Vapor-fed electrolysis of water has been performed using membrane-electrode assemblies (MEAs) incorporating earth-abundant catalysts and bipolar membranes (BPMs). Catalyst films containing CoP nanoparticles, carbon black, and Nafion were synthesized, characterized, and integrated into cathodes of MEAs. The CoP-containing MEAs exhibited stable (>16 h) vapor-fed electrolysis of water at room temperature at a current density of 10 mA cm⁻² with 350 mV of additional overvoltage relative to MEA's formed from Pt/C cathodic electrocatalysts due to slower hydrogen-evolution reaction kinetics under vapor-fed conditions and fewer available triple-phase boundaries in the catalyst film. Additionally, catalyst films containing a [NiFe]-layered double hydroxide ([NiFe]-LDH) as well as a hydroxide ion conductor, hexamethyl-p-terphenyl poly(benzimidazolium) (HMT-PMBI), were synthesized, characterized, and integrated into the anodes of the MEAs. The [NiFe]-LDH-containing MEAs exhibited overvoltages at 10 mA cm⁻² that were similar to those of IrO_x-containing MEAs for vapor-fed electrolysis of water at room temperature. A BPM was formed by pairing Nafion with HMT-PMBI, resulting in a locally alkaline environment of HMT-PMBI to stabilize the [NiFe]-LDH and a locally acidic environment to stabilize the CoP. BPM-based MEAs were stable (>16 h) for vapor-fed electrolysis of water at room temperature at a current density of 10 mA cm⁻², with a change in the pH gradient of 1 unit over 16 h of electrolysis for IrOx-containing MEAs. The stability of [NiFe]-LDH-based MEAs under vapor-fed conditions was dependent on the catalyst film morphology and resulting BPM interface, with stable operation at 10 mA cm⁻² achieved for 16 h. All MEAs exhibited a drift in the operating voltage over time associated with dehydration. These results demonstrate that earth-abundant catalysts and BPMs can be incorporated into stable, room-temperature, vapor-fed water-splitting cells operated at 10 mA cm⁻²

Freund, Michael S.

Giesbrecht, Patrick K.

Holdcroft, Steven

Lewis, Nathan S.

Müller, Astrid M.

Read, Carlos G.

English

Caltech Authors - Main

 S1 
Vapor-Fed Electrolysis of Water Using Earth-Abundant Catalysts in Nafion or in Bipolar 
Nafion/ Poly(benzimidazolium) Membranes:  Supporting Information 
 
Authors: Patrick K. Giesbrecht;1,2 Astrid M. Müller;3,4 Carlos G. Read;5 Steven Holdcroft;6 Nathan 
S. Lewis;5 Michael S. Freund1,2 
 
Affiliations: 1Department of Chemistry, Florida Institute of Technology, Melbourne, Florida 
32901, United States; 2Department of Chemistry, Dalhousie University, 6274 Coburg Road, 
Halifax, NS B3H 4R2, Canada; 3Beckman Institute, California Institute of Technology, 1200 E. 
California Boulevard, Mail Code 139-74, Pasadena, California 91125, United States; 4Department 
of Chemical Engineering, University of Rochester, Rochester, New York 14627, United States; 
5Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, 
California 91125, United States; 6Department of Chemistry, Simon Fraser University, Burnaby, 
BC V5A 1S6, Canada 
 
Table of Contents 
1. Catalyst Films and Solution-Phase HER/OER. .................................................................................................... S3 
Figure S1. Tafel plots of a) HER catalyst films in 0.50 M H2SO4(aq); and b) OER catalyst films in 1.0 M 
KOH(aq). Dashed lines represent predicted Tafel slopes for an HER/OER electrocatalyst under operation with 
n=0.5, 1, 2 (120, 59 and 30 mV dec-1).1,2 ............................................................................................................................................... S3 
Figure S2. Scanning-electron micrographs of a) Pt/C and b) IrOx Nafion-based films on C-paper prior to MEA 
incorporation. Catalyst loadings of 3 mg cm-2. .................................................................................................................................... S3 
Table S1. Overpotentials for the Cathode and Anode Catalysts Determined in this Work. .......................................... S4 
2. TP-WS Capabilities of MEAs in this work. ........................................................................................................... S4 
Figure S3. Comparison of the TP-WS performance in a two-electrode configuration under humid-N2(g) flow 
at room temperature of a commercially available Pt|IrRuOx sample (black trace) with that of an in-house 
Pt|IrOx MEA used in this work (red trace).  a) Steady-state polarization data and b) constant-current 
electrolysis at 10 mA cm-2. Catalyst loadings were 3 mg cm-2. ..................................................................................................... S4 
Figure S4. a) Constant-current electrolysis (10 mA cm-2) data for CoP-Ti|IrOx MEAs performing TP-WS under 
humid-N2(g) flow at room temperature in the absence (blue trace) and presence (grey trace) of a Nafion 
overcoat. b) Steady-state polarization and c) constant-current electrolysis (10 mA cm-2) data for CoP-C|IrOx 
MEAs performing TP-WS under humid-N2(g) flow at room temperature with and without C black (cb) 
incorporated into the CoP side or a Nafion overcoat. Nafion-based Pt/C|IrOx MEA (red squares) shown for 
comparison. CoP loading of 2 mg cm-2 for C-paper-based cathodes. IrOx loading of 3 mg cm-2 on C-paper for 
the anode. ................................................................................................................................................................................................................ S5 
Figure S5. a) Steady-state polarization and b) constant-current electrolysis (10 mA cm-2) data for [NiFe]-LDH 
samples performing TP-WS under humid-N2(g) flow at room temperature with a HMT-PMBI overlayer (light 
blue, brown traces) and a HMT-PMBI backlayer (dark blue trace). A Nafion-based Pt/C|IrOx MEA (red) is 
shown for comparison. [NiFe]-LDH loading of 0.6 mg cm-2 on the anode; Pt/C loading of 3 mg cm-2 on C-paper 
for the cathode. ..................................................................................................................................................................................................... S5 
Figure S6. a) Steady-state polarization and b) constant-current electrolysis (10 mA cm-2) data for [NiFe]-LDH 
samples performing TP-WS under humid-N2(g) flow at room temperature with HMT-PMBI-Br (gold) or HMT-
PMBI-OH (brown) as the ionomer binder. Nafion-based Pt/C|IrOx MEA (red) shown for comparison. [NiFe]-
LDH loading of 0.6 mg cm-2 on the anode; Pt/C loading of 3 mg cm-2 on C-paper for the cathode. ......................... S6 
Electronic Supplementary Material (ESI) for Sustainable Energy & Fuels.
This journal is © The Royal Society of Chemistry 2019
 S2 
Figure S7. a-c) Steady-state polarization and d-e) constant-current electrolysis (10 mA cm-2) data for 
multiple samples of a,d) Nafion-based Pt|IrOx and CoP-Ti|IrOx MEAs, b) Pt|IrOx BPM-based MEAs, c,e) 
Pt|[NiFe] BPM-based MEAs performing TP-WS under humid-N2(g) flow at room temperature. CoP loading of 
2.5 mg cm-2 on Ti-paper or C-paper for the cathode; IrOx loading of 3 mg cm-2 on C-paper for the anode; 
[NiFe]-LDH loading of 0.6 mg cm-2 on C-paper for the anode; Pt/C loading of 3 mg cm-2 on C-paper for the 
cathode. .................................................................................................................................................................................................................... S6 
Figure S8. Constant-current electrolysis (10 mA cm-2) data for a) Nafion-based (red) and BPM-based (blue) 
Pt|IrOx MEAs; b) Pt|[NiFe] BPM-based MEA; c) CoP-C|IrOx Nafion-based MEA; and d) CoP-Ti|IrOx Nafion-
based MEA before and after rehydration of the MEA under open-circuit voltage conditions. CoP loading of 2.5 
mg cm-2 on Ti-paper or C-paper for the cathode; IrOx loading of 3 mg cm-2 on C-paper for the anode; [NiFe]-
LDH loading of 0.6 mg cm-2 on C-paper for the anode; Pt/C loading of 3 mg cm-2 on C-paper for the cathode. S7 
Figure S9. Bode Plots for representative MEAs at the operating voltage V10 mA cm-2 for TP-WS in this work: a) 
Pt|IrOx Nafion-based MEA; b) Pt|IrOx BPM-based MEAs (Pt|IrOx-10 light blue; Pt|IrOx-30 dark blue); c) CoP-
Ti|IrOx MEA; d) Pt|[NiFe]-30 (gold) and Pt|[NiFe]-100 (brown) BPM-based MEAs; e) CoP-C|IrOx MEA before 
(purple) and after (blue) constant-current electrolysis at 10 mA cm-2. .................................................................................. S8 
Figure S10. Equivalent circuit model fits to EIS spectra at the operating voltage V10 mA cm-2 for representative 
MEAs in this work. ............................................................................................................................................................................................... S9 
Table S2. Series, polarization, mass-transport and activation overvoltages determined from EIS data at V10 mA 
cm-2 for representative MEAs studied in this work............................................................................................................................... S9 
Table S3. Values of the operating voltage V10 mA cm-2 and the drift in the operating voltage during constant-
current electrolysis at 10 mA cm-2 for individual MEAs studied in this work.....................................................................S10 
Table S4. EIS equivalent circuit model values for representative MEAs in this work. Uncorrected for surface 
area of MEA. .........................................................................................................................................................................................................S10 
Determination of the mass-transport overvoltage at 10 mA cm-2. ................................................................ S11 
Determination of the longevity of co-ion current at 10 mA cm-2 in BPM-based MEAs. ............................ S11 
Calculation of current contribution through carbonate removal. ................................................................. S11 
References ..................................................................................................................................................................... S11 
 
 S3 
 
1. Catalyst Films and Solution-Phase HER/OER. 
 
Figure S1. Tafel plots of a) HER catalyst films in 0.50 M H2SO4(aq); and b) OER catalyst films 
in 1.0 M KOH(aq). Dashed lines in a) represent predicted Tafel slopes for an HER electrocatalyst 
under operation (120, 40 and 30 mV dec-1). Dashed lines in b) represent predicted Tafel slopes for 
an OER electrocatalyst under operation with n(1-) =1, 2 (Tafel slopes of 59 and 30 mV dec-1).1,2 
 
 
Figure S2. Scanning-electron micrographs of a) Pt/C and b) IrOx Nafion-based films on C-paper 
prior to MEA incorporation. Catalyst loadings of 3 mg cm-2. 
 
 
 
 
 
 
 
 
 
b) a) 
 S4 
Table S1. Overpotentials, Tafel slope, and exchange current densities for the cathode and anode 
catalysts determined in this work. 
Catalyst Loading (mg cm-2)  −0 mA cm-2 
(HER, V)a 
 0 mA cm-2 
(OER, V)b 
Tafel Slope 
(mV dec-1)c 
J0 (mA 
cm-2) 
Pt foil - -0.045 - 29 0.9 
CoP-Tid 2.5 -0.062 - 49 0.1 
CoP-Ce 2 -0.068 - 132; 44 -g 
IrOx
f 2 - 0.300 55 5x10-5 
[NiFe]-LDHf 0.4 - 0.286 25; 63 2x10-11 
aHER in 0.50 M H2SO4(aq). 
bOER in 1.0 M KOH(aq). cTafel slope reported at low and high 
overpotentials if potential-dependent. dCoP deposited on Ti paper. eCoP deposited on C-paper. 
fDropcast film on glassy-carbon-disk electrode. gPotential-dependent Tafel slope prevented 
accurate determination of the exchange current density. 
 
2. TP-WS Capabilities of MEAs in this work. 
 
Figure S3. Comparison of the TP-WS performance in a two-electrode configuration under humid-
N2(g) flow at room temperature of a commercially available Pt|IrRuOx sample (black trace) with 
that of an in-house Pt|IrOx MEA used in this work (red trace).  a) Steady-state polarization data 
and b) constant-current electrolysis at 10 mA cm-2. Catalyst loadings were 3 mg cm-2.  
 
 
 
 
 
 S5 
 
Figure S4. a) Constant-current electrolysis (10 mA cm-2) data for CoP-Ti|IrOx MEAs performing 
TP-WS under humid-N2(g) flow at room temperature in the absence (blue trace) and presence 
(grey trace) of a Nafion overcoat. b) Steady-state polarization and c) constant-current electrolysis 
(10 mA cm-2) data for CoP-C|IrOx MEAs performing TP-WS under humid-N2(g) flow at room 
temperature with and without C black (cb) incorporated into the CoP side or a Nafion overcoat. 
Nafion-based Pt/C|IrOx MEA (red squares) shown for comparison. CoP loading of 2 mg cm
-2 for 
C-paper-based cathodes. IrOx loading of 3 mg cm
-2 on C-paper for the anode. 
 
 
Figure S5. a) Steady-state polarization and b) constant-current electrolysis (10 mA cm-2) data for 
[NiFe]-LDH samples performing TP-WS under humid-N2(g) flow at room temperature with a 
HMT-PMBI overlayer (light blue, brown traces) and a HMT-PMBI backlayer (dark blue trace). A 
Nafion-based Pt/C|IrOx MEA (red) is shown for comparison. [NiFe]-LDH loading of 0.6 mg cm
-2 
on the anode; Pt/C loading of 3 mg cm-2 on C-paper for the cathode. 
 
 S6 
 
Figure S6. a) Steady-state polarization and b) constant-current electrolysis (10 mA cm-2) data for 
[NiFe]-LDH samples performing TP-WS under humid-N2(g) flow at room temperature with 
HMT-PMBI-Br (gold) or HMT-PMBI-OH (brown) as the ionomer binder. Nafion-based Pt/C|IrOx 
MEA (red) shown for comparison. [NiFe]-LDH loading of 0.6 mg cm-2 on the anode; Pt/C loading 
of 3 mg cm-2 on C-paper for the cathode. 
 
 
Figure S7. a-c) Steady-state polarization and d-e) constant-current electrolysis (10 mA cm-2) data 
for multiple samples of a,d) Nafion-based Pt|IrOx and CoP-Ti|IrOx MEAs, b) Pt|IrOx BPM-based 
MEAs, c,e) Pt|[NiFe] BPM-based MEAs performing TP-WS under humid-N2(g) flow at room 
temperature. CoP loading of 2.5 mg cm-2 on Ti-paper or C-paper for the cathode; IrOx loading of 
3 mg cm-2 on C-paper for the anode; [NiFe]-LDH loading of 0.6 mg cm-2 on C-paper for the anode; 
Pt/C loading of 3 mg cm-2 on C-paper for the cathode. 
 
 S7 
 
Figure S8. Constant-current electrolysis (10 mA cm-2) data for a) Nafion-based (red) and BPM-
based (blue) Pt|IrOx MEAs; b) Pt|[NiFe] BPM-based MEA; c) CoP-C|IrOx Nafion-based MEA; 
and d) CoP-Ti|IrOx Nafion-based MEA before and after rehydration of the MEA under open-
circuit voltage conditions. CoP loading of 2.5 mg cm-2 on Ti-paper or C-paper for the cathode; 
IrOx loading of 3 mg cm
-2 on C-paper for the anode; [NiFe]-LDH loading of 0.6 mg cm-2 on C-
paper for the anode; Pt/C loading of 3 mg cm-2 on C-paper for the cathode. 
 
 S8 
 
Figure S9. Bode Plots for representative MEAs at the operating voltage V10 mA cm-2 for TP-WS in 
this work: a) Pt|IrOx Nafion-based MEA; b) Pt|IrOx BPM-based MEAs (Pt|IrOx-10 light blue; 
Pt|IrOx-30 dark blue); c) CoP-Ti|IrOx MEA; d) Pt|[NiFe]-30 (gold) and Pt|[NiFe]-100 (brown) 
BPM-based MEAs; e) CoP-C|IrOx MEA before (purple) and after (blue) constant-current 
electrolysis at 10 mA cm-2. 
 
 S9 
 
Figure S10. Equivalent circuit model fits to EIS spectra at the operating voltage V10 mA cm-2 for 
representative MEAs in this work. 
 
Table S2. Series, polarization, mass-transport and activation overvoltages determined from EIS 
data at V10 mA cm-2 for representative MEAs studied in this work. 
MEA ViR (V)
a Vpolarization (V)
b Vmxt (V)
c Vact (V)
d 
Pt|IrOx 0.03 0.05 0.005 0.38 
Pt|IrOx-10 0.02 0.08 0.009 0.56 
Pt|IrOx-30 0.04 0.12 0.010 0.54 
CoP-Ti|IrOx 0.09 0.13 0.012 0.60 
CoP-C|IrOx 0.02 0.14 0.010 0.75 
CoP-C|IrOx after 0.02 0.17 - - 
Pt|[NiFe]-30 0.02 0.07 0.005 0.48 
Pt|[NiFe]-30 after 0.02 0.32 - - 
Pt|[NiFe]-100 0.02 0.08 0.005 0.50 
Pt|[NiFe]-100 after 0.02 0.28 - - 
aDetermined from the Z’ high-frequency intercept in Nyquist plot of the EIS spectra of the MEA 
at V10 mA cm-2. 
bWidth of the Nyquist plot of the EIS spectra of the MEA at V10 mA cm-2. 
cDetermined 
 S10 
from application of Equation S1 to steady-state polarization data. dDetermined from Equation 1 in 
the manuscript. 
 
Table S3. Values of the operating voltage V10 mA cm-2 and the drift in the operating voltage during 
constant-current electrolysis at 10 mA cm-2 for individual MEAs studied in this work. 
MEA V10 mA cm-2 (V)
a 
Vdrift (V)
b Rate (mV hr-1) 
Pt|IrRuOx 1.45 0 0 
Pt|IrOx 1.60 0.05 2.8 
Pt|IrOx-2 1.59 0.05 2.8 
Pt|IrOx-10 1.72 0.06 3.3 
Pt|IrOx-30 1.75 0.03 1.7 
CoP-Ti|IrOx 1.90 0.10 5.5 
CoP-Ti|IrOx-2 2.01 0.09 5.0 
CoP-C|IrOx 1.95 0.19 10.6 
Pt-Ti|IrOx 1.70 0.19 10.6 
Pt|[NiFe]-10 1.72 0.78 43.3 
Pt|[NiFe]-10-2 1.74 0.76 190 
Pt|[NiFe]-30 1.71 0.50 27.8 
Pt|[NiFe]-30-2 1.75 0.70 38.9 
Pt|[NiFe]-100 1.70 0.15 8.3 
Pt|[NiFe]-100-2 1.70 0.17 9.4 
Pt|HMT|[NiFe]-30 1.83 0.76 42.2 
Pt|[NiFe]-100|HMT 1.75 0.32 17.8 
aOperating voltage at 10 mA cm-2 as determined from steady-state polarization data. bDrift in V10 
mA cm
-2 during constant-current electrolysis at 10 mA cm-2. 
 
Table S4. EIS equivalent circuit model values for representative MEAs in this work. Uncorrected 
for surface area of MEA. 
MEA Rs () Rcath 
() 
Qcath
a 
cath Ran () Qan
a 
an 
Pt|IrOx 0.8944 0.23592 0.0004818 0.88111 1.222 0.03866601 0.66835 
Pt|IrOx-10* 0.81403 0.23592 0.0004818 0.88111 2.212 0.0002194 0.75934 
Pt|IrOx-30 1.286 0.44631 2.4302E-05 0.98216 3.482 0.00245811 0.6883 
CoP-Ti 2.741 3.528 0.01490799 0.76528 0.84837 0.02601 0.45651 
CoP-C 
initial 
0.57244 3.831 0.00631101 
0.75567 
0.82432 0.02221401 
0.52097 
CoP-C 
after** 
0.79924 4.463 0.00140571 
0.74212 
0.82432 0.02221401 
0.52097 
Pt|[NiFe]-30 0.77181 0.4936 0.0002114 0.90747 1.635 0.00380631 0.7388 
Pt|[NiFe]100 0.89998 0.28377 0.00013037 0.99547 1.936 0.00092538 0.77069 
aQ unit is -1 s. 
*Values of Rcath, Qcath, and cath were fixed to values obtained from Pt|IrOx. 
**Values of Ran, Qan, and an were kept fixed to values obtained from CoP-C initial. 
 
 S11 
Determination of the mass-transport overvoltage at 10 mA cm-2. 
 
The overvoltage associated with mass transport for TP-WS under flow can be determined by 
∆𝑉𝑚𝑥𝑡 =
𝑅𝑇
𝑛𝐹
(1 +
1
𝛼
) ln (
𝐽lim
Jlim − J
)      (𝑆1) 
Where R is the ideal gas constant, T temperature, n = 2, F Faraday’s constant, charge-transfer 
coefficient 𝛼 = 0.5, 𝐽lim  the limiting current density determined from steady-state polarization 
data, and J the current density of interest (10 mA cm-2). 
Determination of the longevity of co-ion current at 10 mA cm-2 in BPM-based MEAs. 
 
Ageometric = 3 cm
2; Lnafion = 0.0183 cm; Lcath = 0.001 cm; Lanode = LHMT-PMBI = 0.001 cm 
[M+]Nafion = 1.5 M; [A
-]HMT-PMBI = 1.5 M 
 
Total co-ion current density time at 10 mA cm-2: 
Ttotal = (nM + nA)*F/(0.03A) 
Ttotal = (3 cm
2)*(0.0015 mol/cm3)*(0.0183 cm+0.002 cm)*(96485 C/mol)/(0.03A) 
Ttotal = 290 s 
Calculation of current contribution through carbonate removal. 
 
From Ref 3:  
CCO2 = 5 ppm (via GC-MS, constant value for ca. 50 h, flow rate of 0.1 L/min) 
VCO2 = 5 ppm (0.1 L/min)(3000 min) = 1.5 mL 
T = 323 K 
NCO2 = PV/RT = (1 atm)(0.0015 L)/[(0.08206 atm*L/K*mol)(323K)] = 5.6x10
-5 mol 
Current: I = ZNF/t = 2*(5.6x10-5 mol) (96485 C/mol)/(1.8x105 s) = 6.1x10-5 A 
Area= 5 cm2; J = 300 mA/cm2 
%Current(Carbonate removal) =100* 6.1x10-5A/(5*0.3 A) = 0.004% 
 
This Work: (Assume 5 ppm CO2 being constantly generated) 
Flow rate of 0.2 L/min; VCO2 = 5 ppm (0.2 L/min)(960 min) = 0.96 mL 
T= 298 K 
NCO2 = (1 atm)(0.00096 L)/[(0.08206 atm*L/K*mol)(298K)] = 3.9x10
-5 mol 
Current: (Z = 4 for this process) I = 4*(3.9x10-5 mol)(96485 C/mol)/57600 s = 0.26 mA 
%Current(Carbonate removal) = 100 * 0.26 mA / [(1.6 cm2)(10 mA/cm2)] = 1.7% 
 
References 
(1)  Bockris, J. O. Kinetics of Activation Controlled Consecutive Electrochemical Reactions: 
Anodic Evolution of Oxygen. J. Chem. Phys. 1956, 24 (4), 817–827. 
https://doi.org/10.1063/1.1742616. 
(2)  Shinagawa, T.; Garcia-Esparza, A. T.; Takanabe, K. Insight on Tafel Slopes from a 
Microkinetic Analysis of Aqueous Electrocatalysis for Energy Conversion. Sci. Rep. 
2015, 5, 1–21. https://doi.org/10.1038/srep13801. 
(3)  Watanabe, S.; Fukuta, K.; Yanagi, H. Determination of Carbonate Ion in MEA during 
Alkaline Membrane Fuel Cell (AMFC) Operation. ECS Trans. 2010, 33 (1), 1837–1845. 


Vapor-fed electrolysis of water using earth-abundant catalysts in Nafion or in bipolar Nafion/poly(benzimidazolium) membranes

Abbott, Clara

Scholarship, Research, and Creative Work at Bryn Mawr College | Bryn Mawr College Research

Teaching and Learning Together in Higher EducationIssue 18 Spring 2016Leaping and Landing in Brave SpacesClara AbbottHaverford CollegeFollow this and additional works at: http://repository.brynmawr.edu/tlthePart of the Higher Education and Teaching CommonsLet us know how access to this document benefits you.Recommended CitationAbbott, Clara "Leaping and Landing in Brave Spaces," Teaching and Learning Together in Higher Education: Iss. 18 (2016),http://repository.brynmawr.edu/tlthe/vol1/iss18/4LEAPING AND LANDING IN BRAVE SPACES  Clara Abbott, Haverford College, Class of 2017  It is hard to describe in words the feeling of deciding to speak or raise my hand in a classroom. It is a crucial moment, the moment between silence and sound, closed and open. It can happen in many different ways: I can feel it as I write, as I make any kind of art, tell a story, or do something that breaks the boundary between myself and the world around me. This feeling of exposure to others can lead to hurt or rejection or great joy and growth.   I feel lucky to have been in surroundings for most of my life that have affirmed and supported me when I have exposed my ideas and poured myself into them. I have learned to trust others when I open myself up or feel uncomfortable, when I raise my hand or read something I have written. I trust that even though it may feel uncomfortable or strange to break the boundary between my mind and the minds of others, that this breakage might ultimately result in growth, not harm. It is like the strengthening of a muscle, with microfibers that break and mend themselves stronger, I leap and land stronger as I share myself and my peers.   This is the essence of what it means to experience brave space, driven by the knowledge that when we open yourselves up, give a part of ourselves to the world around us, that our discomfort will somehow leave us stronger and greater instead of damaged and embarrassed. Leaping into a brave space does not keep us from experiencing moments of rupture or discomfort. Instead, brave spaces facilitate regeneration and growth after these moments happen. They allow for brave leaps to happen because they ensure a safe landing.   But it is not always so easy for students to take those leaps or for faculty members to support them. During my partnership with a faculty member in a seminar-style, discussion-based natural science class taught at Haverford College in the Spring-2016 semester, as I sat in the classroom as a student consultant through the Students as Learners and Teachers (SaLT) program rather than a student enrolled in the course, I watched this leaping and landing occur for other students. I saw the process happen from a more removed perspective, and I saw how others felt about exposing their ideas to the rest of the room. I watched people look over their notes and decide to raise their hands, walk slowly up to the board to write down an idea, field questions about their ideas and conclusions. I saw this crossing of a threshold constantly in the classroom and it became the lens through which I viewed almost all of the observations I was making about discussion and class dynamics.  I started to wonder, when did people feel that they could leap or stretch or open? And when did people not trust that they would land safely?   As the class became more familiar with one another as people, my faculty partner and I saw a greater variety of people speaking up and contributing in different ways. Discussion became less about finding the certain right answer and more open to questions and queries. People began to speak to each other more candidly about things that concerned or confused them about a particular concept, dwelling in the uncertain, growing from the moments of vulnerability. These changes were in no way linear; the fluctuated from week to week and depended on anything from the weather to the readings being covered. But one could feel in the room when this magic was happening. It felt clear in the way people began their sentences with, “This isn’t a fully 1Abbott: Leaping and Landing in Brave Spacesdeveloped idea but…” or “I’m just wondering about…” as they grappled with ideas, forming relationships with them rather than passively writing them down.   With these phrases that I came to recognize as preceding the leaps, the boundaries between the students, the professor, and the ideas began to crack and exchange became possible. The room transformed from a space of memorization to a space that supported personal transformation. When students said what they were wondering or asked questions, they were answered compassionately and with love rather than with shaming or rejection. I saw on the good days that students felt they could be affirmed in their wondering and trusting that it would help them expand.   These safe landings, these moments of affirmation, needed to be fostered and facilitated carefully by the professor. When two students in the class had trouble engaging, breaking this boundary and opening up, she decided to email them both and let them know that she had loved reading their work and hearing about their ideas and that the class would benefit from hearing what they had to say.  She affirmed their thoughts and ideas and let them know that their views would be appreciated by others in the classroom. She let them know that they would have a place to land after they took a jump or made themselves vulnerable, that others would support them and say yes to them when they opened themselves up. After this email exchange, we saw a huge difference in how these students participated. They did not need any punishment or shame for not participating, just affirmation that if they participated their contributions would be received with grace and appreciation.   And this affirmation worked inversely as well. There were students who dominated the classroom space at the beginning of the semester, who felt most comfortable and least vulnerable when they had the airtime. There were students who answered every question, filling in the silence and getting the right answer almost every time. There was no such blatant intervention for these students, but we saw changes as different means of contribution were introduced. Written work, presentations, group work, and other formats challenged them to embrace silence and make space for their peers. For the number of people who had trouble participating and found their vulnerable space in raising their hand, there were just as many people who found their brave space in the act of listening and opening their minds to receive new ideas. Such receptivity also requires vulnerability, a degree of exposure from the listener that might not feel easy.   I believe that these precarious moments are sacred. They are the reason why I want to learn, because what is learning if not discovering things we did not expect, feeling changed and shaken by things we did not understand before? I have had many conversations this semester with my faculty partner and other student consultants about the ways in which these leaps, these moments when we put ourselves into something, breaking the barrier between ourselves and our surroundings, are terrifying. It feels terrifying to not know what will happen when we tell a truth about ourselves or connect ourselves with something in the outside world. Damage is possible when we give ourselves to our surroundings.   But when a leader of a classroom space makes it clear that discomfort, exposure, and rupture yield regeneration rather than damage, a certain type of magic emerges in the room. It is the 2Teaching and Learning Together in Higher Education, 18 [2016]http://repository.brynmawr.edu/tlthe/vol1/iss18/4feeling of knowing one is accepted and welcomed unconditionally, that we are all in this room in order to grow together and that our successes and gains are intimately intertwined. In a brave space, we catch each other after our big leaps and make sure we grow when we feel uncomfortable.   To me, a brave space acknowledges the interconnectedness of our lives and our world, acknowledges that we are in conversation with a confusing and changing world and that that feels scary. But we know this vulnerability and change can make us better and we feel committed to making that happen. We know when we make a little tear in the fiber of our understanding that we have enough affirmation and love from our surroundings to rebuild the fiber so it is stronger and more complex. We know we will walk out of the brave space changed, and that is beautiful.      3Abbott: Leaping and Landing in Brave Spaces

Leaping and Landing in Brave Spaces

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Leaping and Landing in Brave Spaces

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