect, and it changed depending on pH and ionic strength. When ionic strength was 0.1M, the mitigated charge effect led to a low rejection of SO42- (<20%) and Cl- (<5%) by the 500Da membranes. On the other hand, the 560Da membrane used in salt&NOM experiments exhibited more than 95% rejection of NOM but less than 25% rejection of both SO42- and Cl- when ionic strength was 1M.
Since the 500Da membranes were unable to reject divalent ions at high ionic strength, it is suggested to decrease the membrane pore size to achieve the separation of SO42- and Cl-. The size of pores in ceramic membranes can be narrowed down by an approach called Atomic Layer Deposition (ALD) (Shang et al., 2017). In this study, the vacuum TiO2 ALD was applied to coat thin films on the commercial ceramic NF membranes that have Molecular weight cut-off (MWCO) ranging from 600Da to 900Da. After the first coating, the water permeability of the membranes decreased dramatically while the MWCO of the membranes decreased slightly. After the second coating, an increased MWCO was observed, which might be attributed to the plugging of small pores. In addition, the flux distribution and pore size distribution were theoretically analysed to investigate the change of the membrane pores before and after ALD.
Pressure driven membranes have become increasingly popular in removal of natural organic matter (NOM). With the purpose to tailor pore size of membrane to remove NOM effectively, atomic layer deposition (ALD) was applied on the ceramic nanofiltration (NF) membrane with a pore siz
...
Pressure driven membranes have become increasingly popular in removal of natural organic matter (NOM). With the purpose to tailor pore size of membrane to remove NOM effectively, atomic layer deposition (ALD) was applied on the ceramic nanofiltration (NF) membrane with a pore size of 1.3 nm. Ceramic membranes were chosen as the substrate membrane due to their high physical strength and high chemical resistance. TiO2 was deposited on the membrane by using TiCl4 and H2O as precursors. After deposition with 3 cycles, MWCO of the ceramic membranes was reduced by ~ 250 Da. The pore size of the ceramic membranes was correspondingly narrowed down by ~ 0.16 nm. The growth per cycle of TiO2 on the pore walls was ~ 0.272 nm/cycle. An improved Carman-Kozeny model was used to estimate water permeability. With the help of two scenarios, the model results are close to the results from water permeability experiments that the water permeability decreased from ~ 24 퐿 h%& m%( bar%& to ~ 6 퐿 h%& m%( bar%&. The application of the fabricated membrane in water treatment could be investigated in the further study.
Journal article
(2010)
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B.C.
Arnold
(author),
B.C.
Arnold
(author),
G
Chen
(author),
G
Chen
(author),
D.
Kong
(author),
D.
Kong
(author),
H.
Park
(author),
H.
Park
(author),
D.
Son
(author),
D.
Son
(author),
S.
SONG
(author),
S.
SONG
(author),
S.
Jung
(author),
S.
Jung
(author),
B.C.
Hong
(author),
B.C.
Hong
(author),
H.
Kim
(author),
H.
Kim
(author),
J.H.
Kim
(author),
J.H.
Kim
(author),
K.S.
Lee
(author),
K.S.
Lee
(author),
S.
Park
(author),
S.
Park
(author),
H
Chen
(author),
H
Chen
(author),
J.
Kim
(author),
J.
Kim
(author),
M.
Choi
(author),
M.
Choi
(author),
G.
Hahn
(author),
G.
Hahn
(author),
S.
Choi
(author),
S.
Choi
(author),
YH
Choi
(author),
YH
Choi
(author),
J.L.
Goh
(author),
J.L.
Goh
(author),
H.
Jeong
(author),
H.
Jeong
(author),
T.
Kim
(author),
T.
Kim
(author),
J
Lee
(author),
J
Lee
(author),
S
Lee
(author),
S
Lee
(author),
C.
Jiang
(author),
C.
Jiang
(author),
P.I.
Petrov
(author),
P.I.
Petrov
(author),
J.
Williams
(author),
J.
Williams
(author),
M.
Ahmad
(author),
M.
Ahmad
(author),
M.
Ahmad
(author),
I.
Ahmed
(author),
I.
Ahmed
(author),
I.
Ahmed
(author),
M.S.
Asghar
(author),
M.S.
Asghar
(author),
M.S.
Asghar
(author),
M.A.A.
Awan
(author),
M.A.A.
Awan
(author),
M.A.A.
Awan
(author),
I.
Hussain
(author),
I.
Hussain
(author),
I.
Hussain
(author),
M.W.
Khan
(author),
M.W.
Khan
(author),
M.W.
Khan
(author),
S.
Muhammad
(author),
S.
Muhammad
(author),
S.
Muhammad
(author),
H.
Shahzad
(author),
H.
Shahzad
(author),
H.
Shahzad
(author),
D.
Liang
(author),
D.
Liang
(author),
P.M.
Zalewski
(author),
P.M.
Zalewski
(author),
A.E.
David
(author),
A.E.
David
(author),
P
Ribeiro
(author),
P
Ribeiro
(author),
PGR
Silva
(author),
PGR
Silva
(author),
M.
Finger
(author),
M.
Finger
(author),
M.
Finger
(author),
M.
Finger
(author),
A.
Denisov
(author),
A.
Denisov
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V.
Kim
(author),
V.
Kim
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A.
Anisimov
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A.
Anisimov
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A.J.
Levine
(author),
A.J.
Levine
(author),
B.
Liu
(author),
B.
Liu
(author),
V.
Petrov
(author),
V.
Petrov
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M.
Daniël
(author),
M.
Daniël
(author),
J.I.
Hernández
(author),
J.I.
Hernández
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B.
Gómez
(author),
B.
Gómez
(author),
J.
Bos
(author),
J.
Bos
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D.
Campi
(author),
D.
Campi
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M.
Hansen
(author),
M.
Hansen
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J.
Harvey
(author),
J.
Harvey
(author),
H.
Hoffmann
(author),
H.
Hoffmann
(author),
R.J.
Loos
(author),
R.J.
Loos
(author),
X
Meng
(author),
X
Meng
(author),
F.E.
Meijers
(author),
F.E.
Meijers
(author),
M.
Mulders
(author),
M.
Mulders
(author),
L.
Orsini
(author),
L.
Orsini
(author),
E
Perez
(author),
E
Perez
(author),
A.
Sharma
(author),
A.
Sharma
(author),
S.
König
(author),
S.
König
(author),
F.A.
Meier
(author),
F.A.
Meier
(author),
Z.
Chen
(author),
Z.
Chen
(author),
A.J.H.
Herve
(author),
A.J.H.
Herve
(author),
A.
Sanchez
(author),
A.
Sanchez
(author),
J.
Tao
(author),
J.
Tao
(author),
M.
Weber
(author),
M.
Weber
(author),
A.
Schmidt
(author),
A.
Schmidt
(author),
Y.
Chang
(author),
Y.
Chang
(author),
E.
Chen
(author),
E.
Chen
(author),
W.
Chen
(author),
W.
Chen
(author),
A.C.S.
Go
(author),
A.C.S.
Go
(author),
C.
Kuo
(author),
C.
Kuo
(author),
S
Li
(author),
S
Li
(author),
W
Lin
(author),
W
Lin
(author),
P.L.T.
Chang
(author),
P.L.T.
Chang
(author),
J
Wang
(author),
J
Wang
(author),
Y.
Chao
(author),
Y.
Chao
(author),
K.
Chen
(author),
K.
Chen
(author),
Y.
Lei
(author),
Y.
Lei
(author),
S.
Lin
(author),
S.
Lin
(author),
R.
Lu
(author),
R.
Lu
(author),
J
Schumann
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J
Schumann
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C.C.
Wang
(author),
C.C.
Wang
(author),
M.
Wang
(author),
M.
Wang
(author),
M.
Kaya
(author),
M.
Kaya
(author),
M.
Kaya
(author),
M.
Kaya
(author),
M.O.
Kaya
(author),
M.O.
Kaya
(author),
M.O.
Kaya
(author),
M.O.
Kaya
(author),
Z
Wang
(author),
Z
Wang
(author),
N.O.
Sonmez
(author),
N.O.
Sonmez
(author),
N.O.
Sonmez
(author),
N.O.
Sonmez
(author),
T.O.C.
Cheng
(author),
T.O.C.
Cheng
(author),
M.
Hansen
(author),
M.
Hansen
(author),
RR
Brown
(author),
RR
Brown
(author),
J.
Williams
(author),
J.
Williams
(author),
J.P.
Hays
(author),
J.P.
Hays
(author),
A.
Papageorgiou
(author),
A.
Papageorgiou
(author),
A.V.
Rose
(author),
A.V.
Rose
(author),
A.
Khan
(author),
A.
Khan
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R.E.
Taylor
(author),
R.E.
Taylor
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Z.
Xue
(author),
Z.
Xue
(author),
J.
Rohlf
(author),
J.
Rohlf
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S
Wu
(author),
S
Wu
(author),
S.
Bhattacharya
(author),
S.
Bhattacharya
(author),
D.C.C.
Nguyen
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D.C.C.
Nguyen
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P.
Cox
(author),
P.
Cox
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H
Liu
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H
Liu
(author),
M.
Nikolic
(author),
M.
Nikolic
(author),
J.N.V.
Smith
(author),
J.N.V.
Smith
(author),
M.
Tripathi
(author),
M.
Tripathi
(author),
J.H.C.
Hauser
(author),
J.H.C.
Hauser
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S.
Schmid
(author),
S.
Schmid
(author),
Z.
Zhang
(author),
Z.
Zhang
(author),
X.
Yang
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X.
Yang
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A.
Chandra
(author),
A.
Chandra
(author),
F.
LIU
(author),
F.
LIU
(author),
H
Liu
(author),
H
Liu
(author),
A.
Luthra
(author),
A.
Luthra
(author),
H.
Nguyen
(author),
H.
Nguyen
(author),
B.
Shen
(author),
B.
Shen
(author),
V.
Sharma
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V.
Sharma
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S.C.
Simon
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S.C.
Simon
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Y.
Ma
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Y.
Ma
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J.
Cai
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J.
Cai
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Y.
Yang
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Y.
Yang
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L
Zhang
(author),
L
Zhang
(author),
K.
Zhu
(author),
K.
Zhu
(author),
R.
Zhu
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R.
Zhu
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B.
Akgün
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B.
Akgün
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S.
Wagner
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S.
Wagner
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A.
Chatterjee
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A.
Chatterjee
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A.
Chatterjee
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S.
Das
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S.
Das
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B.A.
Kreis
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B.A.
Kreis
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VB
Kuznetsov
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VB
Kuznetsov
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Y.
GE
(author),
Y.
GE
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X.
Shi
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X.
Shi
(author),
W.
Sun
(author),
W.
Sun
(author),
W.Y.
Teo
(author),
W.Y.
Teo
(author),
Y.
Weng
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Y.
Weng
(author),
S.
Banerjee
(author),
S.
Banerjee
(author),
P.
Bhat
(author),
P.
Bhat
(author),
J.G.
Butler
(author),
J.G.
Butler
(author),
H.Y.
Cheung
(author),
H.Y.
Cheung
(author),
D.M.J.
Dykstra
(author),
D.M.J.
Dykstra
(author),
L.
Feng
(author),
L.
Feng
(author),
S.
GUO
(author),
S.
GUO
(author),
Y.
Guo
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Y.
Guo
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M.K.P.
Johnson
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M.K.P.
Johnson
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C.
Jones
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C.
Jones
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J.
Kaiser
(author),
J.
Kaiser
(author),
C.O.S.
Lei
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C.O.S.
Lei
(author),
S.A.
Los
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S.A.
Los
(author),
K.A.
Mishra
(author),
K.A.
Mishra
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R.V.
Rivera
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R.V.
Rivera
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S.
Ryu
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S.
Ryu
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S.
Sharma
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S.
Sharma
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Z.
Hu
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Z.
Hu
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R.
Smith
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R.
Smith
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R.A.
Vidal
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R.A.
Vidal
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W.
Wu
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W.
Wu
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J.
Yun
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J.
Yun
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M
Chen
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M
Chen
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Y.
Fu
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Y.
Fu
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J.
Gartner
(author),
J.
Gartner
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B.
Kim
(author),
B.
Kim
(author),
D.
Wang
(author),
D.
Wang
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L.
Kramer
(author),
L.
Kramer
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Y.
Mao
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Y.
Mao
(author),
J.L.
Rodriguez
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J.L.
Rodriguez
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M
Bertoldi
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M
Bertoldi
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J
Chen
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J
Chen
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J.
Haas
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J.
Haas
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K.
Johnson
(author),
K.
Johnson
(author),
M.G.A.
Adams
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M.G.A.
Adams
(author),
MC
Castro
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MC
Castro
(author),
D.
Hofman
(author),
D.
Hofman
(author),
E.
Albayrak
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E.
Albayrak
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RO
Briggs
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RO
Briggs
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S
Qian
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S
Qian
(author),
L.F.K.
Chung
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L.F.K.
Chung
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I
Schmidt
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I
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S.
Sen
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S.
Sen
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J.
Wetzel
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J.
Wetzel
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K.W.A.
Yi
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K.W.A.
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Z.
Guo
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Z.
Guo
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N.Q.
Tran
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N.Q.
Tran
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Y
Zhang
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Y
Zhang
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S.J.
Sanders
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S.J.
Sanders
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T.K.
Bolton
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T.K.
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H.H.
Teng
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H.H.
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A.
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A.
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Z.
Wan
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Z.
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D.J.
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D.J.
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G.
Bauer
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G.
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M.
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M.
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Y.
Kim
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Y.
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Y.
Lee
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Y.
Lee
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W
Li
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W
Li
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T.
Ma
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T.
Ma
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M.
Rudolph
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M.
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B.
Zhu
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B.
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S.
Xie
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S.
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A.
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A.
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J.H.A.
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J.H.A.
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J
Zhang
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J
Zhang
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D.
Sanders
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D.
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D.
Claes
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D.
Claes
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J.
Keller
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J.
Keller
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S.
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S.
Malik
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A
Kumar
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A
Kumar
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K.L.
Smith
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K.L.
Smith
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A.M.
Gomez
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A.M.
Gomez
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L.I.P.
Taylor
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L.I.P.
Taylor
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S.
Won
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S.
Won
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D.K.
Berry
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D.K.
Berry
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J.
Gu
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J.
Gu
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G.F.
Williams
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G.F.
Williams
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N.J.
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N.J.
Adam
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A.
Hunt
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A.
Hunt
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J.C.
Jones
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J.C.
Jones
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E.A.
Laird
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E.A.
Laird
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M.T.
Mooney
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M.T.
Mooney
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A
Fedorov
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A
Fedorov
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A.K.
Hektor
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A.K.
Hektor
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J.M.M.
Werner
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J.M.M.
Werner
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Z.
Xie
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Z.
Xie
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X
Huang
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X
Huang
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A.J.M.
Lopez
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A.J.M.
Lopez
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N.I.
Ippolito
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N.I.
Ippolito
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M.
Jones
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M.
Jones
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C
Liu
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C
Liu
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H.W.
Yoo
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H.W.
Yoo
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Y.
Zheng
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Y.
Zheng
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P.
Jindal
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P.
Jindal
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L.D.
Gross
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L.D.
Gross
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F.
Geurts
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F.
Geurts
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J
Liu
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J
Liu
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L.
Sabbatini
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L.
Sabbatini
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Y.S.
Chung
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Y.S.
Chung
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M.A.
Bhatti
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M.A.
Bhatti
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M.
Yan
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M.
Yan
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S.
Thomas
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S.
Thomas
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T.G.
Watts
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T.G.
Watts
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Z.
Yang
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Z.
Yang
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C.T.
Nguyen
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C.T.
Nguyen
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P.D.
van Hove
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P.D.
van Hove
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S.
Sengupta
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S.
Sengupta
(author),
H.
Kim
(author),
H.
Kim
(author),
S
Lee
(author),
S
Lee
(author),
BE
Cox
(author),
BE
Cox
(author),
M.H.
Anderson
(author),
M.H.
Anderson
(author),
S.
Dutta
(author),
S.
Dutta
(author),
A.
Mohapatra
(author),
A.
Mohapatra
(author),
W.M.
Smith
(author),
W.M.
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Commissioning studies of the CMS hadron calorimeter have identified sporadic uncharacteristic noise and a small number of malfunctioning calorimeter channels. Algorithms have been developed to identify and address these problems in the data. The methods have been tested on cosmic
...
Commissioning studies of the CMS hadron calorimeter have identified sporadic uncharacteristic noise and a small number of malfunctioning calorimeter channels. Algorithms have been developed to identify and address these problems in the data. The methods have been tested on cosmic ray muon data, calorimeter noise data, and single beam data collected with CMS in 2008. The noise rejection algorithms can be applied to LHC collision data at the trigger level or in the offline analysis. The application of the algorithms at the trigger level is shown to remove 90% of noise events with fake missing transverse energy above 100 GeV, which is sufficient for the CMS physics trigger operation.
@en